camera_ir - IMAS Data Dictionary documentation

See common IDS structure reference: ids_properties.

channel(i1)AoS ¶Set of channels (line of sight, viewing the plasma recorded by […]

Set of channels (line of sight, viewing the plasma recorded by one or more cameras e.g. for different wavelength ranges)

Maximum occurrences (MDS+ backend only): 20

	Coordinate
1	`1...N`

New in version >4.1.0.

channel(i1)/name STR_0D ¶Name of the channel

Name of the channel

channel(i1)/camera(i2)AoS ¶Set of cameras

Set of cameras

Maximum occurrences (MDS+ backend only): 5

	Coordinate
1	`1...N`

channel(i1)/camera(i2)/name STR_0D ¶Name of the detector

Name of the detector

channel(i1)/camera(i2)/calibrationstructure ¶Calibration data

Calibration data

channel(i1)/camera(i2)/calibration/luminance_to_temperature(:,:)INT_2D ¶Luminance to temperature conversion table

Luminance to temperature conversion table

	Coordinate
1	`1...N`
2	`1...2`

channel(i1)/camera(i2)/calibration/transmission_barrel(:,:)INT_2D ¶Transmission of the optical barrel

Transmission of the optical barrel

	Coordinate
1	`1...N` (same as `channel(i1)/camera(i2)/frame(1)/apparent_temperature`)
2	`1...N` (same as `channel(i1)/camera(i2)/frame(1)/apparent_temperature`)

channel(i1)/camera(i2)/calibration/transmission_mirror(:,:)INT_2D ¶Transmission of the mirror

Transmission of the mirror

	Coordinate
1	`1...N` (same as `channel(i1)/camera(i2)/frame(1)/apparent_temperature`)
2	`1...N` (same as `channel(i1)/camera(i2)/frame(1)/apparent_temperature`)

channel(i1)/camera(i2)/calibration/transmission_window(:,:)INT_2D ¶Transmission of the window

Transmission of the window

	Coordinate
1	`1...N` (same as `channel(i1)/camera(i2)/frame(1)/apparent_temperature`)
2	`1...N` (same as `channel(i1)/camera(i2)/frame(1)/apparent_temperature`)

channel(i1)/camera(i2)/calibration/optical_temperature(:,:)INT_2D ¶Temperature of the optical components (digital levels)

Temperature of the optical components (digital levels)

	Coordinate
1	`1...N`
2	`1...N`

channel(i1)/camera(i2)/frame(itime)AoS ¶Set of frames

Set of frames

	Coordinate
1	`channel(i1)/camera(i2)/frame(itime)/time`

channel(i1)/camera(i2)/frame(itime)/apparent_temperature(:,:) ⇹KFLT_2D ¶Processed image in apparent temperature. […]

Processed image in apparent temperature. First dimension : row index (horizontal orientation). Second dimension: column index (vertical orientation). The size of this matrix is assumed to be constant over time

	Coordinate
1	`1...N`
2	`1...N`

channel(i1)/camera(i2)/frame(itime)/integration_time(:,:) ⇹KFLT_2D ¶Integration time per pixel. […]

Integration time per pixel. First dimension : row index (horizontal orientation). Second dimension: column index (vertical orientation). The size of this matrix is assumed to be constant over time. Allocate dimensions to 1 in case of uniform exposure time.

	Coordinate
1	`1...N`
2	`1...N`

channel(i1)/camera(i2)/frame(itime)/filter(i3)AoS ¶Set of filters

Set of filters

	Coordinate
1	`1...N`

channel(i1)/camera(i2)/frame(itime)/filter(i3)/wavelength_central ⇹mFLT_0D ¶Central wavelength of the filter

Central wavelength of the filter

channel(i1)/camera(i2)/frame(itime)/filter(i3)/wavelength_width ⇹mFLT_0D ¶Filter transmission function width (at 90% level)

Filter transmission function width (at 90% level)

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)AoS ¶Set of regions of interest for the real-time monitoring of machine […]

Set of regions of interest for the real-time monitoring of machine protection. Regions of interest are defined by a combination of polygons for each image

	Coordinate
1	`1...N`

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/name STR_0D ¶Short string identifier (unique for a given device)

Short string identifier (unique for a given device)

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/emissivity ⇹1FLT_0D ¶Emissivity of the region of interest

