camera_visible¶
Camera in the visible light range
Maximum occurrences (MDS+ backend only): 20
New in version 3.27.0: lifecycle status alpha
Changed in version 3.39.0.
ids_propertiesstructure¶
See common IDS structure reference: ids_properties.
channel(i1)AoS¶Set of channels (a front aperture, possibly followed by others, […]
Set of channels (a front aperture, possibly followed by others, viewing the plasma recorded by one or more detectors e.g. for different wavelength ranges)
Maximum occurrences (MDS+ backend only): 20
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channel(i1)/aperture(i2)AoS¶Description of apertures between plasma and the detectors (position, […]
Description of apertures between plasma and the detectors (position, outline shape and orientation)
Maximum occurrences (MDS+ backend only): 3
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channel(i1)/aperture(i2)/geometry_typeINT_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.
channel(i1)/aperture(i2)/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.
channel(i1)/aperture(i2)/radius ⇹mFLT_0D¶Radius of the circle, used only if geometry_type = 2
Radius of the circle, used only if geometry_type = 2
channel(i1)/aperture(i2)/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).
channel(i1)/aperture(i2)/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.
channel(i1)/aperture(i2)/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.
channel(i1)/aperture(i2)/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
channel(i1)/aperture(i2)/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
channel(i1)/aperture(i2)/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
channel(i1)/aperture(i2)/outline/x1(:) ⇹mFLT_1D¶Positions along x1 axis
Positions along x1 axis
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channel(i1)/viewing_angle_alpha_bounds(:) ⇹radFLT_1D¶Minimum and maximum values of alpha angle of the field of view, […]
Minimum and maximum values of alpha angle of the field of view, where alpha is the agle between the axis X3 and projection of the chord of view on the plane X1X3 counted clockwise from the top view of X2 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).
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channel(i1)/viewing_angle_beta_bounds(:) ⇹radFLT_1D¶Minimum and maximum values of beta angle of the field of view, […]
Minimum and maximum values of beta angle of the field of view, where beta is the angle between the axis X3 and projection of the chord of view on the plane X2X3 counted clockwise from the top view of X1 axis. X1, X2, X3 are the ones of the first aperture (i.e. the closest to the plasma).
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channel(i1)/detector(i2)AoS¶Set of detectors
Set of detectors
Maximum occurrences (MDS+ backend only): 10
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channel(i1)/detector(i2)/pixel_to_alpha(:) ⇹radFLT_1D¶Alpha angle of each pixel in the horizontal axis
Alpha angle of each pixel in the horizontal axis
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channel(i1)/detector(i2)/pixel_to_beta(:) ⇹radFLT_1D¶Beta angle of each pixel in the vertical axis
Beta angle of each pixel in the vertical axis
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channel(i1)/detector(i2)/wavelength_lower ⇹mFLT_0D¶Lower bound of the detector wavelength range
Lower bound of the detector wavelength range
channel(i1)/detector(i2)/wavelength_upper ⇹mFLT_0D¶Upper bound of the detector wavelength range
Upper bound of the detector wavelength range
channel(i1)/detector(i2)/counts_to_radiance(:,:) ⇹m^-2.s^-1.sr^-1FLT_2D¶Counts to radiance factor, for each pixel of the detector. […]
Counts to radiance factor, for each pixel of the detector. Includes both the transmission losses in the relay optics and the quantum efficiency of the camera itself, integrated over the wavelength range
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channel(i1)/detector(i2)/noise ⇹1FLT_0D¶Detector noise (e.g. […]
Detector noise (e.g. read-out noise) (rms counts per second exposure time)
channel(i1)/detector(i2)/columns_nINT_0D¶Number of pixel columns in the horizontal direction
Number of pixel columns in the horizontal direction
New in version >3.37.2.
channel(i1)/detector(i2)/lines_nINT_0D¶Number of pixel lines in the vertical direction
Number of pixel lines in the vertical direction
New in version >3.37.2.
channel(i1)/detector(i2)/frame(itime)AoS¶Set of frames
Set of frames
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channel(i1)/detector(i2)/frame(itime)/image_raw(:,:)INT_2D¶Raw image (unprocessed) (digital levels). […]
Raw image (unprocessed) (digital levels). First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).
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channel(i1)/detector(i2)/frame(itime)/radiance(:,:) ⇹m^-2.s^-1.sr^-1FLT_2D¶Radiance image. […]
Radiance image. First dimension : line index (horizontal axis). Second dimension: column index (vertical axis).
