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SANSILLIntegration.py
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SANSILLIntegration.py
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# Mantid Repository : https://github.com/mantidproject/mantid
#
# Copyright © 2018 ISIS Rutherford Appleton Laboratory UKRI,
# NScD Oak Ridge National Laboratory, European Spallation Source,
# Institut Laue - Langevin & CSNS, Institute of High Energy Physics, CAS
# SPDX - License - Identifier: GPL - 3.0 +
from mantid.api import PythonAlgorithm, MatrixWorkspaceProperty, WorkspaceUnitValidator, WorkspaceGroupProperty, \
PropertyMode, MatrixWorkspace, NumericAxis, ITableWorkspaceProperty
from mantid.kernel import EnabledWhenProperty, FloatArrayProperty, Direction, StringListValidator, \
IntBoundedValidator, FloatBoundedValidator, PropertyCriterion, LogicOperator, FloatArrayOrderedPairsValidator, \
FloatArrayLengthValidator, CompositeValidator
from mantid.simpleapi import *
from MildnerCarpenter import *
from DirectBeamResolution import *
import numpy as np
class SANSILLIntegration(PythonAlgorithm):
_input_ws = ''
_output_ws = ''
_output_type = ''
_resolution = ''
_masking_criterion = ''
_lambda_range = []
_is_tof = False
def category(self):
return 'ILL\\SANS'
def summary(self):
return 'Performs SANS integration and resolution calculation based on corrected data.'
def seeAlso(self):
return ['SANSILLReduction']
def name(self):
return 'SANSILLIntegration'
def validateInputs(self):
issues = dict()
if self.getPropertyValue('DefaultQBinning') == 'ResolutionBased' and self.getPropertyValue('CalculateResolution') == 'None':
issues['CalculateResolution'] = 'Please choose a resolution calculation method if resolution based binning is requested.'
if not isinstance(self.getProperty('InputWorkspace').value, MatrixWorkspace):
issues['InputWorkspace'] = 'The input must be a MatrixWorkspace'
else:
run = self.getProperty('InputWorkspace').value.getRun()
if not run:
issues['InputWorkspace'] = 'The input workspace does not have a run object attached.'
else:
if run.hasProperty('ProcessedAs'):
processed = run.getLogData('ProcessedAs').value
if processed != 'Sample':
issues['InputWorkspace'] = 'The input workspace is not processed as sample.'
else:
issues['InputWorkspace'] = 'The input workspace is not processed by SANSILLReduction'
instrument = self.getProperty('InputWorkspace').value.getInstrument()
if not instrument:
issues['InputWorkspace'] += 'The input workspace does not have an instrument attached.'
output_type = self.getPropertyValue('OutputType')
if output_type == 'I(Q)':
if self.getProperty('NumberOfWedges').value != 0 and not self.getPropertyValue('WedgeWorkspace'):
issues['WedgeWorkspace'] = 'This is required when NumberOfWedges is not 0.'
if output_type == 'I(Q)' or output_type == 'I(Phi,Q)':
binning = self.getProperty('OutputBinning').value
if len(binning) > 3 and len(binning) % 2 == 0:
issues['OutputBinning'] = 'If specifying binning explicitly, the array should have odd number of items.'
if output_type == 'I(Phi,Q)' and self.getProperty('NumberOfWedges').value == 0:
issues['NumberOfWedges'] = 'This is required for I(Phi,Q) output.'
return issues
def PyInit(self):
self.declareProperty(MatrixWorkspaceProperty('InputWorkspace', '', direction=Direction.Input,
validator=WorkspaceUnitValidator('Wavelength')),
doc='The input workspace.')
self.declareProperty(MatrixWorkspaceProperty('OutputWorkspace', '', direction=Direction.Output),
doc='The output workspace.')
self.declareProperty(name='OutputType', defaultValue='I(Q)',
validator=StringListValidator(['I(Q)', 'I(Qx,Qy)', 'I(Phi,Q)']),
doc='Choose the output type.')
self.declareProperty(name='CalculateResolution',
defaultValue='None',
validator=StringListValidator(['MildnerCarpenter', 'DirectBeam', 'None']),
doc='Choose to calculate the Q resolution.')
