mseΒΆ
| Path | Dimensions | Type | Units | Description |
|---|---|---|---|---|
mse (alpha) | Motional Stark Effect diagnostic | |||
mse.channel (alpha) | [1...N] | STRUCT_ARRAY | Set of channels (lines of sight) | |
mse.channel[:].active_spatial_resolution (alpha) | [mse.channel[:].active_spatial_resolution[:].time] | STRUCT_ARRAY | Spatial resolution of the measurement, calculated as a convolution of the atomic smearing, magnetic and beam geometry smearing and detector projection, for a set of time slices (use a single time slice for the whole pulse if the beam and the line of sight are not moving during the pulse) | |
mse.channel[:].active_spatial_resolution[:].centre (alpha) | STRUCTURE | Position of the centre of the spatially resolved zone | ||
mse.channel[:].active_spatial_resolution[:].centre.phi (alpha) | FLT_0D (uncertain) | rad | Toroidal angle (oriented counter-clockwise when viewing from above) | |
mse.channel[:].active_spatial_resolution[:].centre.r (alpha) | FLT_0D (uncertain) | m | Major radius | |
mse.channel[:].active_spatial_resolution[:].centre.z (alpha) | FLT_0D (uncertain) | m | Height | |
mse.channel[:].active_spatial_resolution[:].geometric_coefficients (alpha) | [1...9] | FLT_1D (uncertain) | mixed | Set of 9 geometric coefficients providing the MSE polarisation angle as a function of the local electric and magnetic field components (these are related to the angle between beam and line of sight). The list is ordered as follows : coefficients of BZ, BR, Bphi, ER (numerator of the MSE angle expression); coefficients of BZ, BR, Bphi, ER, EZ (denominator) |
mse.channel[:].active_spatial_resolution[:].time (alpha) | FLT_0D | s | Time | |
mse.channel[:].active_spatial_resolution[:].width (alpha) | STRUCTURE | Full width of the spatially resolved zone in the R, Z and phi directions | ||
mse.channel[:].active_spatial_resolution[:].width.phi (alpha) | FLT_0D (uncertain) | rad | Toroidal angle (oriented counter-clockwise when viewing from above) | |
mse.channel[:].active_spatial_resolution[:].width.r (alpha) | FLT_0D (uncertain) | m | Major radius | |
mse.channel[:].active_spatial_resolution[:].width.z (alpha) | FLT_0D (uncertain) | m | Height | |
mse.channel[:].aperture (alpha) | [1...N] | STRUCT_ARRAY | Description of a set of collimating apertures | |
mse.channel[:].aperture[:].centre (alpha) | STRUCTURE | 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. | ||
mse.channel[:].aperture[:].centre.phi (alpha) | FLT_0D (uncertain) | rad | Toroidal angle (oriented counter-clockwise when viewing from above) | |
mse.channel[:].aperture[:].centre.r (alpha) | FLT_0D (uncertain) | m | Major radius | |
mse.channel[:].aperture[:].centre.z (alpha) | FLT_0D (uncertain) | m | Height | |
mse.channel[:].aperture[:].geometry_type (alpha) | INT_0D | 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. | ||
mse.channel[:].aperture[:].outline (alpha) | STRUCTURE | Irregular outline of the detector/aperture in the (X1, X2) coordinate system. Do NOT repeat the first point. | ||
mse.channel[:].aperture[:].outline.x1 (alpha) | [1...N] | FLT_1D (uncertain) | m | Positions along x1 axis |
mse.channel[:].aperture[:].outline.x2 (alpha) | [mse.channel[:].aperture[:].outline.x1] | FLT_1D (uncertain) | m | Positions along x2 axis |
mse.channel[:].aperture[:].radius (alpha) | FLT_0D (uncertain) | m | Radius of the circle, used only if geometry_type = 2 | |
mse.channel[:].aperture[:].surface (alpha) | FLT_0D (uncertain) | m^2 | Surface of the detector/aperture, derived from the above geometric data | |
mse.channel[:].aperture[:].x1_unit_vector (alpha) | STRUCTURE | 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). | ||
mse.channel[:].aperture[:].x1_unit_vector.x (alpha) | FLT_0D (uncertain) | m | Component along X axis | |
mse.channel[:].aperture[:].x1_unit_vector.y (alpha) | FLT_0D (uncertain) | m | Component along Y axis | |
mse.channel[:].aperture[:].x1_unit_vector.z (alpha) | FLT_0D (uncertain) | m | Component along Z axis | |
