<string>Actually load the data and convert to MD, or just<br> proceed to the next tab using previously loaded data.</string>
</property>
<propertyname="text">
<string>Apply</string>
</property>
...
...
@@ -95,6 +101,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Name of the MD workspace to use. This name is set<br>by default, if data is loaded from an event file and mapped to an MD workspace.</string>
<string>Name of the event workspace to use. This name is set by default,<br> if data is loaded from an event file and mapped to an MD workspace.</string>
<string>Apply the Lorentz Correction as<br> data is mapped to reciprocal space and stored in the MD workspace. This helps with finding peaks with larger |Q|.</string>
</property>
<propertyname="text">
<string>Apply Lorentz Correction</string>
</property>
...
...
@@ -226,6 +256,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>Optionally, apply<br> calibration information from the specified .DetCal file(s).</string>
</property>
<propertyname="text">
<string> Load ISAW Detector Calibration</string>
</property>
...
...
@@ -252,6 +285,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Select the .DetCal file to apply.</string>
<string>Browse for the second .DetCal file to be used<br> for the second panel on SNAP.</string>
</property>
<propertyname="text">
<string>Browse</string>
</property>
...
...
@@ -316,6 +361,9 @@
<height>28</height>
</rect>
</property>
<propertyname="toolTip">
<string>Proceed to actually get the<br> peaks or use the existing peaks, as specified..</string>
</property>
<propertyname="text">
<string>Apply</string>
</property>
...
...
@@ -329,6 +377,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Use a peaks workspace with peaks that have been<br> been previously found, predicted, or loaded. </string>
</property>
<propertyname="text">
<string>Use Existing Peaks Workspace</string>
</property>
...
...
@@ -342,6 +393,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Search through the MD workspace to find Bragg peaks.</string>
</property>
<propertyname="text">
<string>Find Peaks</string>
</property>
...
...
@@ -368,6 +422,9 @@
<height>28</height>
</rect>
</property>
<propertyname="toolTip">
<string>Name of the peaks workspace to use. This name is set by default,<br> if data is loaded from an event file and mapped to an MD workspace on the Select Data tab.</string>
</property>
</widget>
<widgetclass="QLabel"name="MaxABC_lbl">
<propertyname="geometry">
...
...
@@ -391,6 +448,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Estimated maximum for real<br> space cell edge length in Angstroms. This is used to get an approximate lower bound on the possible distances between peaks.</string>
</property>
<propertyname="text">
<string>15</string>
</property>
...
...
@@ -417,6 +477,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Maximum number of peaks to find. Boxes with progressively<br> lower local intensity will be tried, until the specified number of peaks is found, or until the intensity falls below the specified Min Intensity.</string>
</property>
<propertyname="text">
<string>50</string>
</property>
...
...
@@ -443,6 +506,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Lower bound on the local intensity of MD boxes to consider as possible peaks, expressed as a multiple of the overall average intensity of the entire MD workspace region. Boxes with progressively<br> lower local intensity will be tried, until the specified number of peaks is found, or until the intensity falls below the specified Min Intensity.</string>
</property>
<propertyname="text">
<string>10000</string>
</property>
...
...
@@ -469,6 +535,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>Load the peaks workspace from a file of peaks<br> that have been previously found or predicted.</string>
</property>
<propertyname="text">
<string>Load ISAW Peaks (or Integrate) File</string>
</property>
...
...
@@ -482,6 +551,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Browse for the file of peaks to load.</string>
</property>
<propertyname="text">
<string>Browse</string>
</property>
...
...
@@ -508,6 +580,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Name of the peaks file that should be loaded.</string>
</property>
</widget>
</widget>
<widgetclass="QWidget"name="FindUB">
...
...
@@ -523,6 +598,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Find a UB matrix using the<br> FindUBUsingFFT algorithm. This will produce a UB matrix corresponding to the Niggli reduced cell for the lattice.</string>
</property>
<propertyname="text">
<string>Find UB Using FFT</string>
</property>
...
...
