waves¶
RF wave propagation and deposition. Note that current estimates in this IDS are a priori not taking into account synergies between multiple sources (a convergence loop with Fokker-Planck calculations is required to account for such synergies)
Maximum occurrences (MDS+ backend only): 8
New in version 3.5.0: lifecycle status alpha
Changed in version 3.41.0.
ids_propertiesstructure¶
See common IDS structure reference: ids_properties.
coherent_wave(i1)AoS¶Wave description for each frequency
Wave description for each frequency
Appendable by appender actor: yes
Maximum occurrences (MDS+ backend only): 100
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coherent_wave(i1)/identifierstructure¶Identifier of the coherent wave, in terms of the type and name […]
Identifier of the coherent wave, in terms of the type and name of the antenna driving the wave and an index separating waves driven by the same antenna.
coherent_wave(i1)/identifier/typestructure¶Wave/antenna type. […]
Wave/antenna type. index=1 for name=EC; index=2 for name=IC; index=3 for name=LH
This is an identifier. See wave_identifier for the available options.
coherent_wave(i1)/wave_solver_typestructure¶Type of wave deposition solver used for this wave. […]
Type of wave deposition solver used for this wave. Index = 1 for beam/ray tracing; index = 2 for full wave
coherent_wave(i1)/global_quantities(itime)AoS¶Global quantities for various time slices
Global quantities for various time slices
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coherent_wave(i1)/global_quantities(itime)/n_phi(:)INT_1D¶Toroidal mode numbers, the wave vector toroidal component being […]
Toroidal mode numbers, the wave vector toroidal component being defined as k_tor = n_tor grad phi where phi is the toroidal angle so that a positive n_tor means a wave propagating in the positive phi direction
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Changed in version 3.42.0: Renamed from n_tor
coherent_wave(i1)/global_quantities(itime)/power ⇹WFLT_0D¶Total absorbed wave power
Total absorbed wave power
coherent_wave(i1)/global_quantities(itime)/power_n_phi(:) ⇹WFLT_1D¶Absorbed wave power per toroidal mode number
Absorbed wave power per toroidal mode number
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Changed in version 3.42.0: Renamed from power_n_tor
coherent_wave(i1)/global_quantities(itime)/current_phi ⇹AFLT_0D¶Wave driven toroidal current from a stand alone calculation (not […]
Wave driven toroidal current from a stand alone calculation (not consistent with other sources)
Changed in version 3.42.0: Renamed from current_tor
coherent_wave(i1)/global_quantities(itime)/current_phi_n_phi(:) ⇹AFLT_1D¶Wave driven toroidal current from a stand alone calculation (not […]
Wave driven toroidal current from a stand alone calculation (not consistent with other sources) per toroidal mode number
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Changed in version 3.42.0: Renamed from current_tor_n_tor
coherent_wave(i1)/global_quantities(itime)/electronsstructure¶Quantities related to the electrons
Quantities related to the electrons
coherent_wave(i1)/global_quantities(itime)/electrons/power_thermal ⇹WFLT_0D¶Wave power absorbed by the thermal particle population
Wave power absorbed by the thermal particle population
coherent_wave(i1)/global_quantities(itime)/electrons/power_thermal_n_phi(:) ⇹WFLT_1D¶Wave power absorbed by the thermal particle population per toroidal […]
Wave power absorbed by the thermal particle population per toroidal mode number
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Changed in version 3.42.0: Renamed from power_thermal_n_tor
coherent_wave(i1)/global_quantities(itime)/electrons/power_fast ⇹WFLT_0D¶Wave power absorbed by the fast particle population
Wave power absorbed by the fast particle population
coherent_wave(i1)/global_quantities(itime)/electrons/power_fast_n_phi(:) ⇹WFLT_1D¶Wave power absorbed by the fast particle population per toroidal […]
Wave power absorbed by the fast particle population per toroidal mode number
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Changed in version 3.42.0: Renamed from power_fast_n_tor
coherent_wave(i1)/global_quantities(itime)/electrons/distribution_assumptionINT_0D¶Assumption on the distribution function used by the wave solver […]
Assumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS).
coherent_wave(i1)/global_quantities(itime)/ion(i2)AoS¶Quantities related to the different ion species
Quantities related to the different ion species
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coherent_wave(i1)/global_quantities(itime)/ion(i2)/element(i3)AoS¶List of elements forming the atom or molecule
List of elements forming the atom or molecule
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coherent_wave(i1)/global_quantities(itime)/ion(i2)/z_ion ⇹eFLT_0D¶Ion charge (of the dominant ionisation state; lumped ions are […]
Ion charge (of the dominant ionisation state; lumped ions are allowed).
coherent_wave(i1)/global_quantities(itime)/ion(i2)/nameSTR_0D¶String identifying the species (e.g. […]
String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/global_quantities(itime)/ion(i2)/power_thermal ⇹WFLT_0D¶Wave power absorbed by the thermal particle population
Wave power absorbed by the thermal particle population
coherent_wave(i1)/global_quantities(itime)/ion(i2)/power_thermal_n_phi(:) ⇹WFLT_1D¶Wave power absorbed by the thermal particle population per toroidal […]
Wave power absorbed by the thermal particle population per toroidal mode number
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Changed in version 3.42.0: Renamed from power_thermal_n_tor
coherent_wave(i1)/global_quantities(itime)/ion(i2)/power_fast ⇹WFLT_0D¶Wave power absorbed by the fast particle population
Wave power absorbed by the fast particle population
coherent_wave(i1)/global_quantities(itime)/ion(i2)/power_fast_n_phi(:) ⇹WFLT_1D¶Wave power absorbed by the fast particle population per toroidal […]
Wave power absorbed by the fast particle population per toroidal mode number
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Changed in version 3.42.0: Renamed from power_fast_n_tor
coherent_wave(i1)/global_quantities(itime)/ion(i2)/multiple_states_flagINT_0D¶Multiple state calculation flag : 0-Only one state is considered; […]
Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure
coherent_wave(i1)/global_quantities(itime)/ion(i2)/distribution_assumptionINT_0D¶Assumption on the distribution function used by the wave solver […]
Assumption on the distribution function used by the wave solver to calculate the power deposition on this species: 0 = Maxwellian (linear absorption); 1 = quasi-linear (F given by a distributions IDS).
