bolometer

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Bolometer diagnostic

  • Maximum occurrences (MDS+ backend only): 2

New in version 3.7.4: lifecycle status alpha

Changed in version 4.1.0.

ids_propertiesstructure

See common IDS structure reference: ids_properties.

camera(i1)AoSSet of cameras

Set of cameras

  • Maximum occurrences (MDS+ backend only): 10

Coordinate

1

1...N

New in version >4.0.0.

camera(i1)/nameSTR_0DShort string identifier (unique for a given device)

Short string identifier (unique for a given device)

camera(i1)/descriptionSTR_0DDescription, e.g. […]

Description, e.g. “Camera viewing the upper divertor”

New in version >3.

camera(i1)/channel(i2)AoSSet of channels (detector or pixel of a camera)

Set of channels (detector or pixel of a camera)

  • Maximum occurrences (MDS+ backend only): 500

Coordinate

1

1...N
camera(i1)/channel(i2)/nameSTR_0DShort string identifier (unique for a given device)

Short string identifier (unique for a given device)

camera(i1)/channel(i2)/descriptionSTR_0DDescription, e.g. […]

Description, e.g. “channel viewing the upper divertor”

New in version >3.

camera(i1)/channel(i2)/detectorstructureDetector description

Detector description

camera(i1)/channel(i2)/detector/geometry_typeINT_0DType 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.

camera(i1)/channel(i2)/detector/centrestructureIf 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.

camera(i1)/channel(i2)/detector/centre/rmFLT_0DMajor radius

Major radius

camera(i1)/channel(i2)/detector/centre/phiradFLT_0DToroidal angle (oriented counter-clockwise when viewing from […]

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

camera(i1)/channel(i2)/detector/centre/zmFLT_0DHeight

Height

camera(i1)/channel(i2)/detector/radiusmFLT_0DRadius of the circle, used only if geometry_type = 2

Radius of the circle, used only if geometry_type = 2

camera(i1)/channel(i2)/detector/x1_unit_vectorstructureComponents 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.

camera(i1)/channel(i2)/detector/x1_unit_vector/xmFLT_0DComponent along X axis

Component along X axis

camera(i1)/channel(i2)/detector/x1_unit_vector/ymFLT_0DComponent along Y axis

Component along Y axis

camera(i1)/channel(i2)/detector/x1_unit_vector/zmFLT_0DComponent along Z axis

Component along Z axis

camera(i1)/channel(i2)/detector/x2_unit_vectorstructureComponents 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.

camera(i1)/channel(i2)/detector/x2_unit_vector/xmFLT_0DComponent along X axis

Component along X axis

camera(i1)/channel(i2)/detector/x2_unit_vector/ymFLT_0DComponent along Y axis

Component along Y axis

camera(i1)/channel(i2)/detector/x2_unit_vector/zmFLT_0DComponent along Z axis

Component along Z axis

camera(i1)/channel(i2)/detector/x3_unit_vectorstructureComponents 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.

camera(i1)/channel(i2)/detector/x3_unit_vector/xmFLT_0DComponent along X axis

Component along X axis

camera(i1)/channel(i2)/detector/x3_unit_vector/ymFLT_0DComponent along Y axis

Component along Y axis

camera(i1)/channel(i2)/detector/x3_unit_vector/zmFLT_0DComponent along Z axis

Component along Z axis

camera(i1)/channel(i2)/detector/x1_widthmFLT_0DFull 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

camera(i1)/channel(i2)/detector/x2_widthmFLT_0DFull 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

camera(i1)/channel(i2)/detector/outlinestructureIrregular 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

camera(i1)/channel(i2)/detector/outline/x1(:)mFLT_1DPositions along x1 axis

Positions along x1 axis

Coordinate

1

1...N
camera(i1)/channel(i2)/detector/outline/x2(:)mFLT_1DPositions along x2 axis

Positions along x2 axis

Coordinate

1

camera(i1)/channel(i2)/detector/outline/x1
camera(i1)/channel(i2)/detector/surfacem^2FLT_0DSurface of the detector/aperture, derived from the above geometric […]

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

camera(i1)/channel(i2)/aperture(i3)AoSDescription of a set of collimating apertures

Description of a set of collimating apertures

  • Maximum occurrences (MDS+ backend only): 5

Coordinate

1

1...N
camera(i1)/channel(i2)/aperture(i3)/geometry_typeINT_0DType 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.

camera(i1)/channel(i2)/aperture(i3)/centrestructureIf 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.