output_iq = EnabledWhenProperty('OutputType', PropertyCriterion.IsEqualTo, 'I(Q)')
output_iphiq = EnabledWhenProperty('OutputType', PropertyCriterion.IsEqualTo, 'I(Phi,Q)')
output_iqxy = EnabledWhenProperty('OutputType', PropertyCriterion.IsEqualTo, 'I(Qx,Qy)')
self.declareProperty(name='DefaultQBinning', defaultValue='PixelSizeBased',
validator=StringListValidator(['PixelSizeBased', 'ResolutionBased']),
doc='Choose how to calculate the default Q binning.')
self.setPropertySettings('DefaultQBinning', EnabledWhenProperty(output_iq, output_iphiq, LogicOperator.Or))
self.declareProperty(name='BinningFactor', defaultValue=1.,
validator=FloatBoundedValidator(lower=0.),
doc='Specify a multiplicative factor for default Q binning (pixel or resolution based).')
self.setPropertySettings('BinningFactor', EnabledWhenProperty(output_iq, output_iphiq, LogicOperator.Or))
self.declareProperty(FloatArrayProperty('OutputBinning'), doc='The manual Q binning of the output')
self.setPropertySettings('OutputBinning', EnabledWhenProperty(output_iq, output_iphiq, LogicOperator.Or))
self.declareProperty('NPixelDivision', 1, IntBoundedValidator(lower=1), 'Number of subpixels to split the pixel (NxN)')
self.setPropertySettings('NPixelDivision', EnabledWhenProperty(output_iq, output_iphiq, LogicOperator.Or))
iq_without_shapes = EnabledWhenProperty(EnabledWhenProperty("ShapeTable", PropertyCriterion.IsDefault),
EnabledWhenProperty(output_iq, output_iphiq, LogicOperator.Or),
LogicOperator.And)
self.declareProperty(name='NumberOfWedges', defaultValue=0, validator=IntBoundedValidator(lower=0),
doc='Number of wedges to integrate separately.')
self.setPropertySettings('NumberOfWedges', iq_without_shapes)
iq_with_wedges = EnabledWhenProperty(output_iq,
EnabledWhenProperty('NumberOfWedges',
PropertyCriterion.IsNotDefault), LogicOperator.And)
iq_with_wedges_or_shapes = EnabledWhenProperty(iq_with_wedges,
EnabledWhenProperty("ShapeTable", PropertyCriterion.IsNotDefault),
LogicOperator.Or)
iq_with_wedges_but_no_shapes = EnabledWhenProperty(iq_with_wedges,
EnabledWhenProperty("ShapeTable", PropertyCriterion.IsDefault),
LogicOperator.And)
self.declareProperty(WorkspaceGroupProperty('WedgeWorkspace', '', direction=Direction.Output, optional=PropertyMode.Optional),
doc='WorkspaceGroup containing I(Q) for each azimuthal wedge.')
self.setPropertySettings('WedgeWorkspace', iq_with_wedges_or_shapes)
self.declareProperty(name='WedgeAngle', defaultValue=30., validator=FloatBoundedValidator(lower=0.),
doc='Wedge opening angle [degrees].')
self.setPropertySettings('WedgeAngle', iq_with_wedges_but_no_shapes)
self.declareProperty(name='WedgeOffset', defaultValue=0., validator=FloatBoundedValidator(lower=0.),
doc='Wedge offset angle from x+ axis.')
self.setPropertySettings('WedgeOffset', iq_with_wedges_but_no_shapes)
self.declareProperty(name='AsymmetricWedges', defaultValue=False, doc='Whether to have asymmetric wedges.')
self.setPropertySettings('AsymmetricWedges', iq_with_wedges_or_shapes)
self.setPropertyGroup('DefaultQBinning', 'I(Q) Options')
self.setPropertyGroup('BinningFactor', 'I(Q) Options')
self.setPropertyGroup('OutputBinning', 'I(Q) Options')
self.setPropertyGroup('NPixelDivision', 'I(Q) Options')
self.setPropertyGroup('NumberOfWedges', 'I(Q) Options')
self.setPropertyGroup('WedgeWorkspace', 'I(Q) Options')
self.setPropertyGroup('WedgeAngle', 'I(Q) Options')
self.setPropertyGroup('WedgeOffset', 'I(Q) Options')
self.setPropertyGroup('AsymmetricWedges', 'I(Q) Options')
self.declareProperty(name='MaxQxy', defaultValue=-1.0,
validator=FloatBoundedValidator(lower=-1.0),
doc='Maximum of absolute Qx and Qy.')
