def __init__(self, parent=None): QtGui.QMainWindow.__init__(self,parent) self.ui = Ui_MainWindow() self.ui.setupUi(self) QtCore.QObject.connect( self.ui.calcButton, QtCore.SIGNAL("clicked()"), self.calculate ) QtCore.QObject.connect( self.ui.Plot, QtCore.SIGNAL("clicked()"), self.plotData ) QtCore.QObject.connect( self.ui.OverPlot, QtCore.SIGNAL("clicked()"), self.addPlot) QtCore.QObject.connect( self.ui.ClearFlux, QtCore.SIGNAL("clicked()"), self.clearFluxAndRes) QtCore.QObject.connect(self.ui.actionLET,QtCore.SIGNAL("triggered()"), self.letSelected) QtCore.QObject.connect(self.ui.actionMARI,QtCore.SIGNAL("triggered()"), lambda : self.otherInstrumentSelected('MAR')) QtCore.QObject.connect(self.ui.actionMERLIN,QtCore.SIGNAL("triggered()"),lambda : self.otherInstrumentSelected('MER')) QtCore.QObject.connect(self.ui.actionMAPS,QtCore.SIGNAL("triggered()"), lambda : self.otherInstrumentSelected('MAP')) self.graph=None; self.loadData() tab_name = "Fllux And Resolution Table" self.t= newTable(tab_name, 28, 3) #table in which are insered each time the value for the plot #self.t.setColName(1, "Frequency") #self.t.setColName(2, "Flux") #self.t.setColName(3, "Resolution") for j in xrange(0,len(self.frequencies)): self.t.setCell(1, j+1, self.frequencies[j])
def __init__(self, parent=None): QtGui.QMainWindow.__init__(self, parent) self.ui = Ui_MainWindow() self.ui.setupUi(self) QtCore.QObject.connect(self.ui.calcButton, QtCore.SIGNAL("clicked()"), self.calculate) QtCore.QObject.connect(self.ui.Plot, QtCore.SIGNAL("clicked()"), self.plotData) QtCore.QObject.connect(self.ui.OverPlot, QtCore.SIGNAL("clicked()"), self.addPlot) QtCore.QObject.connect(self.ui.ClearFlux, QtCore.SIGNAL("clicked()"), self.clearFluxAndRes) QtCore.QObject.connect(self.ui.actionLET, QtCore.SIGNAL("triggered()"), self.letSelected) QtCore.QObject.connect(self.ui.actionMARI, QtCore.SIGNAL("triggered()"), lambda: self.otherInstrumentSelected('MAR')) QtCore.QObject.connect(self.ui.actionMERLIN, QtCore.SIGNAL("triggered()"), lambda: self.otherInstrumentSelected('MER')) QtCore.QObject.connect(self.ui.actionMAPS, QtCore.SIGNAL("triggered()"), lambda: self.otherInstrumentSelected('MAP')) self.graph = None self.loadData() tab_name = "Fllux And Resolution Table" self.t = newTable( tab_name, 28, 3) #table in which are insered each time the value for the plot #self.t.setColName(1, "Frequency") #self.t.setColName(2, "Flux") #self.t.setColName(3, "Resolution") for j in xrange(0, len(self.frequencies)): self.t.setCell(1, j + 1, self.frequencies[j])
class MainWindow(QtGui.QMainWindow): def __init__(self, parent=None): QtGui.QMainWindow.__init__(self,parent) self.ui = Ui_MainWindow() self.ui.setupUi(self) QtCore.QObject.connect( self.ui.calcButton, QtCore.SIGNAL("clicked()"), self.calculate ) QtCore.QObject.connect( self.ui.Plot, QtCore.SIGNAL("clicked()"), self.plotData ) QtCore.QObject.connect( self.ui.OverPlot, QtCore.SIGNAL("clicked()"), self.addPlot) QtCore.QObject.connect( self.ui.ClearFlux, QtCore.SIGNAL("clicked()"), self.clearFluxAndRes) QtCore.QObject.connect(self.ui.actionLET,QtCore.SIGNAL("triggered()"), self.letSelected) QtCore.QObject.connect(self.ui.actionMARI,QtCore.SIGNAL("triggered()"), lambda : self.otherInstrumentSelected('MAR')) QtCore.QObject.connect(self.ui.actionMERLIN,QtCore.SIGNAL("triggered()"),lambda : self.otherInstrumentSelected('MER')) QtCore.QObject.connect(self.ui.actionMAPS,QtCore.SIGNAL("triggered()"), lambda : self.otherInstrumentSelected('MAP')) self.graph=None; self.loadData() tab_name = "Fllux And Resolution Table" self.t= newTable(tab_name, 28, 3) #table in which are insered each time the value for the plot #self.t.setColName(1, "Frequency") #self.t.setColName(2, "Flux") #self.t.setColName(3, "Resolution") for j in xrange(0,len(self.frequencies)): self.t.setCell(1, j+1, self.frequencies[j]) def loadData(self): """ Loads and preprocess all data used for interpolation """ self.flux_matrix = np.multiply(self.loadMatrix("PyChop/small_matrix(flux).txt"),0.021) # *0.021 -- this gives n/cm^2/s. 0.021= (40/60)*0.5*(1/16) #40/60 