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channel(i1)/detector(i2)/geometry_matrixstructure¶Description of geometry matrix (ray transfer matrix)
Description of geometry matrix (ray transfer matrix)
channel(i1)/detector(i2)/geometry_matrix/with_reflectionsstructure¶Geometry matrix with reflections
Geometry matrix with reflections
New in version >3.37.2.
channel(i1)/detector(i2)/geometry_matrix/with_reflections/data(:) ⇹mFLT_1D¶The Ray Transfer Matrix (RTM, or geometry matrix) here provides […]
The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indices. The pixel indices corresponding to an element of this array can be found in pixel_indices
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channel(i1)/detector(i2)/geometry_matrix/with_reflections/voxel_indices(:)INT_1D¶List of voxel indices (defined in the voxel map) used in the […]
List of voxel indices (defined in the voxel map) used in the sparse data array
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channel(i1)/detector(i2)/geometry_matrix/with_reflections/pixel_indices(:,:)INT_2D¶List of pixel indices used in the sparse data array. […]
List of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).
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channel(i1)/detector(i2)/geometry_matrix/without_reflectionsstructure¶Geometry matrix without reflections
Geometry matrix without reflections
New in version >3.37.2.
channel(i1)/detector(i2)/geometry_matrix/without_reflections/data(:) ⇹mFLT_1D¶The Ray Transfer Matrix (RTM, or geometry matrix) here provides […]
The Ray Transfer Matrix (RTM, or geometry matrix) here provides transformation of the signal from each individual unit light source (voxel) to each pixel of the receiver (detector). The emission profile has [photons.m^-3.s^-1.sr^-1] units and radiance signal has [photons.m^-2.s^-1.sr^-1] units. So the RTM has [m] units. This data is stored in a sparse form, i.e. the array contains only the non-zero element of the Ray transfer matrix. The voxel index corresponding to an element of this array can be found in voxel_indices. The pixel indices corresponding to an element of this array can be found in pixel_indices
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channel(i1)/detector(i2)/geometry_matrix/without_reflections/voxel_indices(:)INT_1D¶List of voxel indices (defined in the voxel map) used in the […]
List of voxel indices (defined in the voxel map) used in the sparse data array
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channel(i1)/detector(i2)/geometry_matrix/without_reflections/pixel_indices(:,:)INT_2D¶List of pixel indices used in the sparse data array. […]
List of pixel indices used in the sparse data array. The first dimension refers to the data array index. The second dimension lists the line index (horizontal axis) in first position, then the column index (vertical axis).
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channel(i1)/detector(i2)/geometry_matrix/interpolatedstructure¶Interpolated geometry matrix for reflected light
Interpolated geometry matrix for reflected light
New in version >3.37.2.
channel(i1)/detector(i2)/geometry_matrix/interpolated/r(:) ⇹mFLT_1D¶Major radius of interpolation knots
Major radius of interpolation knots
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channel(i1)/detector(i2)/geometry_matrix/interpolated/z(:) ⇹mFLT_1D¶Height of interpolation knots
Height of interpolation knots
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channel(i1)/detector(i2)/geometry_matrix/interpolated/phi(:) ⇹radFLT_1D¶Toroidal angle (oriented counter-clockwise when viewing from […]
Toroidal angle (oriented counter-clockwise when viewing from above) of interpolation knots
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channel(i1)/detector(i2)/geometry_matrix/interpolated/data(:,:,:) ⇹m^-2FLT_3D¶Interpolated Ray Transfer Matrix (RTM, or geometry matrix), which […]
Interpolated Ray Transfer Matrix (RTM, or geometry matrix), which provides transformation of the reflected light from each interpolation knot to the receiver (detector pixel). When convolving with an emission profile, the values must be interpolated to the emission grid and multiplied by the volume of the grid cells. The interpolated matrix is given on an array of interpolation knots of coordinates r, z and phi (third dimension of this array). The first two dimension correspond to the detector pixels : first dimension : line index (horizontal axis); second dimension: column index (vertical axis).
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channel(i1)/detector(i2)/geometry_matrix/voxel_map(:,:,:)INT_3D¶Voxel map for geometry matrix. […]
Voxel map for geometry matrix. The cells with same number are merged in the computation into a single emission source meta-cell (the voxel). Cells with number -1 are excluded. Voxel count starts from 0.
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channel(i1)/detector(i2)/geometry_matrix/voxels_nINT_0D¶Number of voxels defined in the voxel_map.
Number of voxels defined in the voxel_map.