self.setPropertySettings('MaxQxy', output_iqxy)
self.declareProperty(name='DeltaQ', defaultValue=-1.0,
validator=FloatBoundedValidator(lower=-1.0),
doc='The dimension of a Qx-Qy cell.')
self.setPropertySettings('DeltaQ', output_iqxy)
self.declareProperty(name='IQxQyLogBinning', defaultValue=False,
doc='I(Qx, Qy) log binning when binning is not specified.')
self.setPropertySettings('IQxQyLogBinning', output_iqxy)
self.setPropertyGroup('MaxQxy', 'I(Qx,Qy) Options')
self.setPropertyGroup('DeltaQ', 'I(Qx,Qy) Options')
self.setPropertyGroup('IQxQyLogBinning', 'I(Qx,Qy) Options')
self.declareProperty(WorkspaceGroupProperty('PanelOutputWorkspaces', '',
direction=Direction.Output,
optional=PropertyMode.Optional),
doc='The name of the output workspace group for detector panels.')
self.declareProperty(ITableWorkspaceProperty('ShapeTable', '', direction=Direction.Input,
optional=PropertyMode.Optional),
doc='The name of the table workspace containing drawn shapes on which to integrate. '
'If provided, NumberOfWedges, WedgeOffset and WedgeAngle arguments are ignored. ')
self.setPropertyGroup('PanelOutputWorkspaces', 'I(Q) Options')
self.setPropertyGroup('ShapeTable', 'I(Q) Options')
lambda_range_validator = CompositeValidator()
lambda_range_validator.add(FloatArrayOrderedPairsValidator())
lambda_range_validator.add(FloatArrayLengthValidator(2))
self.declareProperty(FloatArrayProperty('WavelengthRange', [1., 10.], validator=lambda_range_validator),
doc='Wavelength range [Angstrom] to be used in integration (TOF only).')
def PyExec(self):
self._input_ws = self.getPropertyValue('InputWorkspace')
self._output_type = self.getPropertyValue('OutputType')
self._resolution = self.getPropertyValue('CalculateResolution')
self._output_ws = self.getPropertyValue('OutputWorkspace')
self._lambda_range = self.getProperty('WavelengthRange').value
self._is_tof = mtd[self._input_ws].getRun().getLogData('tof_mode').value == 'TOF' and \
mtd[self._input_ws].getInstrument().getName() == 'D33' # D33 only
if self._is_tof:
cut_input_ws = self._input_ws+'_cut'
CropWorkspaceRagged(InputWorkspace=self._input_ws,
OutputWorkspace=cut_input_ws,
XMin=self._lambda_range[0],
XMax=self._lambda_range[1])
self._input_ws = cut_input_ws
# re-calculate the Q-range after lambda cut
# TOF is only D33 which has panels
panel_names = mtd[self._input_ws].getInstrument().getStringParameter('detector_panels')[0].split(',')
CalculateDynamicRange(Workspace=self._input_ws, ComponentNames=panel_names)
self._integrate(self._input_ws, self._output_ws)
self.setProperty('OutputWorkspace', self._output_ws)
panels_out_ws = self.getPropertyValue('PanelOutputWorkspaces')
if mtd[self._output_ws].getInstrument().getName() in ['D33', 'D11B', 'D22B'] and panels_out_ws:
panel_names = mtd[self._output_ws].getInstrument().getStringParameter('detector_panels')[0].split(',')
panel_outputs = []
for panel in panel_names:
in_ws = self._input_ws + '_' + panel
out_ws = panels_out_ws + '_' + panel
CropToComponent(InputWorkspace=self._input_ws, OutputWorkspace=in_ws, ComponentNames=panel)
self._integrate(in_ws, out_ws, panel)
DeleteWorkspace(in_ws)
ReplaceSpecialValues(InputWorkspace=out_ws, OutputWorkspace=out_ws, NaNValue=0, NaNError=0)
panel_outputs.append(out_ws)
GroupWorkspaces(InputWorkspaces=panel_outputs, OutputWorkspace=panels_out_ws)
self.setProperty('PanelOutputWorkspaces', mtd[panels_out_ws])
if self._is_tof:
DeleteWorkspace(self._input_ws)
def _integrate(self, in_ws, out_ws, panel=None):
if self._output_type == 'I(Q)' or self._output_type == 'I(Phi,Q)':
self._integrate_iq(in_ws, out_ws, panel)
elif self._output_type == 'I(Qx,Qy)':
self._integrate_iqxy(in_ws, out_ws)
def _get_iq_binning(self, q_min, q_max, pixel_size, wavelength, l2, binning_factor):
"""
Returns the OutputBinning string to be used in Q1DWeighted
"""
if q_min < 0. or q_min >= q_max:
raise ValueError('qmin must be positive and smaller than qmax. '
'Given qmin={0:.2f}, qmax={0:.2f}.'.format(q_min, q_max))
binning = self.getProperty('OutputBinning').value
strategy = self.getPropertyValue('DefaultQBinning')
if len(binning) == 0:
if strategy == 'ResolutionBased':
q_binning = self._resolution_q_binning(q_min, q_max, binning_factor)
else:
if wavelength != 0:
run = mtd[self._input_ws].getRun()
instrument = mtd[self._input_ws].getInstrument()
if instrument.getName() == "D16" and run.hasProperty("Gamma.value"):
if instrument.hasParameter('detector-width'):
pixel_nb = instrument.getNumberParameter('detector-width')[0]
else:
self.log().warning("Width of the instrument not found. Assuming 320 pixels.")