Emissivity of the region of interest

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/surface_area ⇹m^2FLT_0D ¶Area of the region of interest

Area of the region of interest

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/type STR_0D ¶Type of the region of interest usage, physical or operational. […]

Type of the region of interest usage, physical or operational. When operational, it means machine protection is active on this region of interest

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/mask(:,:)INT_2D ¶Mask of the region of interest on the frame (0 = point outside […]

Mask of the region of interest on the frame (0 = point outside the ROI, 1 = point inside the ROI). First dimension : row index (horizontal orientation). Second dimension: column index (vertical orientation)

	Coordinate
1	`1...N` (same as `channel(i1)/camera(i2)/frame(itime)/apparent_temperature`)
2	`1...N` (same as `channel(i1)/camera(i2)/frame(itime)/apparent_temperature`)

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/temperature_limit_maxKFLT_0D ¶Maximum allowed apparent temperature in the region of interest. […]

Maximum allowed apparent temperature in the region of interest. A machine protection message is triggered if this limit is exceeded

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/temperature_max ⇹KFLT_0D ¶Maximum apparent temperature measured in the region of interest

Maximum apparent temperature measured in the region of interest

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/row_index_temperature_max INT_0D ¶Row index with maximum apparent temperature

Row index with maximum apparent temperature

channel(i1)/camera(i2)/frame(itime)/region_of_interest(i3)/column_index_temperature_max INT_0D ¶Column index with maximum apparent temperature

Column index with maximum apparent temperature

channel(i1)/camera(i2)/frame(itime)/timesFLT_0D ¶Time

Time

channel(i1)/camera(i2)/pinholestructure ¶Pinhole position in the (X,Y,Z) coordinate system

Pinhole position in the (X,Y,Z) coordinate system

Click here for further documentation.

channel(i1)/camera(i2)/pinhole/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

channel(i1)/camera(i2)/pinhole/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

channel(i1)/camera(i2)/pinhole/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

channel(i1)/camera(i2)/directionstructure ¶Line of sight direction unit vector

Line of sight direction unit vector

Click here for further documentation.

channel(i1)/camera(i2)/direction/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

channel(i1)/camera(i2)/direction/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

channel(i1)/camera(i2)/direction/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

channel(i1)/camera(i2)/upstructure ¶Detector orientation unit vector

Detector orientation unit vector

Click here for further documentation.

channel(i1)/camera(i2)/up/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

channel(i1)/camera(i2)/up/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

channel(i1)/camera(i2)/up/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

channel(i1)/camera(i2)/pixel_size ⇹mFLT_0D ¶Sensor pixel size (square pixel assumed)

Sensor pixel size (square pixel assumed)

channel(i1)/camera(i2)/field_of_view_horizontal ⇹radFLT_0D ¶Field of view in the horizontal detector plane

Field of view in the horizontal detector plane

channel(i1)/camera(i2)/field_of_view_vertical ⇹radFLT_0D ¶Field of view in the vertical detector plane

Field of view in the vertical detector plane

channel(i1)/camera(i2)/pixels_n_horizontal INT_0D ¶Number of pixels in the horizontal direction (of the detector)

Number of pixels in the horizontal direction (of the detector)

channel(i1)/camera(i2)/pixels_n_vertical INT_0D ¶Number of pixels in the vertical direction (of the detector)

Number of pixels in the vertical direction (of the detector)

channel(i1)/target_surface_centerstructure ¶Position of the center of the targeted surface

Position of the center of the targeted surface

channel(i1)/target_surface_center/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

channel(i1)/target_surface_center/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

channel(i1)/target_surface_center/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

midplanestructure ¶Choice of midplane definition for the mapping of measurements […]

Choice of midplane definition for the mapping of measurements on an equilibrium

This is an identifier. See midplane_identifier for the available options.