mse.channel[:].aperture[:].x1_width (alpha) | FLT_0D (uncertain) | m | Full width of the aperture in the X1 direction, used only if geometry_type = 3 | |
mse.channel[:].aperture[:].x2_unit_vector (alpha) | STRUCTURE | 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. | ||
mse.channel[:].aperture[:].x2_unit_vector.x (alpha) | FLT_0D (uncertain) | m | Component along X axis | |
mse.channel[:].aperture[:].x2_unit_vector.y (alpha) | FLT_0D (uncertain) | m | Component along Y axis | |
mse.channel[:].aperture[:].x2_unit_vector.z (alpha) | FLT_0D (uncertain) | m | Component along Z axis | |
mse.channel[:].aperture[:].x2_width (alpha) | FLT_0D (uncertain) | m | Full width of the aperture in the X2 direction, used only if geometry_type = 3 | |
mse.channel[:].aperture[:].x3_unit_vector (alpha) | STRUCTURE | 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. | ||
mse.channel[:].aperture[:].x3_unit_vector.x (alpha) | FLT_0D (uncertain) | m | Component along X axis | |
mse.channel[:].aperture[:].x3_unit_vector.y (alpha) | FLT_0D (uncertain) | m | Component along Y axis | |
mse.channel[:].aperture[:].x3_unit_vector.z (alpha) | FLT_0D (uncertain) | m | Component along Z axis | |
mse.channel[:].detector (alpha) | STRUCTURE | Detector description | ||
mse.channel[:].detector.centre (alpha) | STRUCTURE | 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. | ||
mse.channel[:].detector.centre.phi (alpha) | FLT_0D (uncertain) | rad | Toroidal angle (oriented counter-clockwise when viewing from above) | |
mse.channel[:].detector.centre.r (alpha) | FLT_0D (uncertain) | m | Major radius | |
mse.channel[:].detector.centre.z (alpha) | FLT_0D (uncertain) | m | Height | |
mse.channel[:].detector.geometry_type (alpha) | INT_0D | 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. | ||
mse.channel[:].detector.outline (alpha) | STRUCTURE | Irregular outline of the detector/aperture in the (X1, X2) coordinate system. Do NOT repeat the first point. | ||
mse.channel[:].detector.outline.x1 (alpha) | [1...N] | FLT_1D (uncertain) | m | Positions along x1 axis |
mse.channel[:].detector.outline.x2 (alpha) | [mse.channel[:].detector.outline.x1] | FLT_1D (uncertain) | m | Positions along x2 axis |
mse.channel[:].detector.radius (alpha) | FLT_0D (uncertain) | m | Radius of the circle, used only if geometry_type = 2 | |
mse.channel[:].detector.surface (alpha) | FLT_0D (uncertain) | m^2 | Surface of the detector/aperture, derived from the above geometric data | |
mse.channel[:].detector.x1_unit_vector (alpha) | STRUCTURE | 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). | ||
mse.channel[:].detector.x1_unit_vector.x (alpha) | FLT_0D (uncertain) | m | Component along X axis | |
mse.channel[:].detector.x1_unit_vector.y (alpha) | FLT_0D (uncertain) | m | Component along Y axis | |
mse.channel[:].detector.x1_unit_vector.z (alpha) | FLT_0D (uncertain) | m | Component along Z axis | |
mse.channel[:].detector.x1_width (alpha) | FLT_0D (uncertain) | m | Full width of the aperture in the X1 direction, used only if geometry_type = 3 | |
mse.channel[:].detector.x2_unit_vector (alpha) | STRUCTURE | 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. | ||
mse.channel[:].detector.x2_unit_vector.x (alpha) | FLT_0D (uncertain) | m | Component along X axis | |
mse.channel[:].detector.x2_unit_vector.y (alpha) | FLT_0D (uncertain) | m | Component along Y axis | |
mse.channel[:].detector.x2_unit_vector.z (alpha) | FLT_0D (uncertain) | m | Component along Z axis | |
mse.channel[:].detector.x2_width (alpha) | FLT_0D (uncertain) | m | Full width of the aperture in the X2 direction, used only if geometry_type = 3 | |
mse.channel[:].detector.x3_unit_vector (alpha) | STRUCTURE | 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. | ||
mse.channel[:].detector.x3_unit_vector.x (alpha) | FLT_0D (uncertain) | m | Component along X axis | |
mse.channel[:].detector.x3_unit_vector.y (alpha) | FLT_0D (uncertain) | m | Component along Y axis | |
mse.channel[:].detector.x3_unit_vector.z (alpha) | FLT_0D (uncertain) | m | Component along Z axis | |
mse.channel[:].line_of_sight (alpha) | STRUCTURE | Description of the line of sight of the channel, given by 2 points | ||