pixel_nb = 320
q_binning = self._pixel_q_binning_non_aligned(q_min, q_max, pixel_nb, binning_factor)
else:
q_binning = self._pixel_q_binning(q_min, q_max, pixel_size * binning_factor, wavelength, l2)
else:
q_binning = self._tof_default_q_binning(q_min, q_max)
elif len(binning) == 1:
q_binning = [q_min, binning[0], q_max]
elif len(binning) == 2:
q_min_actual = max(q_min, binning[0])
q_max_actual = min(q_max, binning[1])
if q_min_actual >= q_max_actual:
raise ValueError('The provided q range does not overlap with the actual range:\n'
'provided [{0:.5f}, {1:.5f}] \n'
'actual [{2:.5f}, {3:.5f}]'
.format(binning[0], binning[1], q_min, q_max))
else:
self.log().notice('Using qmin_actual={0:.5f}, qmax_actual={1:.5f}'.format(q_min_actual, q_max_actual))
if strategy == 'ResolutionBased':
q_binning = self._resolution_q_binning(q_min_actual, q_max_actual, binning_factor)
else:
if wavelength != 0:
q_binning = self._pixel_q_binning(q_min_actual, q_max_actual, pixel_size * binning_factor, wavelength, l2)
else:
q_binning = self._tof_default_q_binning(q_min_actual, q_max_actual)
else:
q_binning = binning
return q_binning
def _tof_default_q_binning(self, q_min, q_max):
"""
Returns default q binning for tof mode
"""
return [q_min, -0.05, q_max]
def _pixel_q_binning_non_aligned(self, q_min, q_max, pixel_nb, binning_factor):
"""
Returns q binning based on q_min, q_max. Used when the detector is not aligned with axis Z.
"""
step = (q_max - q_min) * binning_factor / pixel_nb
return [q_min-step/2, step, q_max+step/2]
def _pixel_q_binning(self, q_min, q_max, pixel_size, wavelength, l2):
"""
Returns q binning based on the size of a single pixel within the range of q_min and q_max
Size is the largest size, i.e. max(height, width)
"""
bins = []
q = 0.
pixels = 1
while q < q_max:
two_theta = np.arctan(pixel_size * pixels / l2)
q = 4 * np.pi * np.sin(two_theta / 2) / wavelength
bins.append(q)
pixels += 1
q_bin_edges = np.array(bins[:-1])
q_bin_edges = q_bin_edges[np.where(q_bin_edges > q_min)]
q_bin_widths = np.diff(q_bin_edges)
q_binning = np.empty(2 * q_bin_edges.size - 1)
q_binning[0::2] = q_bin_edges
q_binning[1::2] = q_bin_widths
return q_binning
def _resolution_q_binning(self, qmin, qmax, factor):
"""
Returns q binning such that at each q, bin width is almost factor*sigma
"""
q = qmin
result = [qmin]
while q < qmax:
bin_width = factor * self._deltaQ(q)
result.append(bin_width)
q += bin_width
result.append(q)
return result
def _setup_mildner_carpenter(self):
"""
Sets up the mildner carpenter formula based on acquisition type and beam parameters
"""
run = mtd[self._input_ws].getRun()
wavelength = run.getLogData('wavelength').value
l1 = run.getLogData('collimation.actual_position').value
l2 = run.getLogData('L2').value
instrument = mtd[self._input_ws].getInstrument()
if instrument.hasParameter("x-pixel-size") and instrument.hasParameter("y-pixel-size"):
x3 = instrument.getNumberParameter('x-pixel-size')[0] / 1000
y3 = instrument.getNumberParameter('y-pixel-size')[0] / 1000
else:
raise RuntimeError('Unable to calculate resolution, missing pixel size.')