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)AoS¶Collisional exchange with the various states of the ion species […]
Collisional exchange with the various states of the ion species (ionisation, energy, excitation, …)
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coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/z_min ⇹eFLT_0D¶Minimum Z of the charge state bundle (z_min = z_max = 0 for a […]
Minimum Z of the charge state bundle (z_min = z_max = 0 for a neutral)
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/z_max ⇹eFLT_0D¶Maximum Z of the charge state bundle (equal to z_min if no bundle)
Maximum Z of the charge state bundle (equal to z_min if no bundle)
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/nameSTR_0D¶String identifying charge state (e.g. […]
String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/electron_configurationSTR_0D¶Configuration of atomic orbitals of this state, e.g. […]
Configuration of atomic orbitals of this state, e.g. 1s2-2s1
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/vibrational_level ⇹eFLT_0D¶Vibrational level (can be bundled)
Vibrational level (can be bundled)
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/vibrational_modeSTR_0D¶Vibrational mode of this state, e.g. […]
Vibrational mode of this state, e.g. “A_g”. Need to define, or adopt a standard nomenclature.
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/power_thermal ⇹WFLT_0D¶Wave power absorbed by the thermal particle population
Wave power absorbed by the thermal particle population
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/power_thermal_n_phi(:) ⇹WFLT_1D¶Wave power absorbed by the thermal particle population per toroidal […]
Wave power absorbed by the thermal particle population per toroidal mode number
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Changed in version 3.42.0: Renamed from power_thermal_n_tor
coherent_wave(i1)/global_quantities(itime)/ion(i2)/state(i3)/power_fast ⇹WFLT_0D¶Wave power absorbed by the fast particle population
Wave power absorbed by the fast particle population
coherent_wave(i1)/profiles_1d(itime)AoS¶Source radial profiles (flux surface averaged quantities) for […]
Source radial profiles (flux surface averaged quantities) for various time slices
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coherent_wave(i1)/profiles_1d(itime)/gridstructure¶Radial grid
Radial grid
coherent_wave(i1)/profiles_1d(itime)/grid/rho_tor_norm(:) ⇹1FLT_1D¶Normalized toroidal flux coordinate. […]
Normalized toroidal flux coordinate. The normalizing value for rho_tor_norm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation, see time_slice/boundary/b_flux_pol_norm in the equilibrium IDS)
Alternatives for this coordinate
The following items may be used as a coordinate instead of rho_tor_norm:
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coherent_wave(i1)/profiles_1d(itime)/grid/rho_tor(:) ⇹mFLT_1D¶Toroidal flux coordinate = sqrt(phi/(pi\*b0)), where the toroidal […]
Toroidal flux coordinate = sqrt(phi/(pi*b0)), where the toroidal magnetic field, b0, corresponds to that stored in vacuum_toroidal_field/b0 and pi can be found in the IMAS constants
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coherent_wave(i1)/profiles_1d(itime)/grid/rho_pol_norm(:) ⇹1FLT_1D¶Normalized poloidal flux coordinate = sqrt((psi(rho)-psi(magnetic_axis)) […]
Normalized poloidal flux coordinate = sqrt((psi(rho)-psi(magnetic_axis)) / (psi(LCFS)-psi(magnetic_axis)))
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coherent_wave(i1)/profiles_1d(itime)/grid/psi(:) ⇹WbFLT_1D¶Poloidal magnetic flux. […]
Poloidal magnetic flux. Integral of magnetic field passing through a contour defined by the intersection of a flux surface passing through the point of interest and a Z=constant plane. If the integration surface is flat, the surface normal vector is in the increasing vertical coordinate direction, Z, namely upwards.
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coherent_wave(i1)/profiles_1d(itime)/grid/volume(:) ⇹m^3FLT_1D¶Volume enclosed inside the magnetic surface
Volume enclosed inside the magnetic surface
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coherent_wave(i1)/profiles_1d(itime)/grid/area(:) ⇹m^2FLT_1D¶Cross-sectional area of the flux surface
Cross-sectional area of the flux surface
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coherent_wave(i1)/profiles_1d(itime)/grid/surface(:) ⇹m^2FLT_1D¶Surface area of the toroidal flux surface
Surface area of the toroidal flux surface
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coherent_wave(i1)/profiles_1d(itime)/grid/psi_magnetic_axis ⇹WbFLT_0D¶Value of the poloidal magnetic flux at the magnetic axis (useful […]
Value of the poloidal magnetic flux at the magnetic axis (useful to normalize the psi array values when the radial grid doesn’t go from the magnetic axis to the plasma boundary)
coherent_wave(i1)/profiles_1d(itime)/grid/psi_boundary ⇹WbFLT_0D¶Value of the poloidal magnetic flux at the plasma boundary (useful […]
Value of the poloidal magnetic flux at the plasma boundary (useful to normalize the psi array values when the radial grid doesn’t go from the magnetic axis to the plasma boundary)
coherent_wave(i1)/profiles_1d(itime)/n_phi(:)INT_1D¶Toroidal mode numbers, the wave vector toroidal component being […]
Toroidal mode numbers, the wave vector toroidal component being defined as k_phi = n_phi grad phi where phi is the toroidal angle so that a positive n_phi means a wave propagating in the positive phi direction
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Changed in version 3.42.0: Renamed from n_tor
coherent_wave(i1)/profiles_1d(itime)/power_density(:) ⇹W.m^-3FLT_1D¶Flux surface averaged total absorbed wave power density (electrons […]
Flux surface averaged total absorbed wave power density (electrons + ion + fast populations)
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coherent_wave(i1)/profiles_1d(itime)/power_density_n_phi(:,:) ⇹W.m^-3FLT_2D¶Flux surface averaged absorbed wave power density per toroidal […]
Flux surface averaged absorbed wave power density per toroidal mode number
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Changed in version 3.42.0: Renamed from power_density_n_tor
coherent_wave(i1)/profiles_1d(itime)/power_inside(:) ⇹WFLT_1D¶Total absorbed wave power (electrons + ion + fast populations) […]
Total absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density)
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coherent_wave(i1)/profiles_1d(itime)/power_inside_n_phi(:,:) ⇹WFLT_2D¶Total absorbed wave power (electrons + ion + fast populations) […]
Total absorbed wave power (electrons + ion + fast populations) inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number
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Changed in version 3.42.0: Renamed from power_inside_n_tor
coherent_wave(i1)/profiles_1d(itime)/current_phi_inside(:) ⇹AFLT_1D¶Wave driven toroidal current, inside a flux surface
Wave driven toroidal current, inside a flux surface
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Changed in version 3.42.0: Renamed from current_tor_inside
coherent_wave(i1)/profiles_1d(itime)/current_phi_inside_n_phi(:,:) ⇹AFLT_2D¶Wave driven toroidal current, inside a flux surface, per toroidal […]
Wave driven toroidal current, inside a flux surface, per toroidal mode number
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Changed in version 3.42.0: Renamed from current_tor_inside_n_tor
coherent_wave(i1)/profiles_1d(itime)/current_parallel_density(:) ⇹A.m^-2FLT_1D¶Flux surface averaged wave driven parallel current density = […]
Flux surface averaged wave driven parallel current density = average(j.B) / B0, where B0 = vacuum_toroidal_field/b0.