@@ -536,6 +614,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Find the UB matrix using the FindUBUsingIndexedPeaks algorithm. Specifically, if the<br> peaks in the peaks workspace have already been indexed, find the UB matrix that corresponds to that indexing.</string>
</property>
<propertyname="text">
<string>Find UB Using Indexed Peaks</string>
</property>
...
...
@@ -549,6 +630,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Load the UB matrix from a file.</string>
</property>
<propertyname="text">
<string>Load Isaw UB</string>
</property>
...
...
@@ -562,6 +646,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Browse for the file with the UB matrix.</string>
</property>
<propertyname="text">
<string>Browse</string>
</property>
...
...
@@ -575,6 +662,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>After obtaining the UB<br> matrix, index the peaks using that UB.</string>
</property>
<propertyname="text">
<string>Index Peaks Using UB</string>
</property>
...
...
@@ -588,6 +678,9 @@
<height>28</height>
</rect>
</property>
<propertyname="toolTip">
<string>Proceed to actually get the<br> UB matrix and (optionally) index the peaks.</string>
</property>
<propertyname="text">
<string>Apply</string>
</property>
...
...
@@ -614,6 +707,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Set this to a value that is<br> about 50%-90% of the shortest real space edge length, in Angstroms.</string>
</property>
<propertyname="text">
<string>3</string>
</property>
...
...
@@ -627,6 +723,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Set this to a value that is<br> about 110%-150% of the longest real space edge length, in Angstroms.</string>
</property>
<propertyname="text">
<string>15</string>
</property>
...
...
@@ -653,6 +752,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Maximum distance of h,k or l from integer values to<br> consider a peak to be indexed.</string>
</property>
<propertyname="text">
<string>0.12</string>
</property>
...
...
@@ -679,6 +781,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>Optimize the goniometer<br> angles, to index the peaks as accurately as possible using the UB matrix that was loaded.</string>
</property>
<propertyname="text">
<string>Optimize Phi, Chi and Omega</string>
</property>
...
...
@@ -705,6 +810,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Maximum number of degrees that CHI, PHI<br> or OMEGA can be changed.</string>
</property>
<propertyname="text">
<string>5</string>
</property>
...
...
@@ -731,6 +839,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Only set the h,k,l values on peaks for which the maximum distance of h,k or l from integer values<br> is less than this tolerance.</string>
</property>
<propertyname="text">
<string>0.12</string>
</property>
...
...
@@ -744,6 +855,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>Round the h,k,l values to the nearest integer.</string>
</property>
<propertyname="text">
<string>Round HKLs</string>
</property>
...
...
@@ -770,6 +884,9 @@
<height>31</height>
</rect>
</property>
<propertyname="toolTip">
<string>Name of the file with the UB matrix.</string>
</property>
</widget>
<widgetclass="QLabel"name="SelectUBFile_lbl">
<propertyname="geometry">
...
...
@@ -793,6 +910,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>If the peaks workspace<br> already has a UB matrix, just use that UB.</string>
</property>
<propertyname="text">
<string>Use Current UB (if already found or loaded)</string>
</property>
...
...
@@ -811,6 +931,9 @@
<height>28</height>
</rect>
</property>
<propertyname="toolTip">
<string>Proceed to show the<br> possible cells, or change the UB matrix and indexing, according to the options selected.</string>
</property>
<propertyname="text">
<string>Apply</string>
</property>
...
...
@@ -824,6 +947,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Show a list of the possible<br> conventional cells in the MantidPlot Results Log window. NOTE: The current UB must correspond to a Niggli reduced cell for these to be valid.</string>
</property>
<propertyname="text">
<string>Show Possible Cells</string>
</property>
...
...
@@ -837,6 +963,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Transform the current UB<br> matrix and indexing to correspond to the best fitting cell with the specified cell-type and centering.</string>
</property>
<propertyname="text">
<string>Select Cell of Type</string>
</property>
...
...
@@ -850,6 +979,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Transform the current UB<br> matrix and indexing to correspond to the cell with the specified Form number, as shown in the list of possible cells.</string>
</property>
<propertyname="text">
<string>Select Cell With Form</string>
</property>
...
...
