\(\renewcommand\AA{\unicode{x212B}}\)
Table of Contents
Name | Direction | Type | Default | Description |
---|---|---|---|---|
InputWorkspace | InOut | MatrixWorkspace | Mandatory | Name the workspace to calculate the resolution for |
ReducedWorkspace | Input | MatrixWorkspace | Mandatory | I(Q) workspace |
OutputBinning | Input | dbl list | Mandatory | |
MinWavelength | Input | number | Optional | Minimum wavelength to use. |
MaxWavelength | Input | number | Optional | Maximum wavelength to use. |
PixelSizeX | Input | number | 5.15 | Pixel size in the X direction (mm). |
PixelSizeY | Input | number | 5.15 | Pixel size in the Y direction (mm). |
SampleApertureRadius | Input | number | 5 | Sample aperture radius (mm). |
SourceApertureRadius | Input | number | 10 | Source aperture radius (mm). |
DeltaT | Input | number | 250 | TOF spread (microsec). |
This algorithm extends the TOFSANSResolution to implement the experimentally determined TOF resolution for EQSANS.
The Q resolution for a TOF SANS has two components: a geometrical contribution and a contributions from the resolution in TOF.
The TOF resolution for EQSANS was measured to be:
\(\Delta T = y_0 + A ( f/(1+\exp((\lambda-x^0_1)/k_1)) + (1-f)/(1+\exp((\lambda-x^0_2)/k_2)) )\)
where \(\lambda\) is the wavelength and
\(y_0 = -388\)
\(A = 3838\)
\(f = 0.04398\)
\(x^0_1 = 3.392\)
\(x^0_2 = 134.3\)
\(k_1 = -0.5587\)
\(k_2 = -65.46\)
This algorithm is generally not called directly. It’s called by EQSANSAzimuthalAverage1D after the calculation of I(Q). It can only be applied to an I(Q) workspace.
Categories: AlgorithmIndex | SANS
C++ header: EQSANSResolution.h (last modified: 2020-03-20)
C++ source: EQSANSResolution.cpp (last modified: 2020-03-20)