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coherent_wave(i1)/profiles_1d(itime)/current_parallel_density_n_phi(:,:) ⇹A.m^-2FLT_2D¶Flux surface averaged wave driven parallel current density, per […]
Flux surface averaged wave driven parallel current density, per toroidal mode number
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Changed in version 3.42.0: Renamed from current_parallel_density_n_tor
coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)AoS¶Components of the electric field per toroidal mode number, averaged […]
Components of the electric field per toroidal mode number, averaged over the flux surface, where the averaged is weighted with the power deposition density, such that e_field = ave(e_field.power_density) / ave(power_density)
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Changed in version 3.42.0: Renamed from e_field_n_tor
coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/plusV.m^-1structure¶Left hand polarized electric field component for every flux surface
Left hand polarized electric field component for every flux surface
coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/plus/amplitude(:) ⇹V.m^-1FLT_1D¶Amplitude
Amplitude
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coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/plus/phase(:) ⇹V.m^-1FLT_1D¶Phase
Phase
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coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/minusV.m^-1structure¶Right hand polarized electric field component for every flux […]
Right hand polarized electric field component for every flux surface
coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/minus/amplitude(:) ⇹V.m^-1FLT_1D¶Amplitude
Amplitude
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coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/minus/phase(:) ⇹V.m^-1FLT_1D¶Phase
Phase
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coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/parallelV.m^-1structure¶Parallel electric field component for every flux surface
Parallel electric field component for every flux surface
coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/parallel/amplitude(:) ⇹V.m^-1FLT_1D¶Amplitude
Amplitude
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coherent_wave(i1)/profiles_1d(itime)/e_field_n_phi(i2)/parallel/phase(:) ⇹V.m^-1FLT_1D¶Phase
Phase
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coherent_wave(i1)/profiles_1d(itime)/k_perpendicular(:,:) ⇹V.m^-1FLT_2D¶Perpendicular wave vector, averaged over the flux surface, where […]
Perpendicular wave vector, averaged over the flux surface, where the averaged is weighted with the power deposition density, such that k_perpendicular = ave(k_perpendicular.power_density) / ave(power_density), for every flux surface and every toroidal number
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coherent_wave(i1)/profiles_1d(itime)/electronsstructure¶Quantities related to the electrons
Quantities related to the electrons
coherent_wave(i1)/profiles_1d(itime)/electrons/power_density_thermal(:) ⇹W.m^-3FLT_1D¶Flux surface averaged absorbed wave power density on the thermal […]
Flux surface averaged absorbed wave power density on the thermal species
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coherent_wave(i1)/profiles_1d(itime)/electrons/power_density_thermal_n_phi(:,:) ⇹W.m^-3FLT_2D¶Flux surface averaged absorbed wave power density on the thermal […]
Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number
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Changed in version 3.42.0: Renamed from power_density_thermal_n_tor
coherent_wave(i1)/profiles_1d(itime)/electrons/power_density_fast(:) ⇹W.m^-3FLT_1D¶Flux surface averaged absorbed wave power density on the fast […]
Flux surface averaged absorbed wave power density on the fast species
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coherent_wave(i1)/profiles_1d(itime)/electrons/power_density_fast_n_phi(:,:) ⇹W.m^-3FLT_2D¶Flux surface averaged absorbed wave power density on the fast […]
Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number
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Changed in version 3.42.0: Renamed from power_density_fast_n_tor
coherent_wave(i1)/profiles_1d(itime)/electrons/power_inside_thermal(:) ⇹WFLT_1D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)
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coherent_wave(i1)/profiles_1d(itime)/electrons/power_inside_thermal_n_phi(:,:) ⇹WFLT_2D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number
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Changed in version 3.42.0: Renamed from power_thermal_inside_n_tor
coherent_wave(i1)/profiles_1d(itime)/electrons/power_inside_fast(:) ⇹WFLT_1D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)
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coherent_wave(i1)/profiles_1d(itime)/electrons/power_inside_fast_n_phi(:,:) ⇹WFLT_2D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number
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Changed in version 3.42.0: Renamed from power_inside_fast_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)AoS¶Quantities related to the different ion species
Quantities related to the different ion species
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/element(i3)AoS¶List of elements forming the atom or molecule
List of elements forming the atom or molecule
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/z_ion ⇹eFLT_0D¶Ion charge (of the dominant ionisation state; lumped ions are […]
Ion charge (of the dominant ionisation state; lumped ions are allowed).
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/nameSTR_0D¶String identifying the species (e.g. […]
String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_density_thermal(:) ⇹W.m^-3FLT_1D¶Flux surface averaged absorbed wave power density on the thermal […]
Flux surface averaged absorbed wave power density on the thermal species
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_density_thermal_n_phi(:,:) ⇹W.m^-3FLT_2D¶Flux surface averaged absorbed wave power density on the thermal […]
Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number
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Changed in version 3.42.0: Renamed from power_density_thermal_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_density_fast(:) ⇹W.m^-3FLT_1D¶Flux surface averaged absorbed wave power density on the fast […]
Flux surface averaged absorbed wave power density on the fast species
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_density_fast_n_phi(:,:) ⇹W.m^-3FLT_2D¶Flux surface averaged absorbed wave power density on the fast […]
Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number
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Changed in version 3.42.0: Renamed from power_density_fast_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_inside_thermal(:) ⇹WFLT_1D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_inside_thermal_n_phi(:,:) ⇹WFLT_2D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number
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Changed in version 3.42.0: Renamed from power_inside_thermal_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_inside_fast(:) ⇹WFLT_1D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/power_inside_fast_n_phi(:,:) ⇹WFLT_2D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number
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Changed in version 3.42.0: Renamed from power_inside_fast_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/multiple_states_flagINT_0D¶Multiple state calculation flag : 0-Only one state is considered; […]
Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)AoS¶Collisional exchange with the various states of the ion species […]
Collisional exchange with the various states of the ion species (ionisation, energy, excitation, …)
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/z_min ⇹eFLT_0D¶Minimum Z of the charge state bundle (z_min = z_max = 0 for a […]
Minimum Z of the charge state bundle (z_min = z_max = 0 for a neutral)
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/z_max ⇹eFLT_0D¶Maximum Z of the charge state bundle (equal to z_min if no bundle)
Maximum Z of the charge state bundle (equal to z_min if no bundle)
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/nameSTR_0D¶String identifying charge state (e.g. […]
String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/electron_configurationSTR_0D¶Configuration of atomic orbitals of this state, e.g. […]
Configuration of atomic orbitals of this state, e.g. 1s2-2s1
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/vibrational_level ⇹eFLT_0D¶Vibrational level (can be bundled)
Vibrational level (can be bundled)
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/vibrational_modeSTR_0D¶Vibrational mode of this state, e.g. […]
Vibrational mode of this state, e.g. “A_g”. Need to define, or adopt a standard nomenclature.