mse.channel[:].line_of_sight.first_point (alpha) | STRUCTURE | Position of the first point | ||
mse.channel[:].line_of_sight.first_point.phi (alpha) | FLT_0D (uncertain) | rad | Toroidal angle (oriented counter-clockwise when viewing from above) | |
mse.channel[:].line_of_sight.first_point.r (alpha) | FLT_0D (uncertain) | m | Major radius | |
mse.channel[:].line_of_sight.first_point.z (alpha) | FLT_0D (uncertain) | m | Height | |
mse.channel[:].line_of_sight.second_point (alpha) | STRUCTURE | Position of the second point | ||
mse.channel[:].line_of_sight.second_point.phi (alpha) | FLT_0D (uncertain) | rad | Toroidal angle (oriented counter-clockwise when viewing from above) | |
mse.channel[:].line_of_sight.second_point.r (alpha) | FLT_0D (uncertain) | m | Major radius | |
mse.channel[:].line_of_sight.second_point.z (alpha) | FLT_0D (uncertain) | m | Height | |
mse.channel[:].name (alpha) | STR_0D | Name of the channel | ||
mse.channel[:].polarisation_angle (alpha) | STRUCTURE | rad | MSE polarisation angle | |
mse.channel[:].polarisation_angle.data (alpha) | [mse.channel[:].polarisation_angle.time] | FLT_1D (uncertain) | rad | Data |
mse.channel[:].polarisation_angle.time (alpha) | [1...N] | FLT_1D_TYPE | s | Time |
mse.channel[:].polarisation_angle.validity (alpha) | INT_0D | Indicator of the validity of the data for the whole acquisition period. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity) | ||
mse.channel[:].polarisation_angle.validity_timed (alpha) | [mse.channel[:].polarisation_angle.time] | INT_1D | Indicator of the validity of the data for each time slice. 0: valid from automated processing, 1: valid and certified by the diagnostic RO; - 1 means problem identified in the data processing (request verification by the diagnostic RO), -2: invalid data, should not be used (values lower than -2 have a code-specific meaning detailing the origin of their invalidity) | |
mse.code (alpha) | STRUCTURE | Generic decription of the code-specific parameters for the code that has produced this IDS | ||
mse.code.commit (alpha) | STR_0D | Unique commit reference of software | ||
mse.code.description (alpha) | STR_0D | Short description of the software (type, purpose) | ||
mse.code.library (alpha) | [1...N] | STRUCT_ARRAY | List of external libraries used by the code that has produced this IDS | |
mse.code.library[:].commit (alpha) | STR_0D | Unique commit reference of software | ||
mse.code.library[:].description (alpha) | STR_0D | Short description of the software (type, purpose) | ||
mse.code.library[:].name (alpha) | STR_0D | Name of software | ||
mse.code.library[:].parameters (alpha) | STR_0D | List of the code specific parameters in XML format | ||
mse.code.library[:].repository (alpha) | STR_0D | URL of software repository | ||
mse.code.library[:].version (alpha) | STR_0D | Unique version (tag) of software | ||
mse.code.name (alpha) | STR_0D | Name of software generating IDS | ||
mse.code.output_flag (alpha) | [mse.time] | INT_1D | Output flag : 0 means the run is successful, other values mean some difficulty has been encountered, the exact meaning is then code specific. Negative values mean the result shall not be used. | |
mse.code.parameters (alpha) | STR_0D | List of the code specific parameters in XML format | ||
mse.code.repository (alpha) | STR_0D | URL of software repository | ||
mse.code.version (alpha) | STR_0D | Unique version (tag) of software | ||
mse.ids_properties (alpha) | STRUCTURE | Interface Data Structure properties. This element identifies the node above as an IDS | ||
mse.ids_properties.comment (alpha) | STR_0D | Any comment describing the content of this IDS | ||
mse.ids_properties.creation_date (alpha) | STR_0D | Date at which this data has been produced | ||
mse.ids_properties.homogeneous_time (alpha) | INT_0D | This node must be filled (with 0, 1, or 2) for the IDS to be valid. If 1, the time of this IDS is homogeneous, i.e. the time values for this IDS are stored in the time node just below the root of this IDS. If 0, the time values are stored in the various time fields at lower levels in the tree. In the case only constant or static nodes are filled within the IDS, homogeneous_time must be set to 2 | ||