New in version >3.32.1.

midplane/name STR_0D ¶Short string identifier

Short string identifier

midplane/index INT_0D ¶Integer identifier (enumeration index within a list). […]

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

midplane/description STR_0D ¶Verbose description

Verbose description

frame_analysis(itime)AoS ¶Quantities deduced from frame analysis for a set of time slices

Quantities deduced from frame analysis for a set of time slices

	Coordinate
1	`frame_analysis(itime)/time`

New in version >3.32.1.

frame_analysis(itime)/sol_heat_decay_length ⇹mFLT_0D ¶Heat flux decay length in SOL at divertor entrance, mapped to […]

Heat flux decay length in SOL at divertor entrance, mapped to the mid-plane, this is the lambda_q parameter defined in reference T. Eich et al, Nucl. Fusion 53 (2013) 093031

frame_analysis(itime)/distance_separatrix_midplane(:) ⇹mFLT_1D ¶Distance between the measurement position and the separatrix, […]

Distance between the measurement position and the separatrix, mapped along flux surfaces to the outboard midplane, in the major radius direction. Positive value means the measurement is outside of the separatrix.

	Coordinate
1	`1...N`

frame_analysis(itime)/power_flux_parallel(:) ⇹W.m^-2FLT_1D ¶Parallel heat flux received by the element monitored by the camera, […]

Parallel heat flux received by the element monitored by the camera, along the distance_separatrix_midplane coordinate

	Coordinate
1	`frame_analysis(itime)/distance_separatrix_midplane`

frame_analysis(itime)/timesFLT_0D ¶Time

Time

optical_element(i1)AoS ¶Set of optical elements

Set of optical elements

Maximum occurrences (MDS+ backend only): 10

	Coordinate
1	`1...N`

New in version >3.38.1.

optical_element(i1)/typestructure ¶Type of optical element. […]

Type of optical element. In case of ‘mirror’ and ‘diaphragm’, the element is described by one ‘front_surface’. In case of ‘lens’, the element is described by ‘front_surface’ and ‘back_surface’.

This is an identifier. See optical_element_identifier for the available options.

optical_element(i1)/type/name STR_0D ¶Short string identifier

Short string identifier

optical_element(i1)/type/index INT_0D ¶Integer identifier (enumeration index within a list). […]

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

optical_element(i1)/type/description STR_0D ¶Verbose description

Verbose description

optical_element(i1)/front_surfacestructure ¶Curvature of the front surface

Curvature of the front surface

optical_element(i1)/front_surface/curvature_typestructure ¶Curvature of the surface

Curvature of the surface

This is an identifier. See curved_object_curvature_identifier for the available options.

optical_element(i1)/front_surface/curvature_type/name STR_0D ¶Short string identifier

Short string identifier

optical_element(i1)/front_surface/curvature_type/index INT_0D ¶Integer identifier (enumeration index within a list). […]

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

optical_element(i1)/front_surface/curvature_type/description STR_0D ¶Verbose description

Verbose description

optical_element(i1)/front_surface/x1_curvature ⇹mFLT_0D ¶Radius of curvature in the X1 direction, to be filled only for […]

Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

optical_element(i1)/front_surface/x2_curvature ⇹mFLT_0D ¶Radius of curvature in the X2 direction, to be filled only for […]

Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

optical_element(i1)/back_surfacestructure ¶Curvature of the front surface

Curvature of the front surface

optical_element(i1)/back_surface/curvature_typestructure ¶Curvature of the surface

Curvature of the surface

This is an identifier. See curved_object_curvature_identifier for the available options.

optical_element(i1)/back_surface/curvature_type/name STR_0D ¶Short string identifier

Short string identifier

optical_element(i1)/back_surface/curvature_type/index INT_0D ¶Integer identifier (enumeration index within a list). […]

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

optical_element(i1)/back_surface/curvature_type/description STR_0D ¶Verbose description

Verbose description

optical_element(i1)/back_surface/x1_curvature ⇹mFLT_0D ¶Radius of curvature in the X1 direction, to be filled only for […]

Radius of curvature in the X1 direction, to be filled only for curvature_type/index = 2, 4 or 5

optical_element(i1)/back_surface/x2_curvature ⇹mFLT_0D ¶Radius of curvature in the X2 direction, to be filled only for […]

Radius of curvature in the X2 direction, to be filled only for curvature_type/index = 3 or 5

optical_element(i1)/thickness ⇹mFLT_0D ¶Distance between front_surface and back_surface along the X3 […]

Distance between front_surface and back_surface along the X3 vector

optical_element(i1)/material_propertiesstructure ¶Material properties of the optical element

Material properties of the optical element

optical_element(i1)/material_properties/typestructure ¶Type of optical element material. […]

Type of optical element material. In case of ‘metal’ refractive_index and extinction_coefficient are used. In case of ‘dielectric’ refractive_index and transmission_coefficient are used.