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_density_thermal(:) ⇹W.m^-3FLT_1D¶Flux surface averaged absorbed wave power density on the thermal […]
Flux surface averaged absorbed wave power density on the thermal species
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_density_thermal_n_phi(:,:) ⇹W.m^-3FLT_2D¶Flux surface averaged absorbed wave power density on the thermal […]
Flux surface averaged absorbed wave power density on the thermal species, per toroidal mode number
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Changed in version 3.42.0: Renamed from power_density_thermal_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_density_fast(:) ⇹W.m^-3FLT_1D¶Flux surface averaged absorbed wave power density on the fast […]
Flux surface averaged absorbed wave power density on the fast species
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_density_fast_n_phi(:,:) ⇹W.m^-3FLT_2D¶Flux surface averaged absorbed wave power density on the fast […]
Flux surface averaged absorbed wave power density on the fast species, per toroidal mode number
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Changed in version 3.42.0: Renamed from power_density_fast_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_inside_thermal(:) ⇹WFLT_1D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_inside_thermal_n_phi(:,:) ⇹WFLT_2D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number
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2 |
Changed in version 3.42.0: Renamed from power_inside_thermal_n_tor
coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_inside_fast(:) ⇹WFLT_1D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density)
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coherent_wave(i1)/profiles_1d(itime)/ion(i2)/state(i3)/power_inside_fast_n_phi(:,:) ⇹WFLT_2D¶Absorbed wave power on thermal species inside a flux surface […]
Absorbed wave power on thermal species inside a flux surface (cumulative volume integral of the absorbed power density), per toroidal mode number
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2 |
Changed in version 3.42.0: Renamed from power_inside_fast_n_tor
coherent_wave(i1)/profiles_2d(itime)AoS¶2D profiles in poloidal cross-section, for various time slices
2D profiles in poloidal cross-section, for various time slices
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coherent_wave(i1)/profiles_2d(itime)/gridstructure¶2D grid in a poloidal cross-section
2D grid in a poloidal cross-section
coherent_wave(i1)/profiles_2d(itime)/grid/typestructure¶Grid type: index=0: Rectangular grid in the (R,Z) coordinates; […]
Grid type: index=0: Rectangular grid in the (R,Z) coordinates; index=1: Rectangular grid in the (radial, theta_geometric) coordinates; index=2: Rectangular grid in the (radial, theta_straight) coordinates. index=3: unstructured grid.
coherent_wave(i1)/profiles_2d(itime)/grid/type/nameSTR_0D¶Short string identifier
Short string identifier
coherent_wave(i1)/profiles_2d(itime)/grid/z(:,:) ⇹mFLT_2D¶Height
Height
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2 |
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coherent_wave(i1)/profiles_2d(itime)/grid/theta_straight(:,:) ⇹radFLT_2D¶Straight field line poloidal angle
Straight field line poloidal angle
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2 |
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coherent_wave(i1)/profiles_2d(itime)/grid/theta_geometric(:,:) ⇹radFLT_2D¶Geometrical poloidal angle
Geometrical poloidal angle
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2 |
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coherent_wave(i1)/profiles_2d(itime)/grid/rho_tor_norm(:,:) ⇹1FLT_2D¶Normalized toroidal flux coordinate. […]
Normalized toroidal flux coordinate. The normalizing value for rho_tor_norm, is the toroidal flux coordinate at the equilibrium boundary (LCFS or 99.x % of the LCFS in case of a fixed boundary equilibium calculation)
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2 |
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coherent_wave(i1)/profiles_2d(itime)/grid/rho_tor(:,:) ⇹mFLT_2D¶Toroidal flux coordinate. […]
Toroidal flux coordinate. The toroidal field used in its definition is indicated under vacuum_toroidal_field/b0
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2 |
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coherent_wave(i1)/profiles_2d(itime)/grid/psi(:,:) ⇹WbFLT_2D¶Poloidal magnetic flux
Poloidal magnetic flux
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2 |
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coherent_wave(i1)/profiles_2d(itime)/grid/volume(:,:) ⇹m^3FLT_2D¶Volume enclosed inside the magnetic surface
Volume enclosed inside the magnetic surface
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2 |
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coherent_wave(i1)/profiles_2d(itime)/grid/area(:,:) ⇹m^2FLT_2D¶Cross-sectional area of the flux surface
Cross-sectional area of the flux surface
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2 |
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coherent_wave(i1)/profiles_2d(itime)/n_phi(:)INT_1D¶Toroidal mode numbers, the wave vector toroidal component being […]
Toroidal mode numbers, the wave vector toroidal component being defined as k_phi = n_phi grad phi where phi is the toroidal angle so that a positive n_phi means a wave propagating in the positive phi direction
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Changed in version 3.42.0: Renamed from n_tor
coherent_wave(i1)/profiles_2d(itime)/power_density(:,:) ⇹W.m^-3FLT_2D¶Total absorbed wave power density (electrons + ion + fast populations)
Total absorbed wave power density (electrons + ion + fast populations)
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2 |
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coherent_wave(i1)/profiles_2d(itime)/power_density_n_phi(:,:,:) ⇹W.m^-3FLT_3D¶Absorbed wave power density per toroidal mode number
Absorbed wave power density per toroidal mode number
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2 |
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3 |
Changed in version 3.42.0: Renamed from power_density_n_tor
coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)AoS¶Components of the electric field per toroidal mode number
Components of the electric field per toroidal mode number
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Changed in version 3.42.0: Renamed from e_field_n_tor
coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/plusV.m^-1structure¶Left hand polarized electric field component
Left hand polarized electric field component
coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/plus/amplitude(:,:) ⇹V.m^-1FLT_2D¶Amplitude
Amplitude
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2 |
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coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/plus/phase(:,:) ⇹V.m^-1FLT_2D¶Phase
Phase
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2 |
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coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/minusV.m^-1structure¶Right hand polarized electric field component
Right hand polarized electric field component
coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/minus/amplitude(:,:) ⇹V.m^-1FLT_2D¶Amplitude
Amplitude
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2 |
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coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/minus/phase(:,:) ⇹V.m^-1FLT_2D¶Phase
Phase
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2 |
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coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/parallelV.m^-1structure¶Parallel electric field component
Parallel electric field component
coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/parallel/amplitude(:,:) ⇹V.m^-1FLT_2D¶Amplitude
Amplitude
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2 |
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coherent_wave(i1)/profiles_2d(itime)/e_field_n_phi(i2)/parallel/phase(:,:) ⇹V.m^-1FLT_2D¶Phase
Phase
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2 |
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coherent_wave(i1)/profiles_2d(itime)/electronsstructure¶Quantities related to the electrons
Quantities related to the electrons
coherent_wave(i1)/profiles_2d(itime)/electrons/power_density_thermal(:,:) ⇹W.m^-3FLT_2D¶Absorbed wave power density on the thermal species
Absorbed wave power density on the thermal species
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2 |