mse.ids_properties.name (alpha) | STR_0D | User-defined name for this IDS occurrence | ||
mse.ids_properties.occurrence | INT_0D | |||
mse.ids_properties.occurrence_type (alpha) | STRUCTURE | Type of data contained in this occurrence | ||
mse.ids_properties.occurrence_type.description (alpha) | STR_0D | Verbose description | ||
mse.ids_properties.occurrence_type.index (alpha) | INT_0D | Integer identifier (enumeration index within a list). Private identifier values must be indicated by a negative index. | ||
mse.ids_properties.occurrence_type.name (alpha) | STR_0D | Short string identifier | ||
mse.ids_properties.plugins (alpha) | STRUCTURE | Information about the plugins used to write/read this IDS. This structure is filled automatically by the Access Layer at GET/PUT time, no need to fill it via a user program. | ||
mse.ids_properties.plugins.infrastructure_get (alpha) | STRUCTURE | Plugin infrastructure used to GET the data | ||
mse.ids_properties.plugins.infrastructure_get.commit (alpha) | STR_0D | Unique commit reference of software | ||
mse.ids_properties.plugins.infrastructure_get.description (alpha) | STR_0D | Short description of the software (type, purpose) | ||
mse.ids_properties.plugins.infrastructure_get.name (alpha) | STR_0D | Name of software used | ||
mse.ids_properties.plugins.infrastructure_get.repository (alpha) | STR_0D | URL of software repository | ||
mse.ids_properties.plugins.infrastructure_get.version (alpha) | STR_0D | Unique version (tag) of software | ||
mse.ids_properties.plugins.infrastructure_put (alpha) | STRUCTURE | Plugin infrastructure used to PUT the data | ||
mse.ids_properties.plugins.infrastructure_put.commit (alpha) | STR_0D | Unique commit reference of software | ||
mse.ids_properties.plugins.infrastructure_put.description (alpha) | STR_0D | Short description of the software (type, purpose) | ||
mse.ids_properties.plugins.infrastructure_put.name (alpha) | STR_0D | Name of software used | ||
mse.ids_properties.plugins.infrastructure_put.repository (alpha) | STR_0D | URL of software repository | ||
mse.ids_properties.plugins.infrastructure_put.version (alpha) | STR_0D | Unique version (tag) of software | ||
mse.ids_properties.plugins.node (alpha) | [1...N] | STRUCT_ARRAY | Set of IDS nodes for which a plugin has been applied | |
mse.ids_properties.plugins.node[:].get_operation (alpha) | [1...N] | STRUCT_ARRAY | Plugins actually used to read back a node (potentially, multiple plugins can be applied, listed in reverse order of application). This information is filled by the plugin infrastructure during the GET operation. | |
mse.ids_properties.plugins.node[:].get_operation[:].commit (alpha) | STR_0D | Unique commit reference of software | ||
mse.ids_properties.plugins.node[:].get_operation[:].description (alpha) | STR_0D | Short description of the software (type, purpose) | ||
mse.ids_properties.plugins.node[:].get_operation[:].name (alpha) | STR_0D | Name of software used | ||
mse.ids_properties.plugins.node[:].get_operation[:].parameters (alpha) | STR_0D | List of the code specific parameters in XML format | ||
mse.ids_properties.plugins.node[:].get_operation[:].repository (alpha) | STR_0D | URL of software repository | ||
mse.ids_properties.plugins.node[:].get_operation[:].version (alpha) | STR_0D | Unique version (tag) of software | ||
mse.ids_properties.plugins.node[:].path (alpha) | STR_0D | Path of the node within the IDS, following the syntax given in the link below. If empty, means the plugin applies to the whole IDS. | ||
mse.ids_properties.plugins.node[:].put_operation (alpha) | [1...N] | STRUCT_ARRAY | Plugins used to PUT a node (potentially, multiple plugins can be applied, if so they are listed by order of application) | |
mse.ids_properties.plugins.node[:].put_operation[:].commit (alpha) | STR_0D | Unique commit reference of software | ||