camera(i1)/channel(i2)/aperture(i3)/centre/rmFLT_0DMajor radius

Major radius

camera(i1)/channel(i2)/aperture(i3)/centre/phiradFLT_0DToroidal angle (oriented counter-clockwise when viewing from […]

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

camera(i1)/channel(i2)/aperture(i3)/centre/zmFLT_0DHeight

Height

camera(i1)/channel(i2)/aperture(i3)/radiusmFLT_0DRadius of the circle, used only if geometry_type = 2

Radius of the circle, used only if geometry_type = 2

camera(i1)/channel(i2)/aperture(i3)/x1_unit_vectorstructureComponents 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.

camera(i1)/channel(i2)/aperture(i3)/x1_unit_vector/xmFLT_0DComponent along X axis

Component along X axis

camera(i1)/channel(i2)/aperture(i3)/x1_unit_vector/ymFLT_0DComponent along Y axis

Component along Y axis

camera(i1)/channel(i2)/aperture(i3)/x1_unit_vector/zmFLT_0DComponent along Z axis

Component along Z axis

camera(i1)/channel(i2)/aperture(i3)/x2_unit_vectorstructureComponents 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.

camera(i1)/channel(i2)/aperture(i3)/x2_unit_vector/xmFLT_0DComponent along X axis

Component along X axis

camera(i1)/channel(i2)/aperture(i3)/x2_unit_vector/ymFLT_0DComponent along Y axis

Component along Y axis

camera(i1)/channel(i2)/aperture(i3)/x2_unit_vector/zmFLT_0DComponent along Z axis

Component along Z axis

camera(i1)/channel(i2)/aperture(i3)/x3_unit_vectorstructureComponents 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.

camera(i1)/channel(i2)/aperture(i3)/x3_unit_vector/xmFLT_0DComponent along X axis

Component along X axis

camera(i1)/channel(i2)/aperture(i3)/x3_unit_vector/ymFLT_0DComponent along Y axis

Component along Y axis

camera(i1)/channel(i2)/aperture(i3)/x3_unit_vector/zmFLT_0DComponent along Z axis

Component along Z axis

camera(i1)/channel(i2)/aperture(i3)/x1_widthmFLT_0DFull 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

camera(i1)/channel(i2)/aperture(i3)/x2_widthmFLT_0DFull 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

camera(i1)/channel(i2)/aperture(i3)/outlinestructureIrregular 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

camera(i1)/channel(i2)/aperture(i3)/outline/x1(:)mFLT_1DPositions along x1 axis

Positions along x1 axis

Coordinate

1

1...N
camera(i1)/channel(i2)/aperture(i3)/outline/x2(:)mFLT_1DPositions along x2 axis

Positions along x2 axis

Coordinate

1

camera(i1)/channel(i2)/aperture(i3)/outline/x1
camera(i1)/channel(i2)/aperture(i3)/surfacem^2FLT_0DSurface of the detector/aperture, derived from the above geometric […]

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

camera(i1)/channel(i2)/subcollimators_nINT_0DNumber of sub-collimators

Number of sub-collimators

New in version >4.0.0.

camera(i1)/channel(i2)/subcollimators_separationmFLT_0DThickness of separation between sub-collimators

Thickness of separation between sub-collimators

New in version >4.0.0.

camera(i1)/channel(i2)/etenduem^2.srFLT_0DEtendue (geometric extent) of the channel’s optical system

Etendue (geometric extent) of the channel’s optical system

camera(i1)/channel(i2)/etendue_methodstructureMethod used to calculate the etendue. […]

Method used to calculate the etendue. Index = 0 : exact calculation with a 4D integral; 1 : approximation with first order formula (detector surface times solid angle subtended by the apertures); 2 : other methods

camera(i1)/channel(i2)/etendue_method/nameSTR_0DShort string identifier

Short string identifier

camera(i1)/channel(i2)/etendue_method/indexINT_0DInteger identifier (enumeration index within a list). […]

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

camera(i1)/channel(i2)/etendue_method/descriptionSTR_0DVerbose description

Verbose description

camera(i1)/channel(i2)/line_of_sightstructureDescription of the reference line of sight of the channel, defined […]

Description of the reference line of sight of the channel, defined by two points when the beam is not reflected, a third point is added to define the reflected beam path

camera(i1)/channel(i2)/line_of_sight/first_pointstructurePosition of the first point

Position of the first point

camera(i1)/channel(i2)/line_of_sight/first_point/rmFLT_0DMajor radius

Major radius

camera(i1)/channel(i2)/line_of_sight/first_point/phiradFLT_0DToroidal angle (oriented counter-clockwise when viewing from […]

