コード例 #1
0
 def setUpClass(self):
     self.ws_MD_3D = CreateMDHistoWorkspace(
         Dimensionality=3,
         Extents='-3,3,-10,10,-1,1',
         SignalInput=range(100),
         ErrorInput=range(100),
         NumberOfBins='5,5,4',
         Names='Dim1,Dim2,Dim3',
         Units='MomentumTransfer,EnergyTransfer,Angstrom',
         OutputWorkspace='ws_MD_3D')
     self.ws_MDE_3D = CreateMDWorkspace(Dimensions='3',
                                        Extents='-3,3,-4,4,-5,5',
                                        Names='h,k,l',
                                        Units='rlu,rlu,rlu',
                                        SplitInto='4',
                                        OutputWorkspace='ws_MDE_3D')
     FakeMDEventData('ws_MDE_3D',
                     PeakParams='100000,0,0,0,0.1',
                     RandomSeed='63759',
                     RandomizeSignal='1')
     FakeMDEventData('ws_MDE_3D',
                     PeakParams='40000,1,0,0,0.1',
                     RandomSeed='63759',
                     RandomizeSignal='1')
     self.ws2d_histo = CreateWorkspace(DataX=[10, 20, 30, 10, 20, 30],
                                       DataY=[2, 3, 4, 5],
                                       DataE=[1, 2, 3, 4],
                                       NSpec=2,
                                       Distribution=True,
                                       UnitX='Wavelength',
                                       VerticalAxisUnit='DeltaE',
                                       VerticalAxisValues=[4, 6, 8],
                                       OutputWorkspace='ws2d_histo')
コード例 #2
0
    def setUpClass(cls):
        """
        Create fake workspaces, 3D and 2D
        """

        # 3D
        DeltaPDF3DTest_MDE = CreateMDWorkspace(Dimensions='3', Extents='-3.1,3.1,-3.1,3.1,-3.1,3.1', Names='[H,0,0],[0,K,0],[0,0,L]',
                                               Units='rlu,rlu,rlu', SplitInto='4',Frames='HKL,HKL,HKL')

        # Add Bragg peaks
        for h in range(-3,4):
            for k in range(-3,4):
                for l in range(-3,4):
                    FakeMDEventData(DeltaPDF3DTest_MDE, PeakParams='100,'+str(h)+','+str(k)+','+str(l)+',0.1', RandomSeed='1337')

        # Add addiontal peaks on [0.5,0.5,0.5] type positions
        # This would correspond to negative substitutional correlations
        for h in np.arange(-2.5,3):
            for k in np.arange(-2.5,3):
                for l in np.arange(-2.5,3):
                    FakeMDEventData(DeltaPDF3DTest_MDE, PeakParams='20,'+str(h)+','+str(k)+','+str(l)+',0.1', RandomSeed='13337')

        BinMD(InputWorkspace='DeltaPDF3DTest_MDE', AlignedDim0='[H,0,0],-3.05,3.05,61', AlignedDim1='[0,K,0],-3.05,3.05,61',
              AlignedDim2='[0,0,L],-3.05,3.05,61', OutputWorkspace='DeltaPDF3DTest_MDH')

        # 2D
        DeltaPDF3DTest_MDE_2 = CreateMDWorkspace(Dimensions='3', Extents='-3.1,3.1,-3.1,3.1,-0.1,0.1', Names='[H,0,0],[0,K,0],[0,0,L]',
                                                 Units='rlu,rlu,rlu', SplitInto='4',Frames='HKL,HKL,HKL')

        # Add Bragg peaks
        for h in range(-3,4):
            for k in range(-3,4):
                FakeMDEventData(DeltaPDF3DTest_MDE_2, PeakParams='100,'+str(h)+','+str(k)+',0,0.01', RandomSeed='1337')

        # Add addiontal peaks on [0.5,0.5,0.5] type positions
        # This would correspond to negative substitutional correlations
        for h in np.arange(-2.5,3):
            for k in np.arange(-2.5,3):
                FakeMDEventData(DeltaPDF3DTest_MDE_2, PeakParams='20,'+str(h)+','+str(k)+',0,0.1', RandomSeed='13337')

        BinMD(InputWorkspace='DeltaPDF3DTest_MDE_2', AlignedDim0='[H,0,0],-3.05,3.05,61', AlignedDim1='[0,K,0],-3.05,3.05,61',
              AlignedDim2='[0,0,L],-0.1,0.1,1', OutputWorkspace='DeltaPDF3DTest_MDH_2')
コード例 #3
0
    def test_mdhisto_workspace_q(self):
        from mantid.simpleapi import (CreateMDWorkspace, FakeMDEventData,
                                      BinMD)

        md_event = CreateMDWorkspace(Dimensions=3,
                                     Extents=[-10, 10, -10, 10, -10, 10],
                                     Names='Q_x,Q_y,Q_z',
                                     Units='U,U,U',
                                     Frames='QLab,QLab,QLab',
                                     StoreInADS=False)
        FakeMDEventData(InputWorkspace=md_event,
                        PeakParams=[100000, 0, 0, 0, 1],
                        StoreInADS=False)  # Add Peak
        md_histo = BinMD(InputWorkspace=md_event,
                         AlignedDim0='Q_y,-10,10,3',
                         AlignedDim1='Q_x,-10,10,4',
                         AlignedDim2='Q_z,-10,10,5',
                         StoreInADS=False)

