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Table of Contents
Name | Direction | Type | Default | Description |
---|---|---|---|---|
InputFiles | Input | str list | Comma seperated list if input files | |
Instrument | Input | string | Mandatory | Instrument used during run. Allowed values: [‘IRIS’, ‘OSIRIS’, ‘TOSCA’] |
Analyser | Input | string | Mandatory | Analyser used during run. Allowed values: [‘graphite’, ‘mica’, ‘fmica’] |
Reflection | Input | string | Mandatory | Reflection used during run. Allowed values: [‘002’, ‘004’, ‘006’] |
DetectorRange | Input | long list | 0,1 | Range of detetcors to use in resolution calculation. |
BackgroundRange | Input | dbl list | 0,0 | Energy range to use as background. |
RebinParam | Input | string | Rebinning parameters (min,width,max) | |
ScaleFactor | Input | number | 1 | Factor to scale resolution curve by |
LoadLogFiles | Input | boolean | True | Option to load log files |
OutputWorkspace | Output | Workspace | Mandatory | Output resolution workspace. |
Creates a resolution workspace for an inelastic indirect sample run by summing all spectra in the energy transfer and subtracting a flat background to give a single resolution curve.
Rebinning and intensity scaling can optionally be applied to the result.
Note
To run these usage examples please first download the usage data, and add these to your path. In Mantid this is done using Manage User Directories.
Example - Running IndirectResolution.
resolution = IndirectResolution(InputFiles='IRS26173.raw',
Instrument='IRIS',
Analyser='graphite',
Reflection='002',
DetectorRange=[3, 53],
BackgroundRange=[-0.16, -0.14],
RebinParam='-0.175,0.002,0.175')
print('Number of histograms: {:d}'.format(resolution.getNumberHistograms()))
print('Number of bins: {:d}'.format(resolution.blocksize()))
Output:
Number of histograms: 1
Number of bins: 175
Categories: AlgorithmIndex | Workflow\Inelastic | Inelastic\Indirect
Python: IndirectResolution.py