@@ -863,6 +995,9 @@
<height>32</height>
</rect>
</property>
<propertyname="toolTip">
<string>The Form number of the<br> desired conventional cell.</string>
</property>
<item>
<propertyname="text">
<string>1</string>
...
...
@@ -1093,6 +1228,9 @@
<height>32</height>
</rect>
</property>
<propertyname="toolTip">
<string>The cell-type to be used.</string>
</property>
<item>
<propertyname="text">
<string>Cubic</string>
...
...
@@ -1138,6 +1276,9 @@
<height>32</height>
</rect>
</property>
<propertyname="toolTip">
<string>The centering to be used.</string>
</property>
<item>
<propertyname="text">
<string>C</string>
...
...
@@ -1186,6 +1327,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Maximum error allowed in the cell<br> scalars. If this is set very large, all possible conventional cells will be shown, including those that don't really match the current cell. If this is set too small, the desired correct cell may be missing from the list due to experimental error. The default value of 0.2 should usually work.</string>
</property>
<propertyname="text">
<string>0.2</string>
</property>
...
...
@@ -1199,6 +1343,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>Only show the best fitting<br> cell for each cell type and centering that is in the list of possible cells.</string>
</property>
<propertyname="text">
<string>Best Only</string>
</property>
...
...
@@ -1217,6 +1364,9 @@
<height>28</height>
</rect>
</property>
<propertyname="toolTip">
<string>Use the specified matrix<br> to update the peak indexes and UB matrix.</string>
</property>
<propertyname="text">
<string>Apply</string>
</property>
...
...
@@ -1230,6 +1380,9 @@
<height>18</height>
</rect>
</property>
<propertyname="toolTip">
<string>Transform the UB matrix<br> and peak indexes using the specified 3X3 matrix.</string>
</property>
<propertyname="text">
<string>Specify 3x3 Matrix to Apply to HKL</string>
</property>
...
...
@@ -1256,6 +1409,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>First row of the<br> transformation matrix to apply the HKL indexes.</string>
</property>
<propertyname="text">
<string>1, 0, 0</string>
</property>
...
...
@@ -1282,6 +1438,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Second row of the<br> transformation matrix to apply the HKL indexes.</string>
</property>
<propertyname="text">
<string>0, 1, 0</string>
</property>
...
...
@@ -1308,6 +1467,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Third row of the<br> transformation matrix to apply the HKL indexes.</string>
</property>
<propertyname="text">
<string>0, 0, 1</string>
</property>
...
...
@@ -1326,6 +1488,9 @@
<height>28</height>
</rect>
</property>
<propertyname="toolTip">
<string>Proceed to actually do the peak integration as specified.</string>
</property>
<propertyname="text">
<string>Apply</string>
</property>
...
...
@@ -1339,6 +1504,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Apply the IntegratePeaksMD<br> algorithm to integrate the current list of peaks, using spherical regions around the peaks in reciprocal space. This is the fastest of the integration methods. See the algorithm documentation for more details.</string>
</property>
<propertyname="text">
<string>Spherical Integration</string>
</property>
...
...
@@ -1352,6 +1520,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Apply the PeakIntegration<br> algorithm to integrate the current list of peaks, by combining the integrated intensities on multiple time-of-flight slices. This method is much slower than the Spherical Integration method, so please allow time for the calculation to complete. See the algorithm documentation for more details.</string>
</property>
<propertyname="text">
<string>2-D Fitting Integration</string>
</property>
...
...
@@ -1365,6 +1536,9 @@
<height>27</height>
</rect>
</property>
<propertyname="toolTip">
<string>Apply the IntegrateEllipsoids<br> algorithm to integrate the current list of peaks, by finding the principal axes of the 3D events in regions around each peak. This method is a little slower than the Spherical Integration method. See the algorithm documentation for more details.</string>
<string>Radius of a spherical region<br> around each peak that will be used when finding the principal axes. This should be large enough to include the entire peak and nearby background region, but not much larger.</string>
</property>
<propertyname="text">
<string>0.25</string>
</property>
...
...