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coherent_wave(i1)/profiles_2d(itime)/electrons/power_density_thermal_n_phi(:,:,:) ⇹W.m^-3FLT_3D¶Absorbed wave power density on the thermal species, per toroidal […]
Absorbed wave power density on the thermal species, per toroidal mode number
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2 |
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3 |
Changed in version 3.42.0: Renamed from power_density_thermal_n_tor
coherent_wave(i1)/profiles_2d(itime)/electrons/power_density_fast(:,:) ⇹W.m^-3FLT_2D¶Absorbed wave power density on the fast species
Absorbed wave power density on the fast species
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2 |
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coherent_wave(i1)/profiles_2d(itime)/electrons/power_density_fast_n_phi(:,:,:) ⇹W.m^-3FLT_3D¶Absorbed wave power density on the fast species, per toroidal […]
Absorbed wave power density on the fast species, per toroidal mode number
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2 |
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3 |
Changed in version 3.42.0: Renamed from power_density_fast_n_tor
coherent_wave(i1)/profiles_2d(itime)/ion(i2)AoS¶Quantities related to the different ion species
Quantities related to the different ion species
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coherent_wave(i1)/profiles_2d(itime)/ion(i2)/element(i3)AoS¶List of elements forming the atom or molecule
List of elements forming the atom or molecule
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coherent_wave(i1)/profiles_2d(itime)/ion(i2)/z_ion ⇹eFLT_0D¶Ion charge (of the dominant ionisation state; lumped ions are […]
Ion charge (of the dominant ionisation state; lumped ions are allowed).
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/nameSTR_0D¶String identifying the species (e.g. […]
String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/power_density_thermal(:,:) ⇹W.m^-3FLT_2D¶Absorbed wave power density on the thermal species
Absorbed wave power density on the thermal species
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2 |
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coherent_wave(i1)/profiles_2d(itime)/ion(i2)/power_density_thermal_n_phi(:,:,:) ⇹W.m^-3FLT_3D¶Absorbed wave power density on the thermal species, per toroidal […]
Absorbed wave power density on the thermal species, per toroidal mode number
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2 |
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3 |
Changed in version 3.42.0: Renamed from power_density_thermal_n_tor
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/power_density_fast(:,:) ⇹W.m^-3FLT_2D¶Absorbed wave power density on the fast species
Absorbed wave power density on the fast species
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2 |
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coherent_wave(i1)/profiles_2d(itime)/ion(i2)/power_density_fast_n_phi(:,:,:) ⇹W.m^-3FLT_3D¶Absorbed wave power density on the fast species, per toroidal […]
Absorbed wave power density on the fast species, per toroidal mode number
1 |
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2 |
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3 |
Changed in version 3.42.0: Renamed from power_density_fast_n_tor
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/multiple_states_flagINT_0D¶Multiple state calculation flag : 0-Only one state is considered; […]
Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)AoS¶Collisional exchange with the various states of the ion species […]
Collisional exchange with the various states of the ion species (ionisation, energy, excitation, …)
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coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/z_min ⇹eFLT_0D¶Minimum Z of the charge state bundle (z_min = z_max = 0 for a […]
Minimum Z of the charge state bundle (z_min = z_max = 0 for a neutral)
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/z_max ⇹eFLT_0D¶Maximum Z of the charge state bundle (equal to z_min if no bundle)
Maximum Z of the charge state bundle (equal to z_min if no bundle)
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/nameSTR_0D¶String identifying charge state (e.g. […]
String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/electron_configurationSTR_0D¶Configuration of atomic orbitals of this state, e.g. […]
Configuration of atomic orbitals of this state, e.g. 1s2-2s1
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/vibrational_level ⇹eFLT_0D¶Vibrational level (can be bundled)
Vibrational level (can be bundled)
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/vibrational_modeSTR_0D¶Vibrational mode of this state, e.g. […]
Vibrational mode of this state, e.g. “A_g”. Need to define, or adopt a standard nomenclature.
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/power_density_thermal(:,:) ⇹W.m^-3FLT_2D¶Absorbed wave power density on the thermal species
Absorbed wave power density on the thermal species
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2 |
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coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/power_density_thermal_n_phi(:,:,:) ⇹W.m^-3FLT_3D¶Absorbed wave power density on the thermal species, per toroidal […]
Absorbed wave power density on the thermal species, per toroidal mode number
1 |
|
2 |
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3 |
Changed in version 3.42.0: Renamed from power_density_thermal_n_tor
coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/power_density_fast(:,:) ⇹W.m^-3FLT_2D¶Absorbed wave power density on the fast species
Absorbed wave power density on the fast species
1 |
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2 |
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coherent_wave(i1)/profiles_2d(itime)/ion(i2)/state(i3)/power_density_fast_n_phi(:,:,:) ⇹W.m^-3FLT_3D¶Absorbed wave power density on the fast species, per toroidal […]
Absorbed wave power density on the fast species, per toroidal mode number
1 |
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2 |
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3 |
Changed in version 3.42.0: Renamed from power_density_fast_n_tor
coherent_wave(i1)/beam_tracing(itime)AoS¶Beam tracing calculations, for various time slices
Beam tracing calculations, for various time slices
1 |
coherent_wave(i1)/beam_tracing(itime)/beam(i2)AoS¶Set of rays/beams describing the wave propagation
Set of rays/beams describing the wave propagation
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/power_initial ⇹WFLT_0D¶Initial power in the ray/beam
Initial power in the ray/beam
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/length(:) ⇹mFLT_1D¶Ray/beam curvilinear length
Ray/beam curvilinear length
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/positionstructure¶Position of the ray/beam along its path
Position of the ray/beam along its path
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/position/phi(:) ⇹radFLT_1D¶Toroidal angle
Toroidal angle
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/position/psi(:) ⇹WbFLT_1D¶Poloidal flux
Poloidal flux
1 |
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/position/rho_tor_norm(:) ⇹1FLT_1D¶Normalised toroidal flux coordinate
Normalised toroidal flux coordinate
1 |
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/position/theta(:) ⇹radFLT_1D¶Poloidal angle (oriented clockwise when viewing the poloidal […]
Poloidal angle (oriented clockwise when viewing the poloidal cross section on the right hand side of the tokamak axis of symmetry, with the origin placed on the plasma magnetic axis)
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vectorstructure¶Wave vector of the ray/beam along its path
Wave vector of the ray/beam along its path
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/k_r(:) ⇹m^-1FLT_1D¶Wave vector component in the major radius direction
Wave vector component in the major radius direction
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/k_z(:) ⇹m^-1FLT_1D¶Wave vector component in the vertical direction
Wave vector component in the vertical direction
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/k_phi(:) ⇹m^-1FLT_1D¶Wave vector component in the toroidal direction
Wave vector component in the toroidal direction
1 |
Changed in version 3.42.0: Renamed from k_tor
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/k_r_norm(:) ⇹1FLT_1D¶Normalized wave vector component in the major radius direction […]
Normalized wave vector component in the major radius direction = k_r / norm(k)
1 |
New in version >3.38.1.