        histo_data_array = mantidcompat.convert_MDHistoWorkspace_to_data_array(
            md_histo)

        self.assertEqual(histo_data_array.coords[sc.Dim.Qx].values.shape,
                         (4, ))
        self.assertEqual(histo_data_array.coords[sc.Dim.Qy].values.shape,
                         (3, ))
        self.assertEqual(histo_data_array.coords[sc.Dim.Qz].values.shape,
                         (5, ))
        self.assertEqual(histo_data_array.coords[sc.Dim.Qx].unit,
                         sc.units.dimensionless / sc.units.angstrom)
        self.assertEqual(histo_data_array.coords[sc.Dim.Qy].unit,
                         sc.units.dimensionless / sc.units.angstrom)
        self.assertEqual(histo_data_array.coords[sc.Dim.Qz].unit,
                         sc.units.dimensionless / sc.units.angstrom)

        self.assertEquals(histo_data_array.values.shape, (3, 4, 5))

        # Sum over 2 dimensions to simplify finding max.
        max_1d = sc.sum(sc.sum(histo_data_array, dim=sc.Dim.Qy),
                        dim=sc.Dim.Qx).values
        max_index = np.argmax(max_1d)
        # Check position of max 'peak'
        self.assertEqual(np.floor(len(max_1d) / 2), max_index)
        # All events in central 'peak'
        self.assertEqual(100000, max_1d[max_index])

        self.assertTrue('nevents' in histo_data_array.attrs)
コード例 #4
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    def runTest(self):
        HelperTestingClass.__init__(self)

        def scale_ws(ws):
            ws = ws * 100

        ws = CreateMDWorkspace(Dimensions='3',
                               EventType='MDEvent',
                               Extents='-10,10,-5,5,-1,1',
                               Names='Q_lab_x,Q_lab_y,Q_lab_z',
                               Units='1\\A,1\\A,1\\A')
        FakeMDEventData(ws, UniformParams="1000000")
        pres = SliceViewer(ws)
        self._assertNoErrorInADSHandlerFromSeparateThread(partial(scale_ws, ws))

        self._qapp.sendPostedEvents()

        self.assertTrue(pres.view in self.find_widgets_of_type(str(type(pres.view))))
        self.assertNotEqual(pres.ads_observer, None)

        pres.view.close()
コード例 #5
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    def test_view_updates_on_replace_when_model_properties_dont_change_mdeventws(
            self):
        def scale_ws(ws):
            ws = ws * 100

        ws = CreateMDWorkspace(Dimensions='3',
                               EventType='MDEvent',
                               Extents='-10,10,-5,5,-1,1',
                               Names='Q_lab_x,Q_lab_y,Q_lab_z',
                               Units='1\\A,1\\A,1\\A')
        FakeMDEventData(ws, UniformParams="1000000")
        pres = SliceViewer(ws)
        self._assertNoErrorInADSHandlerFromSeparateThread(partial(
            scale_ws, ws))

        QApplication.sendPostedEvents()

        self.assertTrue(
            pres.view in self.find_widgets_of_type(str(type(pres.view))))
        self.assertNotEqual(pres.ads_observer, None)

        pres.view.close()
コード例 #6
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ファイル: test_mantid.py プロジェクト: scipp/scippneutron
    def test_mdhisto_workspace_many_dims(self):
        from mantid.simpleapi import (CreateMDWorkspace, FakeMDEventData,
                                      BinMD)

        md_event = CreateMDWorkspace(
            Dimensions=4,
            Extents=[-10, 10, -10, 10, -10, 10, -10, 10],
            Names='deltae,y,z,T',
            Units='U,U,U,U',
            StoreInADS=False)
        FakeMDEventData(InputWorkspace=md_event,
                        PeakParams=[100000, 0, 0, 0, 0, 1],
                        StoreInADS=False)  # Add Peak
        md_histo = BinMD(InputWorkspace=md_event,
                         AlignedDim0='deltae,-10,10,3',
                         AlignedDim1='y,-10,10,4',
                         AlignedDim2='z,-10,10,5',
                         AlignedDim3='T,-10,10,7',
                         StoreInADS=False)

        histo_data_array = scn.mantid.convert_MDHistoWorkspace_to_data_array(
            md_histo)
        self.assertEqual(4, len(histo_data_array.dims))
コード例 #7
0
ファイル: HB3AWorkflowTests.py プロジェクト: durong24/mantid
    def runTest(self):
        # Na Mn Cl3
        # R -3 H (148)
        # 6.592 6.592 18.585177 90 90 120