@@ -1417,6 +1594,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Length of the major axis<br> to use for the ellipsoidal peak region.</string>
</property>
<propertyname="text">
<string>0.20</string>
</property>
...
...
@@ -1430,6 +1610,9 @@
<height>21</height>
</rect>
</property>
<propertyname="toolTip">
<string>If this is set true, the major axis<br> size of each ellipsoidal region will be constant for all peaks, and will be set by the following three parameters. If this is set false, the major axis sizes will be calculated based on the standard deviation in the direction of the major axis.</string>
</property>
<propertyname="text">
<string>Specify Size</string>
</property>
...
...
@@ -1456,6 +1639,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Length of the major axis<br> of the inner surface of the ellipsoidal shell used for the background region.</string>
</property>
<propertyname="text">
<string>0.20</string>
</property>
...
...
@@ -1482,6 +1668,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Length of the major axis<br> of the outer surface of the ellipsoidal shell used for the background region.</string>
</property>
<propertyname="text">
<string>0.25</string>
</property>
...
...
@@ -1508,6 +1697,9 @@
<height>21</height>
</rect>
</property>
<propertyname="toolTip">
<string>Parameters used to form<br> histograms from the event data. The first and last values are the start and end times-of-flight. The middle value is the step size. If the step size is negative it represents the decimal fraction increase in the bin boundary at each step, instead of the actual bin size.</string>
</property>
<propertyname="text">
<string>1000,-0.004,16000</string>
</property>
...
...
@@ -1534,6 +1726,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>The width of the border of<br> bad pixels around the edge of each detector that should be omitted.</string>
</property>
<propertyname="text">
<string>5</string>
</property>
...
...
@@ -1547,6 +1742,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>If true, the Ikeda-Carpenter<br> function will be used to fit the results of integrating the various time-of-flight slices, to obtain the final integrated result.</string>
</property>
<propertyname="text">
<string>Ikeda-Carpenter TOF</string>
</property>
...
...
@@ -1573,6 +1771,9 @@
<height>22</height>
</rect>
</property>
<propertyname="toolTip">
<string>Radius of the spherical<br> region that will be considered the body of the peak.</string>
</property>
<propertyname="text">
<string>0.20</string>
</property>
...
...
@@ -1599,6 +1800,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Radius of the inner surface<br> of the spherical shell that will be used for the background estimate.</string>
</property>
<propertyname="text">
<string>0.20</string>
</property>
...
...
@@ -1625,6 +1829,9 @@
<height>24</height>
</rect>
</property>
<propertyname="toolTip">
<string>Radius of the outer surface<br> of the spherical shell that will be used for the background estimate.</string>
</property>
<propertyname="text">
<string>0.25</string>
</property>
...
...
@@ -1638,6 +1845,9 @@
<height>23</height>
</rect>
</property>
<propertyname="toolTip">
<string>If true, all peaks will be<br> integrated. If false, any peak for which the background shell goes off the edge of the detector will not be integrated.</string>
<string>The X-coordinate of a point<br> of interest in reciprocal space specified in lab coordinates.</string>
</property>
<propertyname="text">
<string>0.0</string>
</property>
...
...
@@ -1672,6 +1885,9 @@
</item>
<item>
<widgetclass="QLineEdit"name="Qy_ledt">
<propertyname="toolTip">
<string>The Y-coordinate of a point<br> of interest in reciprocal space specified in lab coordinates.</string>
</property>
<propertyname="text">
<string>0.0</string>
</property>
...
...
@@ -1679,6 +1895,9 @@
</item>
<item>
<widgetclass="QLineEdit"name="Qz_ledt">
<propertyname="toolTip">
<string>The Z-coordinate of a point<br> of interest in reciprocal space specified in lab coordinates.</string>
</property>
<propertyname="text">
<string>0.0</string>
</property>
...
...
@@ -1686,6 +1905,9 @@
</item>
<item>
<widgetclass="QPushButton"name="ShowInfo_btn">
<propertyname="toolTip">
<string>Press this after entering<br> Qx,Qy,Qz in lab coordinates to display information about that point in the Selected Point Info table.</string>