New in version >3.37.2.
channel(i1)/detector(i2)/geometry_matrix/emission_gridstructure¶Grid defining the light emission cells
Grid defining the light emission cells
channel(i1)/detector(i2)/geometry_matrix/emission_grid/grid_typestructure¶Grid type
Grid type
This is an identifier. See emission_grid_identifier for the available options.
channel(i1)/detector(i2)/geometry_matrix/emission_grid/grid_type/nameSTR_0D¶Short string identifier
Short string identifier
channel(i1)/detector(i2)/geometry_matrix/emission_grid/dim1(:) ⇹mixedFLT_1D¶First dimension values
First dimension values
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channel(i1)/detector(i2)/geometry_matrix/emission_grid/dim2(:) ⇹mixedFLT_1D¶Second dimension values
Second dimension values
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channel(i1)/optical_element(i2)AoS¶Set of optical elements
Set of optical elements
Maximum occurrences (MDS+ backend only): 10
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New in version >3.38.1.
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/front_surfacestructure¶Curvature of the front surface
Curvature of the front surface
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/front_surface/curvature_type/nameSTR_0D¶Short string identifier
Short string identifier
channel(i1)/optical_element(i2)/back_surfacestructure¶Curvature of the front surface
Curvature of the front surface
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/back_surface/curvature_type/nameSTR_0D¶Short string identifier
Short string identifier
channel(i1)/optical_element(i2)/thickness ⇹mFLT_0D¶Distance between front_surface and back_surface along the X3 […]
Distance between front_surface and back_surface along the X3 vector
channel(i1)/optical_element(i2)/material_propertiesstructure¶Material properties of the optical element
Material properties of the optical element
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/material_properties/type/nameSTR_0D¶Short string identifier
Short string identifier
channel(i1)/optical_element(i2)/material_properties/wavelengths(:) ⇹mFLT_1D¶Wavelengths array for refractive_index, extinction_coefficient […]
Wavelengths array for refractive_index, extinction_coefficient and transmission_coefficient
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channel(i1)/optical_element(i2)/material_properties/refractive_index(:) ⇹1FLT_1D¶Refractive index (for metal and dielectric)
Refractive index (for metal and dielectric)
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channel(i1)/optical_element(i2)/material_properties/extinction_coefficient(:) ⇹1FLT_1D¶Extinction coefficient (for metal)
Extinction coefficient (for metal)
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channel(i1)/optical_element(i2)/material_properties/transmission_coefficient(:) ⇹1FLT_1D¶Transmission coefficient (for dielectric)
Transmission coefficient (for dielectric)
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channel(i1)/optical_element(i2)/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
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channel(i1)/optical_element(i2)/geometrystructure¶Further geometrical description of the element
Further geometrical description of the element
channel(i1)/optical_element(i2)/geometry/geometry_typeINT_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.
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/geometry/radius ⇹mFLT_0D¶Radius of the circle, used only if geometry_type = 2
Radius of the circle, used only if geometry_type = 2
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/geometry/x1_unit_vector/x ⇹mFLT_0D¶Component along X axis
Component along X axis
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/geometry/x2_unit_vector/x ⇹mFLT_0D¶Component along X axis
Component along X axis
channel(i1)/optical_element(i2)/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.
channel(i1)/optical_element(i2)/geometry/x3_unit_vector/x ⇹mFLT_0D¶Component along X axis
Component along X axis
channel(i1)/optical_element(i2)/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
channel(i1)/optical_element(i2)/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
channel(i1)/optical_element(i2)/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
channel(i1)/optical_element(i2)/geometry/outline/x1(:) ⇹mFLT_1D¶Positions along x1 axis
Positions along x1 axis
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channel(i1)/fibre_bundlestructure¶Description of the fibre bundle
Description of the fibre bundle
New in version >3.38.1.
channel(i1)/fibre_bundle/geometrystructure¶Geometry of the fibre bundle entrance
Geometry of the fibre bundle entrance
channel(i1)/fibre_bundle/geometry/geometry_typeINT_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.
channel(i1)/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.
channel(i1)/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
channel(i1)/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.
channel(i1)/fibre_bundle/geometry/x1_unit_vector/x ⇹mFLT_0D¶Component along X axis
Component along X axis
channel(i1)/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.
channel(i1)/fibre_bundle/geometry/x2_unit_vector/x ⇹mFLT_0D¶Component along X axis
Component along X axis
channel(i1)/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.
channel(i1)/fibre_bundle/geometry/x3_unit_vector/x ⇹mFLT_0D¶Component along X axis
Component along X axis
channel(i1)/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
channel(i1)/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
channel(i1)/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
channel(i1)/fibre_bundle/geometry/outline/x1(:) ⇹mFLT_1D¶Positions along x1 axis
Positions along x1 axis
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channel(i1)/fibre_bundle/fibre_positionsstructure¶Individual fibres centres positions in the (X1, X2) coordinate […]
Individual fibres centres positions in the (X1, X2) coordinate system
channel(i1)/fibre_bundle/fibre_positions/x1(:) ⇹mFLT_1D¶Positions along x1 axis
Positions along x1 axis
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