This is an identifier. See optical_element_material_identifier for the available options.

optical_element(i1)/material_properties/type/name STR_0D ¶Short string identifier

Short string identifier

optical_element(i1)/material_properties/type/index INT_0D ¶Integer identifier (enumeration index within a list). […]

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

optical_element(i1)/material_properties/type/description STR_0D ¶Verbose description

Verbose description

optical_element(i1)/material_properties/wavelengths(:) ⇹mFLT_1D ¶Wavelengths array for refractive_index, extinction_coefficient […]

Wavelengths array for refractive_index, extinction_coefficient and transmission_coefficient

	Coordinate
1	`1...N`

optical_element(i1)/material_properties/refractive_index(:) ⇹1FLT_1D ¶Refractive index (for metal and dielectric)

Refractive index (for metal and dielectric)

	Coordinate
1	`optical_element(i1)/material_properties/wavelengths`

optical_element(i1)/material_properties/extinction_coefficient(:) ⇹1FLT_1D ¶Extinction coefficient (for metal)

Extinction coefficient (for metal)

	Coordinate
1	`optical_element(i1)/material_properties/wavelengths`

optical_element(i1)/material_properties/transmission_coefficient(:) ⇹1FLT_1D ¶Transmission coefficient (for dielectric)

Transmission coefficient (for dielectric)

	Coordinate
1	`optical_element(i1)/material_properties/wavelengths`

optical_element(i1)/material_properties/roughness(:) ⇹1FLT_1D ¶Roughness parameter of the material. […]

Roughness parameter of the material. Varies in range [0, 1]. 0 is perfectly specular, 1 is perfectly rough

	Coordinate
1	`optical_element(i1)/material_properties/wavelengths`

optical_element(i1)/geometrystructure ¶Further geometrical description of the element

Further geometrical description of the element

optical_element(i1)/geometry/geometry_type INT_0D ¶Type of geometry used to describe the surface of the detector […]

Type of geometry used to describe the surface of the detector or aperture (1:’outline’, 2:’circular’, 3:’rectangle’). In case of ‘outline’, the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of ‘circular’, the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of ‘rectangle’, the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

optical_element(i1)/geometry/centrestructure ¶If geometry_type=2, coordinates of the centre of the circle. […]

If geometry_type=2, coordinates of the centre of the circle. If geometry_type=1 or 3, coordinates of the origin of the local coordinate system (X1,X2,X3) describing the plane detector/aperture. This origin is located within the detector/aperture area.

optical_element(i1)/geometry/centre/r ⇹mFLT_0D ¶Major radius

Major radius

optical_element(i1)/geometry/centre/phi ⇹radFLT_0D ¶Toroidal angle (oriented counter-clockwise when viewing from […]

Toroidal angle (oriented counter-clockwise when viewing from above)

optical_element(i1)/geometry/centre/z ⇹mFLT_0D ¶Height

Height

optical_element(i1)/geometry/radius ⇹mFLT_0D ¶Radius of the circle, used only if geometry_type = 2

Radius of the circle, used only if geometry_type = 2

optical_element(i1)/geometry/x1_unit_vectorstructure ¶Components of the X1 direction unit vector in the (X,Y,Z) coordinate […]

Components of the X1 direction unit vector in the (X,Y,Z) coordinate system, where X is the major radius axis for phi = 0, Y is the major radius axis for phi = pi/2, and Z is the height axis. The X1 vector is more horizontal than X2 (has a smaller abs(Z) component) and oriented in the positive phi direction (counter-clockwise when viewing from above).

Click here for further documentation.

optical_element(i1)/geometry/x1_unit_vector/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

optical_element(i1)/geometry/x1_unit_vector/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

optical_element(i1)/geometry/x1_unit_vector/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

optical_element(i1)/geometry/x2_unit_vectorstructure ¶Components of the X2 direction unit vector in the (X,Y,Z) coordinate […]

Components of the X2 direction unit vector in the (X,Y,Z) coordinate system, where X is the major radius axis for phi = 0, Y is the major radius axis for phi = pi/2, and Z is the height axis. The X2 axis is orthonormal so that uX2 = uX3 x uX1.