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/k_z_norm(:) ⇹1FLT_1D¶Normalized wave vector component in the vertical direction = […]
Normalized wave vector component in the vertical direction = k_z / norm(k)
1 |
New in version >3.38.1.
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/k_phi_norm(:) ⇹1FLT_1D¶Normalized wave vector component in the toroidal direction = […]
Normalized wave vector component in the toroidal direction = k_phi / norm(k)
1 |
Changed in version 3.42.0: Renamed from k_tor_norm
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/n_parallel(:) ⇹1FLT_1D¶Parallel refractive index
Parallel refractive index
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/n_perpendicular(:) ⇹1FLT_1D¶Perpendicular refractive index
Perpendicular refractive index
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/wave_vector/n_phi(:)INT_1D¶Toroidal wave number, contains a single value if varying_n_phi […]
Toroidal wave number, contains a single value if varying_n_phi = 0 to avoid useless repetition of constant values. The wave vector toroidal component is defined as k_phi = n_phi grad phi where phi is the toroidal angle so that a positive n_phi means a wave propagating in the positive phi direction
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Changed in version 3.42.0: Renamed from n_tor
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/e_fieldstructure¶Electric field polarization of the ray/beam along its path
Electric field polarization of the ray/beam along its path
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/e_field/plusV.m^-1structure¶Left hand polarised electric field component
Left hand polarised electric field component
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/e_field/plus/real(:) ⇹V.m^-1FLT_1D¶Real part
Real part
1 |
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/e_field/minusV.m^-1structure¶Right hand polarised electric field component
Right hand polarised electric field component
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/e_field/minus/real(:) ⇹V.m^-1FLT_1D¶Real part
Real part
1 |
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/e_field/parallelV.m^-1structure¶Parallel to magnetic field polarised electric field component
Parallel to magnetic field polarised electric field component
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/e_field/parallel/real(:) ⇹V.m^-1FLT_1D¶Real part
Real part
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/power_flow_normstructure¶Normalized power flow
Normalized power flow
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/power_flow_norm/perpendicular(:) ⇹1FLT_1D¶Normalized power flow in the direction perpendicular to the magnetic […]
Normalized power flow in the direction perpendicular to the magnetic field
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/electronsstructure¶Quantities related to the electrons
Quantities related to the electrons
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)AoS¶Quantities related to the different ion species
Quantities related to the different ion species
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/element(i4)AoS¶List of elements forming the atom or molecule
List of elements forming the atom or molecule
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/element(i4)/a ⇹uFLT_0D¶Mass of atom
Mass of atom
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/z_ion ⇹eFLT_0D¶Ion charge (of the dominant ionisation state; lumped ions are […]
Ion charge (of the dominant ionisation state; lumped ions are allowed).
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/nameSTR_0D¶String identifying the species (e.g. […]
String identifying the species (e.g. H+, D+, T+, He+2, C+, D2, DT, CD4, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/power(:) ⇹WFLT_1D¶Power absorbed along the beam by the species
Power absorbed along the beam by the species
1 |
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/multiple_states_flagINT_0D¶Multiple state calculation flag : 0-Only one state is considered; […]
Multiple state calculation flag : 0-Only one state is considered; 1-Multiple states are considered and are described in the state structure
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/state(i4)AoS¶Collisional exchange with the various states of the ion species […]
Collisional exchange with the various states of the ion species (ionisation, energy, excitation, …)
1 |
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/state(i4)/z_min ⇹eFLT_0D¶Minimum Z of the charge state bundle (z_min = z_max = 0 for a […]
Minimum Z of the charge state bundle (z_min = z_max = 0 for a neutral)
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/state(i4)/z_max ⇹eFLT_0D¶Maximum Z of the charge state bundle (equal to z_min if no bundle)
Maximum Z of the charge state bundle (equal to z_min if no bundle)
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/state(i4)/nameSTR_0D¶String identifying charge state (e.g. […]
String identifying charge state (e.g. C+, C+2 , C+3, C+4, C+5, C+6, …)
Changed in version 3.42.0: Renamed from label
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/state(i4)/electron_configurationSTR_0D¶Configuration of atomic orbitals of this state, e.g. […]
Configuration of atomic orbitals of this state, e.g. 1s2-2s1
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/state(i4)/vibrational_level ⇹eFLT_0D¶Vibrational level (can be bundled)
Vibrational level (can be bundled)
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/ion(i3)/state(i4)/vibrational_modeSTR_0D¶Vibrational mode of this state, e.g. […]
Vibrational mode of this state, e.g. “A_g”. Need to define, or adopt a standard nomenclature.
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/spotstructure¶Spot ellipse characteristics
Spot ellipse characteristics
New in version >3.38.1.