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

camera(i1)/channel(i2)/line_of_sight/first_point/zmFLT_0DHeight

Height

camera(i1)/channel(i2)/line_of_sight/second_pointstructurePosition of the second point

Position of the second point

camera(i1)/channel(i2)/line_of_sight/second_point/rmFLT_0DMajor radius

Major radius

camera(i1)/channel(i2)/line_of_sight/second_point/phiradFLT_0DToroidal angle (oriented counter-clockwise when viewing from […]

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

camera(i1)/channel(i2)/line_of_sight/second_point/zmFLT_0DHeight

Height

camera(i1)/channel(i2)/line_of_sight/third_pointstructurePosition of the third point

Position of the third point

camera(i1)/channel(i2)/line_of_sight/third_point/rmFLT_0DMajor radius

Major radius

camera(i1)/channel(i2)/line_of_sight/third_point/phiradFLT_0DToroidal angle (oriented counter-clockwise when viewing from […]

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

camera(i1)/channel(i2)/line_of_sight/third_point/zmFLT_0DHeight

Height

camera(i1)/channel(i2)/powerWstructurePower received on the detector

Power received on the detector

camera(i1)/channel(i2)/power/data(:)WFLT_1DData

Data

Coordinate

1

camera(i1)/channel(i2)/power/time
camera(i1)/channel(i2)/power/time(:)sFLT_1DTime

Time

Coordinate

1

1...N
camera(i1)/channel(i2)/validity_timedstructureIndicator of the validity of the channel as a function of time […]

Indicator of the validity of the channel as a function of time (0 means valid, negative values mean non-valid)

camera(i1)/channel(i2)/validity_timed/data(:)INT_1DData

Data

Coordinate

1

camera(i1)/channel(i2)/validity_timed/time
camera(i1)/channel(i2)/validity_timed/time(:)sFLT_1DTime

Time

Coordinate

1

1...N
camera(i1)/channel(i2)/validityINT_0DIndicator of the validity of the channel for the whole acquisition […]

Indicator of the validity of the channel for the whole acquisition period (0 means valid, negative values mean non-valid)

power_radiated_total(:)WFLT_1DTotal radiated power reconstructed from bolometry data

Total radiated power reconstructed from bolometry data

Coordinate

1

time
power_radiated_inside_lcfs(:)WFLT_1DRadiated power from the plasma inside the Last Closed Flux Surface, […]

Radiated power from the plasma inside the Last Closed Flux Surface, reconstructed from bolometry data

Coordinate

1

time
power_radiated_validity(:)INT_1DValidity flag related to the radiated power reconstructions

Validity flag related to the radiated power reconstructions

Coordinate

1

time
grid_typestructureSelection of one of a set of grid types for the 2D power density […]

Selection of one of a set of grid types for the 2D power density map

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

New in version >3.39.0.

grid_type/nameSTR_0DShort string identifier

Short string identifier

grid_type/indexINT_0DInteger identifier (enumeration index within a list). […]

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

grid_type/descriptionSTR_0DVerbose description

Verbose description

gridstructureDefinition of the 2D grid (the content of dim1 and dim2 is defined […]

Definition of the 2D grid (the content of dim1 and dim2 is defined by the selected grid_type)

New in version >3.39.0.

grid/dim1(:)mixedFLT_1DFirst dimension values

First dimension values

Coordinate

1

1...N
grid/dim2(:)mixedFLT_1DSecond dimension values

Second dimension values

Coordinate

1

1...N
grid/volume_element(:,:)m^3FLT_2DVolume of plasma enclosed in the cell formed by the nodes [dim1(i) […]

Volume of plasma enclosed in the cell formed by the nodes [dim1(i) dim2(j)], [dim1(i+1) dim2(j)], [dim1(i) dim2(j+1)] and [dim1(i+1) dim2(j+1)]

Coordinate

1

grid/dim1

2

grid/dim2
power_densityW.m^-3structurePower density map in the poloidal cross-section, obtained from […]

Power density map in the poloidal cross-section, obtained from tomographic inversion of the bolometer data

Coordinate

1

grid/dim1

2

grid/dim2

New in version >3.39.0.

power_density/data(:,:,:)W.m^-3FLT_3DData

Data

Coordinate

1

grid/dim1

2

grid/dim2

3

power_density/time
power_density/time(:)sFLT_1DTime

Time

Coordinate

1

1...N
latencysFLT_0DUpper 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_1DGeneric time

Generic time

Coordinate

1

1...N