Click here for further documentation.

optical_element(i1)/geometry/x2_unit_vector/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

optical_element(i1)/geometry/x2_unit_vector/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

optical_element(i1)/geometry/x2_unit_vector/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

optical_element(i1)/geometry/x3_unit_vectorstructure ¶Components of the X3 direction unit vector in the (X,Y,Z) coordinate […]

Components of the X3 direction unit vector in the (X,Y,Z) coordinate system, where X is the major radius axis for phi = 0, Y is the major radius axis for phi = pi/2, and Z is the height axis. The X3 axis is normal to the detector/aperture plane and oriented towards the plasma.

Click here for further documentation.

optical_element(i1)/geometry/x3_unit_vector/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

optical_element(i1)/geometry/x3_unit_vector/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

optical_element(i1)/geometry/x3_unit_vector/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

optical_element(i1)/geometry/x1_width ⇹mFLT_0D ¶Full width of the aperture in the X1 direction, used only if […]

Full width of the aperture in the X1 direction, used only if geometry_type = 3

optical_element(i1)/geometry/x2_width ⇹mFLT_0D ¶Full width of the aperture in the X2 direction, used only if […]

Full width of the aperture in the X2 direction, used only if geometry_type = 3

optical_element(i1)/geometry/outlinestructure ¶Irregular outline of the detector/aperture in the (X1, X2) coordinate […]

Irregular outline of the detector/aperture in the (X1, X2) coordinate system. Repeat the first point since this is a closed contour

Changed in version 4: Since this describes a closed countour first point must now be repeated at the end of the coordinate arrays of the children

optical_element(i1)/geometry/outline/x1(:) ⇹mFLT_1D ¶Positions along x1 axis

Positions along x1 axis

	Coordinate
1	`1...N`

optical_element(i1)/geometry/outline/x2(:) ⇹mFLT_1D ¶Positions along x2 axis

Positions along x2 axis

	Coordinate
1	`optical_element(i1)/geometry/outline/x1`

optical_element(i1)/geometry/surface ⇹m^2FLT_0D ¶Surface of the detector/aperture, derived from the above geometric […]

Surface of the detector/aperture, derived from the above geometric data

fibre_bundlestructure ¶Description of the fibre bundle

Description of the fibre bundle

New in version >3.38.1.

fibre_bundle/geometrystructure ¶Geometry of the fibre bundle entrance

Geometry of the fibre bundle entrance

fibre_bundle/geometry/geometry_type INT_0D ¶Type of geometry used to describe the surface of the detector […]

Type of geometry used to describe the surface of the detector or aperture (1:’outline’, 2:’circular’, 3:’rectangle’). In case of ‘outline’, the surface is described by an outline of point in a local coordinate system defined by a centre and three unit vectors X1, X2, X3. Note that there is some flexibility here and the data provider should choose the most convenient coordinate system for the object, respecting the definitions of (X1,X2,X3) indicated below. In case of ‘circular’, the surface is a circle defined by its centre, radius, and normal vector oriented towards the plasma X3. In case of ‘rectangle’, the surface is a rectangle defined by its centre, widths in the X1 and X2 directions, and normal vector oriented towards the plasma X3.

fibre_bundle/geometry/centrestructure ¶If geometry_type=2, coordinates of the centre of the circle. […]

If geometry_type=2, coordinates of the centre of the circle. If geometry_type=1 or 3, coordinates of the origin of the local coordinate system (X1,X2,X3) describing the plane detector/aperture. This origin is located within the detector/aperture area.

fibre_bundle/geometry/centre/r ⇹mFLT_0D ¶Major radius

Major radius

fibre_bundle/geometry/centre/phi ⇹radFLT_0D ¶Toroidal angle (oriented counter-clockwise when viewing from […]

Toroidal angle (oriented counter-clockwise when viewing from above)

fibre_bundle/geometry/centre/z ⇹mFLT_0D ¶Height

Height

fibre_bundle/geometry/radius ⇹mFLT_0D ¶Radius of the circle, used only if geometry_type = 2

Radius of the circle, used only if geometry_type = 2

fibre_bundle/geometry/x1_unit_vectorstructure ¶Components of the X1 direction unit vector in the (X,Y,Z) coordinate […]

Components of the X1 direction unit vector in the (X,Y,Z) coordinate system, where X is the major radius axis for phi = 0, Y is the major radius axis for phi = pi/2, and Z is the height axis. The X1 vector is more horizontal than X2 (has a smaller abs(Z) component) and oriented in the positive phi direction (counter-clockwise when viewing from above).