if 'selector.wavelength_res' in run:
delta_wavelength = run.getLogData('selector.wavelength_res').value * 0.01
elif 'selector.wave_lenght_res' in run:
delta_wavelength = run.getLogData('selector.wave_lenght_res').value * 0.01 # sic! log name for at least some D22 data
else:
raise RuntimeError("Wavelength resolution log not available.")
if run.hasProperty('collimation.sourceAperture'):
source_aperture = run.getLogData('collimation.sourceAperture').value
elif run.hasProperty('collimation.ap_size'):
source_aperture = str(run.getLogData('collimation.ap_size').value)
elif run.hasProperty('collimation.apt_size_1'): # D22
source_aperture = str(run.getLogData('collimation.apt_size_1').value)
else:
raise RuntimeError('Unable to calculate resolution, missing source aperture size.')
if not run.hasProperty('tof_mode'):
self.log().information('No TOF flag available, assuming monochromatic.')
to_meter = 0.001
is_rectangular = True
if 'x' not in source_aperture:
is_rectangular = False
if is_rectangular:
pos1 = source_aperture.find('(') + 1
pos2 = source_aperture.find('x')
pos3 = source_aperture.find(')')
x1 = float(source_aperture[pos1:pos2]) * to_meter
y1 = float(source_aperture[pos2 + 1:pos3]) * to_meter
x2 = run.getLogData('Beam.sample_ap_x_or_diam').value * to_meter
y2 = run.getLogData('Beam.sample_ap_y').value * to_meter
if self._is_tof:
raise RuntimeError('TOF resolution is not supported yet')
else:
self._deltaQ = MonochromaticScalarQCartesian(wavelength, delta_wavelength, x1, y1, x2, y2, x3, y3, l1, l2)
else:
if '(' in source_aperture:
pos1 = source_aperture.find('(') + 1
pos3 = source_aperture.find(')')
source_aperture = source_aperture[pos1:pos3]
r1 = float(source_aperture) * to_meter
r2 = run.getLogData('Beam.sample_ap_x_or_diam').value * to_meter
if self._is_tof:
raise RuntimeError('TOF resolution is not supported yet')
else:
self._deltaQ = MonochromaticScalarQCylindric(wavelength, delta_wavelength, r1, r2, x3, y3, l1, l2)
def _resolution_direct_beam(self):
if self._is_tof:
raise RuntimeError('TOF resolution is not supported yet')
run = mtd[self._input_ws].getRun()
wavelength = run.getLogData('wavelength').value
if 'selector.wavelength_res' in run:
delta_wavelength = run.getLogData('selector.wavelength_res').value * 0.01
elif 'selector.wave_lenght_res' in run:
delta_wavelength = run.getLogData('selector.wave_lenght_res').value * 0.01 # sic! log name for at least some D22 data
else:
raise RuntimeError("Wavelength resolution log not available.")
if 'BeamWidthX' in run:
beam_width = run.getLogData('BeamWidthX').value
else:
raise RuntimeError("BeamWidthX log not available. Have you provided empty beam measurement?")