        # UB/wavelength from /HFIR/HB3A/IPTS-25470/shared/autoreduce/HB3A_exp0769_scan0040.nxs

        ub = np.array([[1.20297e-01, 1.70416e-01, 1.43000e-04],
                       [8.16000e-04, -8.16000e-04, 5.38040e-02],
                       [1.27324e-01, -4.05110e-02, -4.81000e-04]])

        wavelength = 1.553

        # create fake MDEventWorkspace, similar to what is expected from exp769 after loading with HB3AAdjustSampleNorm
        MD_Q_sample = CreateMDWorkspace(
            Dimensions='3',
            Extents='-5,5,-5,5,-5,5',
            Names='Q_sample_x,Q_sample_y,Q_sample_z',
            Units='rlu,rlu,rlu',
            Frames='QSample,QSample,QSample')

        inst = LoadEmptyInstrument(InstrumentName='HB3A')
        AddTimeSeriesLog(inst, 'omega', '2010-01-01T00:00:00', 0.)
        AddTimeSeriesLog(inst, 'phi', '2010-01-01T00:00:00', 0.)
        AddTimeSeriesLog(inst, 'chi', '2010-01-01T00:00:00', 0.)
        MD_Q_sample.addExperimentInfo(inst)
        SetUB(MD_Q_sample, UB=ub)

        ol = OrientedLattice()
        ol.setUB(ub)

        sg = SpaceGroupFactory.createSpaceGroup("R -3")

        hkl = []
        sat_hkl = []

        for h in range(0, 6):
            for k in range(0, 6):
                for l in range(0, 11):
                    if sg.isAllowedReflection([h, k, l]):
                        if h == k == l == 0:
                            continue
                        q = V3D(h, k, l)
                        q_sample = ol.qFromHKL(q)
                        if not np.any(np.array(q_sample) > 5):
                            hkl.append(q)
                            FakeMDEventData(
                                MD_Q_sample,
                                PeakParams='1000,{},{},{},0.05'.format(
                                    *q_sample))
                        # satellite peaks at 0,0,+1.5
                        q = V3D(h, k, l + 1.5)
                        q_sample = ol.qFromHKL(q)
                        if not np.any(np.array(q_sample) > 5):
                            sat_hkl.append(q)
                            FakeMDEventData(
                                MD_Q_sample,
                                PeakParams='100,{},{},{},0.02'.format(
                                    *q_sample))
                        # satellite peaks at 0,0,-1.5
                        q = V3D(h, k, l - 1.5)
                        q_sample = ol.qFromHKL(q)
                        if not np.any(np.array(q_sample) > 5):
                            sat_hkl.append(q)
                            FakeMDEventData(
                                MD_Q_sample,
                                PeakParams='100,{},{},{},0.02'.format(
                                    *q_sample))

        # Check that this fake workpsace gives us the expected UB
        peaks = FindPeaksMD(MD_Q_sample,
                            PeakDistanceThreshold=1,
                            OutputType='LeanElasticPeak')
        FindUBUsingFFT(peaks, MinD=5, MaxD=20)
        ShowPossibleCells(peaks)
        SelectCellOfType(peaks,
                         CellType='Rhombohedral',
                         Centering='R',
                         Apply=True)
        OptimizeLatticeForCellType(peaks, CellType='Hexagonal', Apply=True)
        found_ol = peaks.sample().getOrientedLattice()
        self.assertAlmostEqual(found_ol.a(), 6.592, places=2)
        self.assertAlmostEqual(found_ol.b(), 6.592, places=2)
        self.assertAlmostEqual(found_ol.c(), 18.585177, places=2)
        self.assertAlmostEqual(found_ol.alpha(), 90)
        self.assertAlmostEqual(found_ol.beta(), 90)
        self.assertAlmostEqual(found_ol.gamma(), 120)

        # nuclear peaks
        predict = HB3APredictPeaks(
            MD_Q_sample,
            Wavelength=wavelength,
            ReflectionCondition='Rhombohedrally centred, obverse',
            SatellitePeaks=True,
            IncludeIntegerHKL=True)
        predict = HB3AIntegratePeaks(MD_Q_sample, predict, 0.25)

        self.assertEqual(predict.getNumberPeaks(), 66)
        # check that the found peaks are expected
        for n in range(predict.getNumberPeaks()):
            HKL = predict.getPeak(n).getHKL()
            self.assertTrue(HKL in hkl, msg=f"Peak {n} with HKL={HKL}")

        # magnetic peaks
        satellites = HB3APredictPeaks(
            MD_Q_sample,
            Wavelength=wavelength,
            ReflectionCondition='Rhombohedrally centred, obverse',
            SatellitePeaks=True,
            ModVector1='0,0,1.5',
            MaxOrder=1,
            IncludeIntegerHKL=False)
        satellites = HB3AIntegratePeaks(MD_Q_sample, satellites, 0.1)

        self.assertEqual(satellites.getNumberPeaks(), 80)
        # check that the found peaks are expected
        for n in range(satellites.getNumberPeaks()):
            HKL = satellites.getPeak(n).getHKL()
            self.assertTrue(HKL in sat_hkl, msg=f"Peak {n} with HKL={HKL}")