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/spot/size(:,:) ⇹mFLT_2D¶Size of the spot ellipse: distance between the central ray and […]
Size of the spot ellipse: distance between the central ray and the peripheral rays in the horizontal (first index of the first coordinate) and vertical direction (second index of the first coordinate)
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coherent_wave(i1)/beam_tracing(itime)/beam(i2)/phasestructure¶Phase ellipse characteristics
Phase ellipse characteristics
New in version >3.38.1.
coherent_wave(i1)/beam_tracing(itime)/beam(i2)/phase/curvature(:,:) ⇹m^-1FLT_2D¶Inverse curvature radii for the phase ellipse, positive/negative […]
Inverse curvature radii for the phase ellipse, positive/negative for divergent/convergent beams, in the horizontal direction (first index of the first coordinate) and in the vertical direction (second index of the first coordinate)
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coherent_wave(i1)/full_wave(itime)AoS¶Solution by a full wave code, given on a generic grid description, […]
Solution by a full wave code, given on a generic grid description, for various time slices
1 |
coherent_wave(i1)/full_wave(itime)/gridstructure¶Grid description
Grid description
coherent_wave(i1)/full_wave(itime)/grid/identifierstructure¶Grid identifier
Grid identifier
This is an identifier. See ggd_identifier for the available options.
coherent_wave(i1)/full_wave(itime)/grid/identifier/nameSTR_0D¶Short string identifier
Short string identifier
coherent_wave(i1)/full_wave(itime)/grid/pathSTR_0D¶Path of the grid, including the IDS name, in case of implicit […]
Path of the grid, including the IDS name, in case of implicit reference to a grid_ggd node described in another IDS. To be filled only if the grid is not described explicitly in this grid_ggd structure. Example syntax: #wall:2/description_ggd(1)/grid_ggd, means that the grid is located in the wall IDS, occurrence 2, with relative path description_ggd(1)/grid_ggd, using Fortran index convention (here : first index of the array)
coherent_wave(i1)/full_wave(itime)/grid/space(i2)AoS¶Set of grid spaces
Set of grid spaces
Click here for further documentation (or contact imas@iter.org if you can’t access this page).
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coherent_wave(i1)/full_wave(itime)/grid/space(i2)/identifierstructure¶Space identifier
Space identifier
This is an identifier. See ggd_space_identifier for the available options.
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/identifier/nameSTR_0D¶Short string identifier
Short string identifier
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/geometry_typestructure¶Type of space geometry (0: standard, 1:Fourier, >1: Fourier with […]
Type of space geometry (0: standard, 1:Fourier, >1: Fourier with periodicity)
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/geometry_type/nameSTR_0D¶Short string identifier
Short string identifier
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/coordinates_type(i3)AoS¶Type of coordinates describing the physical space, for every […]
Type of coordinates describing the physical space, for every coordinate of the space. The size of this node therefore defines the dimension of the space.
This is an identifier. See coordinate_identifier for the available options.
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Changed in version 4.0.0: Type changed from INT_1D
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/coordinates_type(i3)/nameSTR_0D¶Short string identifier
Short string identifier
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)AoS¶Definition of the space objects for every dimension (from one […]
Definition of the space objects for every dimension (from one to the dimension of the highest-dimensional objects). The index correspond to 1=nodes, 2=edges, 3=faces, 4=cells/volumes, …. For every index, a collection of objects of that dimension is described.
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coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)AoS¶Set of objects for a given dimension
Set of objects for a given dimension
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coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)/boundary(i5)AoS¶Set of (n-1)-dimensional objects defining the boundary of this […]
Set of (n-1)-dimensional objects defining the boundary of this n-dimensional object
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coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)/boundary(i5)/indexINT_0D¶Index of this (n-1)-dimensional boundary object
Index of this (n-1)-dimensional boundary object
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)/boundary(i5)/neighbours(:)INT_1D¶List of indices of the n-dimensional objects adjacent to the […]
List of indices of the n-dimensional objects adjacent to the given n-dimensional object. An object can possibly have multiple neighbours on a boundary
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coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)/geometry(:)mixedFLT_1D¶Geometry data associated with the object, its detailed content […]
Geometry data associated with the object, its detailed content is defined by ../../geometry_content. Its dimension depends on the type of object, geometry and coordinate considered.
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coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)/nodes(:)INT_1D¶List of nodes forming this object (indices to objects_per_dimension(1)%object(:) […]
List of nodes forming this object (indices to objects_per_dimension(1)%object(:) in Fortran notation)
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coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)/measurem^dimensionFLT_0D¶Measure of the space object, i.e. […]
Measure of the space object, i.e. physical size (length for 1d, area for 2d, volume for 3d objects,…)
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/object(i4)/geometry_2d(:,:)mixedFLT_2D¶2D geometry data associated with the object. […]
2D geometry data associated with the object. Its dimension depends on the type of object, geometry and coordinate considered. Typically, the first dimension represents the object coordinates, while the second dimension would represent the values of the various degrees of freedom of the finite element attached to the object.
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New in version >3.35.0.
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/geometry_contentstructure¶Content of the ../object/geometry node for this dimension
Content of the ../object/geometry node for this dimension
This is an identifier. See ggd_geometry_content_identifier for the available options.
New in version >3.33.0.
coherent_wave(i1)/full_wave(itime)/grid/space(i2)/objects_per_dimension(i3)/geometry_content/nameSTR_0D¶Short string identifier
Short string identifier
coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)AoS¶Grid subsets
Grid subsets
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/identifierstructure¶Grid subset identifier
Grid subset identifier
Click here for further documentation.
This is an identifier. See ggd_subset_identifier for the available options.
coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/identifier/nameSTR_0D¶Short string identifier
Short string identifier
coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/dimensionINT_0D¶Space dimension of the grid subset elements, using the convention […]
Space dimension of the grid subset elements, using the convention 1=nodes, 2=edges, 3=faces, 4=cells/volumes
coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/element(i3)AoS¶Set of elements defining the grid subset. […]
Set of elements defining the grid subset. An element is defined by a combination of objects from potentially all spaces
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/element(i3)/object(i4)AoS¶Set of objects defining the element
Set of objects defining the element
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/element(i3)/object(i4)/spaceINT_0D¶Index of the space from which that object is taken
Index of the space from which that object is taken
coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/base(i3)AoS¶Set of bases for the grid subset. […]
Set of bases for the grid subset. For each base, the structure describes the projection of the base vectors on the canonical frame of the grid.