self._deltaQ = DirectBeamResolution(wavelength, delta_wavelength, beam_width)
def _integrate_iqxy(self, ws_in, ws_out):
"""
Calls Qxy
"""
max_qxy = self.getProperty('MaxQxy').value
delta_q = self.getProperty('DeltaQ').value
log_binning = self.getProperty('IQxQyLogBinning').value
if max_qxy == -1:
qmax = mtd[ws_in].getRun().getLogData("qmax").value
max_qxy = qmax * 0.7071 # np.sqrt(2) / 2
self.log().information("Nothing ptovided for MaxQxy. Using a "
"calculated value: {0}".format(max_qxy))
if delta_q == -1:
if log_binning:
delta_q = max_qxy / 10
else:
delta_q = max_qxy / 64
self.log().information("Nothing provided for DeltaQ. Using a "
"calculated value: {0}".format(delta_q))
Qxy(InputWorkspace=ws_in, OutputWorkspace=ws_out, MaxQxy=max_qxy,
DeltaQ=delta_q, IQxQyLogBinning=log_binning)
def _integrate_iq(self, ws_in, ws_out, panel=None):
"""
Produces I(Q) or I(Phi,Q) using Q1DWeighted
"""
if self._resolution == 'MildnerCarpenter':
self._setup_mildner_carpenter()
elif self._resolution == 'DirectBeam':
self._resolution_direct_beam()
run = mtd[ws_in].getRun()
q_min_name = 'qmin'
q_max_name = 'qmax'
if panel:
q_min_name += ('_' + panel)
q_max_name += ('_' + panel)
q_min = run.getLogData(q_min_name).value
q_max = run.getLogData(q_max_name).value
self.log().information('From sample logs qmin={0:.5f}, qmax={1:.5f}'.format(q_min, q_max))
instrument = mtd[self._input_ws].getInstrument()
pixel_width = instrument.getNumberParameter('x-pixel-size')[0] / 1000
pixel_height = instrument.getNumberParameter('y-pixel-size')[0] / 1000
pixel_size = pixel_height if pixel_height >= pixel_width else pixel_width
binning_factor = self.getProperty('BinningFactor').value
wavelength = 0. # for TOF mode there is no wavelength
if run.hasProperty('wavelength'):
wavelength = run.getLogData('wavelength').value
l2 = run.getLogData('l2').value
q_binning = self._get_iq_binning(q_min, q_max, pixel_size, wavelength, l2, binning_factor)
n_wedges = self.getProperty('NumberOfWedges').value
pixel_division = self.getProperty('NPixelDivision').value
gravity = wavelength == 0.
shape_table = self.getProperty('ShapeTable').value
if self._output_type == 'I(Q)':
if panel:
# do not process wedges for panels
n_wedges = 0
shape_table = ''
wedge_ws = self.getPropertyValue('WedgeWorkspace')
wedge_angle = self.getProperty('WedgeAngle').value
wedge_offset = self.getProperty('WedgeOffset').value
asymm_wedges = self.getProperty('AsymmetricWedges').value
Q1DWeighted(InputWorkspace=ws_in,
OutputWorkspace=ws_out,
NumberOfWedges=n_wedges,
OutputBinning=q_binning,
AccountForGravity=gravity,
WedgeWorkspace=wedge_ws,
WedgeAngle=wedge_angle,
WedgeOffset=wedge_offset,
AsymmetricWedges=asymm_wedges,
NPixelDivision=pixel_division,
ShapeTable=shape_table)
if shape_table:
# if there is a shape table, the final number of wedges cannot be known beforehand
# (because of possible symmetry choices)
n_wedges = mtd[wedge_ws].size()
if self._resolution != 'None':
x = mtd[ws_out].readX(0)
mid_x = (x[1:] + x[:-1]) / 2
res = self._deltaQ(mid_x)
mtd[ws_out].setDx(0, res)
for wedge in range(n_wedges):
mtd[wedge_ws].getItem(wedge).setDx(0, res)
if n_wedges != 0:
self.setProperty('WedgeWorkspace', mtd[wedge_ws])
elif self._output_type == 'I(Phi,Q)':
wedge_ws = '__wedges' + ws_in
iq_ws = '__iq' + ws_in
wedge_angle = 360./n_wedges
azimuth_axis = NumericAxis.create(n_wedges)
azimuth_axis.setUnit("Phi")
for i in range(n_wedges):
azimuth_axis.setValue(i, i * wedge_angle)
Q1DWeighted(InputWorkspace=ws_in,
OutputWorkspace=iq_ws,
NumberOfWedges=n_wedges,
NPixelDivision=pixel_division,
OutputBinning=q_binning,
WedgeWorkspace=wedge_ws,
WedgeAngle=wedge_angle,
AsymmetricWedges=True,
AccountForGravity=gravity)
DeleteWorkspace(iq_ws)
ConjoinSpectra(InputWorkspaces=wedge_ws, OutputWorkspace=ws_out)
mtd[ws_out].replaceAxis(1, azimuth_axis)
DeleteWorkspace(wedge_ws)
if self._resolution != 'None':
x = mtd[ws_out].readX(0)
mid_x = (x[1:] + x[:-1]) / 2
res = self._deltaQ(mid_x)
for i in range(mtd[ws_out].getNumberHistograms()):
mtd[ws_out].setDx(i, res)
# Register algorithm with Mantid
AlgorithmFactory.subscribe(SANSILLIntegration)