Click here for further documentation.

fibre_bundle/geometry/x1_unit_vector/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

fibre_bundle/geometry/x1_unit_vector/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

fibre_bundle/geometry/x1_unit_vector/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

fibre_bundle/geometry/x2_unit_vectorstructure ¶Components of the X2 direction unit vector in the (X,Y,Z) coordinate […]

Components of the X2 direction unit vector in the (X,Y,Z) coordinate system, where X is the major radius axis for phi = 0, Y is the major radius axis for phi = pi/2, and Z is the height axis. The X2 axis is orthonormal so that uX2 = uX3 x uX1.

Click here for further documentation.

fibre_bundle/geometry/x2_unit_vector/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

fibre_bundle/geometry/x2_unit_vector/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

fibre_bundle/geometry/x2_unit_vector/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

fibre_bundle/geometry/x3_unit_vectorstructure ¶Components of the X3 direction unit vector in the (X,Y,Z) coordinate […]

Components of the X3 direction unit vector in the (X,Y,Z) coordinate system, where X is the major radius axis for phi = 0, Y is the major radius axis for phi = pi/2, and Z is the height axis. The X3 axis is normal to the detector/aperture plane and oriented towards the plasma.

Click here for further documentation.

fibre_bundle/geometry/x3_unit_vector/x ⇹mFLT_0D ¶Component along X axis

Component along X axis

fibre_bundle/geometry/x3_unit_vector/y ⇹mFLT_0D ¶Component along Y axis

Component along Y axis

fibre_bundle/geometry/x3_unit_vector/z ⇹mFLT_0D ¶Component along Z axis

Component along Z axis

fibre_bundle/geometry/x1_width ⇹mFLT_0D ¶Full width of the aperture in the X1 direction, used only if […]

Full width of the aperture in the X1 direction, used only if geometry_type = 3

fibre_bundle/geometry/x2_width ⇹mFLT_0D ¶Full width of the aperture in the X2 direction, used only if […]

Full width of the aperture in the X2 direction, used only if geometry_type = 3

fibre_bundle/geometry/outlinestructure ¶Irregular outline of the detector/aperture in the (X1, X2) coordinate […]

Irregular outline of the detector/aperture in the (X1, X2) coordinate system. Repeat the first point since this is a closed contour

Changed in version 4: Since this describes a closed countour first point must now be repeated at the end of the coordinate arrays of the children

fibre_bundle/geometry/outline/x1(:) ⇹mFLT_1D ¶Positions along x1 axis

Positions along x1 axis

	Coordinate
1	`1...N`

fibre_bundle/geometry/outline/x2(:) ⇹mFLT_1D ¶Positions along x2 axis

Positions along x2 axis

	Coordinate
1	`fibre_bundle/geometry/outline/x1`

fibre_bundle/geometry/surface ⇹m^2FLT_0D ¶Surface of the detector/aperture, derived from the above geometric […]

Surface of the detector/aperture, derived from the above geometric data

fibre_bundle/fibre_radius ⇹mFLT_0D ¶Radius of a single fibre

Radius of a single fibre

fibre_bundle/fibre_positionsstructure ¶Individual fibres centres positions in the (X1, X2) coordinate […]

Individual fibres centres positions in the (X1, X2) coordinate system

fibre_bundle/fibre_positions/x1(:) ⇹mFLT_1D ¶Positions along x1 axis

Positions along x1 axis

	Coordinate
1	`1...N`

fibre_bundle/fibre_positions/x2(:) ⇹mFLT_1D ¶Positions along x2 axis

Positions along x2 axis

	Coordinate
1	`fibre_bundle/fibre_positions/x1`

latency ⇹sFLT_0D ¶Upper bound of the delay between physical information received […]

Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network.

New in version >3.32.1.

codestructure ¶

See common IDS structure reference: code.

time(:)sFLT_1D ¶Generic time

Generic time

	Coordinate
1	`1...N`

camera_ir¶

`camera_ir`¶