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/base(i3)/jacobian(:) ⇹mixedFLT_1D¶Metric Jacobian
Metric Jacobian
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/base(i3)/tensor_covariant(:,:,:) ⇹mixedFLT_3D¶Covariant metric tensor, given on each element of the subgrid […]
Covariant metric tensor, given on each element of the subgrid (first dimension)
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/base(i3)/tensor_contravariant(:,:,:) ⇹mixedFLT_3D¶Contravariant metric tensor, given on each element of the subgrid […]
Contravariant metric tensor, given on each element of the subgrid (first dimension)
coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/metricstructure¶Metric of the canonical frame onto Cartesian coordinates
Metric of the canonical frame onto Cartesian coordinates
coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/metric/jacobian(:) ⇹mixedFLT_1D¶Metric Jacobian
Metric Jacobian
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/metric/tensor_covariant(:,:,:) ⇹mixedFLT_3D¶Covariant metric tensor, given on each element of the subgrid […]
Covariant metric tensor, given on each element of the subgrid (first dimension)
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coherent_wave(i1)/full_wave(itime)/grid/grid_subset(i2)/metric/tensor_contravariant(:,:,:) ⇹mixedFLT_3D¶Contravariant metric tensor, given on each element of the subgrid […]
Contravariant metric tensor, given on each element of the subgrid (first dimension)
coherent_wave(i1)/full_wave(itime)/e_fieldstructure¶Components of the wave electric field, represented as Fourier […]
Components of the wave electric field, represented as Fourier coefficients E(n_tor,frequency) such that the electric is equal to real(E(n_tor,frequency).exp(i(n_tor.phi - 2.pi.frequency.t)))
coherent_wave(i1)/full_wave(itime)/e_field/plus(i2)V.m^-1AoS¶Left hand circularly polarized component of the perpendicular […]
Left hand circularly polarized component of the perpendicular (to the static magnetic field) electric field, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/e_field/plus(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/e_field/plus(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/e_field/plus(i2)/values(:) ⇹V.m^-1CPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/e_field/plus(i2)/coefficients(:,:) ⇹V.m^-1CPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/e_field/minus(i2)V.m^-1AoS¶Right hand circularly polarized component of the perpendicular […]
Right hand circularly polarized component of the perpendicular (to the static magnetic field) electric field, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/e_field/minus(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/e_field/minus(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/e_field/minus(i2)/values(:) ⇹V.m^-1CPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/e_field/minus(i2)/coefficients(:,:) ⇹V.m^-1CPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/e_field/parallel(i2)V.m^-1AoS¶Parallel (to the static magnetic field) component of electric […]
Parallel (to the static magnetic field) component of electric field, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/e_field/parallel(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/e_field/parallel(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/e_field/parallel(i2)/values(:) ⇹V.m^-1CPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/e_field/parallel(i2)/coefficients(:,:) ⇹V.m^-1CPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/e_field/normal(i2)V.m^-1AoS¶Magnitude of wave electric field normal to a flux surface, given […]
Magnitude of wave electric field normal to a flux surface, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/e_field/normal(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/e_field/normal(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/e_field/normal(i2)/values(:) ⇹V.m^-1CPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/e_field/normal(i2)/coefficients(:,:) ⇹V.m^-1CPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/e_field/bi_normal(i2)V.m^-1AoS¶Magnitude of perpendicular (to the static magnetic field) wave […]
Magnitude of perpendicular (to the static magnetic field) wave electric field tangent to a flux surface, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/e_field/bi_normal(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/e_field/bi_normal(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/e_field/bi_normal(i2)/values(:) ⇹V.m^-1CPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/e_field/bi_normal(i2)/coefficients(:,:) ⇹V.m^-1CPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/b_fieldstructure¶Components of the wave magnetic field, , represented as Fourier […]
Components of the wave magnetic field, , represented as Fourier coefficients B(n_tor,frequency) such that the electric is equal to real(B(n_tor,frequency).exp(i(n_tor.phi - 2.pi.frequency.t)))
coherent_wave(i1)/full_wave(itime)/b_field/parallel(i2)TAoS¶Parallel (to the static magnetic field) component of the wave […]
Parallel (to the static magnetic field) component of the wave magnetic field, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/b_field/parallel(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/b_field/parallel(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/b_field/parallel(i2)/values(:) ⇹TCPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/b_field/parallel(i2)/coefficients(:,:) ⇹TCPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/b_field/normal(i2)TAoS¶Magnitude of wave magnetic field normal to a flux surface, given […]
Magnitude of wave magnetic field normal to a flux surface, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/b_field/normal(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/b_field/normal(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/b_field/normal(i2)/values(:) ⇹TCPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/b_field/normal(i2)/coefficients(:,:) ⇹TCPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/b_field/bi_normal(i2)TAoS¶Magnitude of perpendicular (to the static magnetic field) wave […]
Magnitude of perpendicular (to the static magnetic field) wave magnetic field tangent to a flux surface, given on various grid subsets
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Changed in version 3.39.0: Type changed from generic_grid_scalar
coherent_wave(i1)/full_wave(itime)/b_field/bi_normal(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/b_field/bi_normal(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on
Index of the grid subset the data is provided on
coherent_wave(i1)/full_wave(itime)/b_field/bi_normal(i2)/values(:) ⇹TCPX_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/b_field/bi_normal(i2)/coefficients(:,:) ⇹TCPX_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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coherent_wave(i1)/full_wave(itime)/k_perpendicular(i2)V.m^-1AoS¶Perpendicular wave vector, given on various grid subsets
Perpendicular wave vector, given on various grid subsets
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coherent_wave(i1)/full_wave(itime)/k_perpendicular(i2)/grid_indexINT_0D¶Index of the grid used to represent this quantity
Index of the grid used to represent this quantity
coherent_wave(i1)/full_wave(itime)/k_perpendicular(i2)/grid_subset_indexINT_0D¶Index of the grid subset the data is provided on. […]
Index of the grid subset the data is provided on. Corresponds to the index used in the grid subset definition: grid_subset(:)/identifier/index
coherent_wave(i1)/full_wave(itime)/k_perpendicular(i2)/values(:) ⇹V.m^-1FLT_1D¶One scalar value is provided per element in the grid subset.
One scalar value is provided per element in the grid subset.
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coherent_wave(i1)/full_wave(itime)/k_perpendicular(i2)/coefficients(:,:) ⇹V.m^-1FLT_2D¶Interpolation coefficients, to be used for a high precision evaluation […]
Interpolation coefficients, to be used for a high precision evaluation of the physical quantity with finite elements, provided per element in the grid subset (first dimension).
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vacuum_toroidal_fieldstructure¶Characteristics of the vacuum toroidal field (used in rho_tor […]
Characteristics of the vacuum toroidal field (used in rho_tor definition)
vacuum_toroidal_field/r0 ⇹mFLT_0D¶Reference major radius where the vacuum toroidal magnetic field […]
Reference major radius where the vacuum toroidal magnetic field is given (usually a fixed position such as the middle of the vessel at the equatorial midplane)