mse.ids_properties.plugins.node[:].put_operation[:].description (alpha) | STR_0D | Short description of the software (type, purpose) | ||
mse.ids_properties.plugins.node[:].put_operation[:].name (alpha) | STR_0D | Name of software used | ||
mse.ids_properties.plugins.node[:].put_operation[:].parameters (alpha) | STR_0D | List of the code specific parameters in XML format | ||
mse.ids_properties.plugins.node[:].put_operation[:].repository (alpha) | STR_0D | URL of software repository | ||
mse.ids_properties.plugins.node[:].put_operation[:].version (alpha) | STR_0D | Unique version (tag) of software | ||
mse.ids_properties.plugins.node[:].readback (alpha) | [1...N] | STRUCT_ARRAY | Plugins to be used to read back a node (potentially, multiple plugins can be applied, listed in reverse order of application) | |
mse.ids_properties.plugins.node[:].readback[:].commit (alpha) | STR_0D | Unique commit reference of software | ||
mse.ids_properties.plugins.node[:].readback[:].description (alpha) | STR_0D | Short description of the software (type, purpose) | ||
mse.ids_properties.plugins.node[:].readback[:].name (alpha) | STR_0D | Name of software used | ||
mse.ids_properties.plugins.node[:].readback[:].parameters (alpha) | STR_0D | List of the code specific parameters in XML format | ||
mse.ids_properties.plugins.node[:].readback[:].repository (alpha) | STR_0D | URL of software repository | ||
mse.ids_properties.plugins.node[:].readback[:].version (alpha) | STR_0D | Unique version (tag) of software | ||
mse.ids_properties.provenance (alpha) | STRUCTURE | Provenance information about this IDS | ||
mse.ids_properties.provenance.node (alpha) | [1...N] | STRUCT_ARRAY | Set of IDS nodes for which the provenance is given. The provenance information applies to the whole structure below the IDS node. For documenting provenance information for the whole IDS, set the size of this array of structure to 1 and leave the child "path" node empty | |
mse.ids_properties.provenance.node[:].path (alpha) | STR_0D | Path of the node within the IDS, following the syntax given in the link below. If empty, means the provenance information applies to the whole IDS. | ||
mse.ids_properties.provenance.node[:].sources (alpha) | [1...N] | STR_1D | List of sources used to import or calculate this node, identified as explained below. In case the node is the result of of a calculation / data processing, the source is an input to the process described in the "code" structure at the root of the IDS. The source can be an IDS (identified by a URI or a persitent identifier, see syntax in the link below) or non-IDS data imported directly from an non-IMAS database (identified by the command used to import the source, or the persistent identifier of the data source). Often data are obtained by a chain of processes, however only the last process input are recorded here. The full chain of provenance has then to be reconstructed recursively from the provenance information contained in the data sources. | |
mse.ids_properties.provider (alpha) | STR_0D | Name of the person in charge of producing this data | ||
mse.ids_properties.source (obsolescent) | STR_0D | Source of the data (any comment describing the origin of the data : code, path to diagnostic signals, processing method, ...). Superseeded by the new provenance structure. | ||
mse.ids_properties.version_put (alpha) | STRUCTURE | Version of the access layer package used to PUT this IDS | ||
mse.ids_properties.version_put.access_layer (alpha) | STR_0D | Version of Access Layer used to PUT this IDS | ||
mse.ids_properties.version_put.access_layer_language (alpha) | STR_0D | Programming language of the Access Layer high level API used to PUT this IDS | ||
mse.ids_properties.version_put.data_dictionary (alpha) | STR_0D | Version of Data Dictionary used to PUT this IDS | ||
mse.latency (alpha) | FLT_0D (uncertain) | s | Upper bound of the delay between physical information received by the detector and data available on the real-time (RT) network. | |
mse.time (alpha) | [1...N] | FLT_1D_TYPE | s | Generic time |