is the fact that simulation is for 60uamps and not 40uamps beam power. #(1/16) accounts for neutron on a 4x4cm vanadium sample i.e. 16cm^2. #0.5 accounts for the factor of 2 difference between simulation and experimental self.flux_energies = array.array( 'f', [0.1, 0.2, 0.5, 0.8, 1.0, 1.5, 2.0, 2.5, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 13.0, 13.1, 14.0, 15.0, 16.0, 17.0, 18.0, 19.0, 20.0, 21.0, 22.0, 23.0, 24.0, 25.0, 26.0, 27.0, 28.0, 29.0, 30.0, 31.0, 32.0, 35.0, 38.0, 40.0] ) self.res_matrix = self.loadMatrix("PyChop/small_matrix(res).txt") self.res_energies = array.array( 'f', [0.2, 0.4, 0.6, 0.8, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40] ) self.frequencies = np.arange(30,310,10) self.ei=""; self.ei_min = 0.2 # max(min(self.flux_energies),min(self.res_energies)) self.ei_max = 40. #min(max(self.flux_energies),max(self.res_energies)) def loadMatrix(self,fileName): """ Opens specified ASCII file in proper format and loads it into a matrix. The interpolation is based on these data return the Numpy matrix read from the fileName provided """ thisDir= config.getString('mantidqt.python_interfaces_directory') input_file = open(thisDir + fileName, 'r') input_lines = [] data_matrix = [] #fix the data formata def convert_mantid_string(mantid_str): mantid_str = mantid_str.replace('.', '') mantid_str = mantid_str.replace(',', '.') return mantid_str for line in iter(input_file.readline, ''): input_lines.append(convert_mantid_string(line)) for line in input_lines: matrix_row = [] line_elems = line.split() for n in line_elems: matrix_row.append(float(n)) data_matrix.append(matrix_row) return data_matrix #python matrix. def interpolate_data(self,data_matrix,energies): """ interpolation based on the small matrices matrix_data """ #create the correct form for the array z values #the values of energy are related to the values on which the interpolation has been made. r = len(data_matrix) c = len(self.frequencies) data_matrix = np.reshape(data_matrix, (r, c)) val_flux = np.transpose(data_matrix) self.ei = self.ui.incidentEnergyValue.text() self.ei= float(self.ei) ei = [self.ei] #linear interpolation self.interpolation = interpolate.RectBivariateSpline(self.frequencies, energies, val_flux,kx=1, ky=1) #spline interpolation over the values of energy given. result = self.interpolation(self.frequencies, ei)#returns the value for the specific energy required ei. return result def letSelected(self): QtGui.QMessageBox.warning(self, "Currently You have to switch gui to select another instrument") self.ui.actionLET.setChecked(True) def otherInstrumentSelected(self,INAME): reply = QtGui.QMessageBox.question(self, 'Selecting : '+INAME, "Do you want to switch GUI?", QtGui.QMessageBox.Yes, QtGui.QMessageBox.No) if reply == QtGui.QMessageBox.Yes: config['default.instrument'] = INAME self.deleteLater() else: pass #QtGui.QMessageBox.setText(self,'Currently You have to switch GUI to have other instrument selected') def calculate(self): """returns the results of interpolation and prints them in the window. """ self.ei = self.ui.incidentEnergyValue.text() if self.ei == "": QtGui.QMessageBox.warning(self, "LETFlux", "No Ei entered. Please,insert energy value in the range from "+str(self.ei_min)+" to "+str(self.ei_max)+" meV \n") return self else: self.ei = float (self.ei) if self.ei< self.ei_min or self.ei > self.ei_max: self.ei=""; QtGui.QMessageBox.warning(self, "LETFlux", "Energy out of range.\n Please, Provide value between "+str(self.ei_min)+" and "+str(self.ei_max)+" meV \n") else: self.setUpTable() #self.ui.list.clear() string = 'Energy selected:' +' '+ str(self.ei) self.ui.list.insertItem(0,string) string_title = 'Frequency(Hz) Flux(n/s/cm^2) Resolution[ueV]' self.ui.list.insertItem(1,string_title) t=self.t; for i in xrange(0, len(self.frequencies)): string1 = str(self.frequencies[i])+' '+ "%e" % t.cell(2,i+1)+' '+ "%e"% t.cell(3,i+1) self.ui.list.insertItem(2+i,string1) return self def clearFluxAndRes(self): """ Clear flux and resolution text printed in flux and resolution window """ self.ui.list.clear() def setUpTable(self): flux = self.interpolate_data(self.flux_matrix,self.flux_energies) res = self.interpolate_data(self.res_matrix,self.res_energies) for i in range(0, len(flux)): self.t.setCell(2, i+1, flux[i]) self.t.setCell(3, i+1, res[i]) return self def plotData(self): """ Plot flux and resoulution in the new window """ if self.ei=="" : return self self.graph = newGraph("Flux and Resolution",2,1,2) l1 = self.graph.layer(1); l1.setAntialiasing() l1.setTitle("Flux") l1.setAxisTitle(Layer.Bottom, "Frequency [Hz]") l1.setAxisTitle(Layer.Left, "Flux [n/s/cm^2]") l1.showGrid() # self.graphFlux.insertCurve(self.t, "Flux/Frequency_2", Layer.Scatter) # legend = self.graphFlux.newLegend(str(self.ei)) l2 = self.graph.layer(2); l2.setAntialiasing() l2.setTitle("Resolution") l2.setAxisTitle(Layer.Bottom, "Frequency [Hz]") l2.setAxisTitle(Layer.Left, "Resolution [ueV]") # legend = self.graphRes.newLegend(str(self.ei)) # self.graphRes.insertCurve(self.t, "Resolution/Frequency_2", Layer.Scatter) l2.showGrid() self.addPlot(); self.raise_(); self.show() return self def addPlot(self): """ Adds plot to an existing graph """ if self.graph==None: self.plotData(); else: self.calculate() if self.ei == "": return try: l1 = self.graph.layer(1) # <- this is activeLayer() except AttributeError: QtGui.QMessageBox.warning(self, "LETFlux", "Plot has been deleted, Can not overplot. Plot graph first\n") return l1.addCurves(self.t, (1,2), Layer.Line, 1, 4) # l1.newLegend(str(self.ei)) l2 = self.graph.layer(2) # <- this is activeLayer() l2.addCurves(self.t, (1,3), Layer.Line, 1, 4) return
class MainWindow(QtGui.QMainWindow): def __init__(self, parent=None): QtGui.QMainWindow.__init__(self, parent) self.ui = Ui_MainWindow() self.ui.setupUi(self) QtCore.QObject.connect(self.ui.calcButton, QtCore.SIGNAL("clicked()"), self.calculate) QtCore.QObject.connect(self.ui.Plot, QtCore.SIGNAL("clicked()"), self.plotData) QtCore.QObject.connect(self.ui.OverPlot, QtCore.SIGNAL("clicked()"), self.addPlot) QtCore.QObject.connect(self.ui.ClearFlux, QtCore.SIGNAL("clicked()"), self.clearFluxAndRes) QtCore.QObject.connect(self.ui.actionLET, QtCore.SIGNAL("triggered()"), self.letSelected) QtCore.QObject.connect(self.ui.actionMARI, QtCore.SIGNAL("triggered()"), lambda: self.otherInstrumentSelected('MAR')) QtCore.QObject.connect(self.ui.actionMERLIN, QtCore.SIGNAL("triggered()"), lambda: self.otherInstrumentSelected('MER')) QtCore.QObject.connect(self.ui.actionMAPS, QtCore.SIGNAL("triggered()"), lambda: self.otherInstrumentSelected('MAP')) self.graph = None self.loadData() tab_name = "Fllux And Resolution Table" self.t = newTable( tab_name, 28, 3) #table in which are insered each time the value for the plot #self.t.setColName(1, "Frequency") #self.t.setColName(2, "Flux") #self.t.setColName(3, "Resolution") for j in xrange(0, len(self.frequencies)): self.t.setCell(1, j + 1, self.frequencies[j]) def loadData(self): """ Loads and preprocess all data used for interpolation """ self.flux_matrix = np.multiply( self.loadMatrix("PyChop/small_matrix(flux).txt"), 0.021) # *0.021 -- this gives n/cm^2/s. 0.021= (40/60)*0.5*(1/16) #40/60 is the fact that simulation is for 60uamps and not 40uamps beam power. #(1/16) accounts for neutron on a 4x4cm vanadium sample i.e. 16cm^2. #0.5 accounts for the factor of 2 difference between simulation and experimental self.flux_energies = array.array('f', [ 0.1, 0.2, 0.5, 0.8, 1.0, 1.5, 2.0, 2.5, 3.0, 4.0, 5.0, 6.0, 7.0, 8.0, 9.0, 10.0, 11.0, 13.0, 13.1, 14.0, 15.0, 16.0, 17.0, 18.0, 19.0, 20.0, 21.0, 22.0, 23.0, 24.0, 25.0, 26.0, 27.0, 28.0, 29.0, 30.0, 31.0, 32.0, 35.0, 38.0, 40.0 ]) self.res_matrix = self.loadMatrix("PyChop/small_matrix(res).txt") self.res_energies = array.array('f', [ 0.2, 0.4, 0.6, 0.8, 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 25, 26, 27, 28, 29, 30, 31, 32, 33, 34, 35, 36, 37, 38, 39, 40 ]) self.frequencies = np.arange(30, 310, 10) self.ei = "" self.ei_min = 0.2 # max(min(self.flux_energies),min(self.res_energies)) self.ei_max = 40. #min(max(self.flux_energies),max(self.res_energies)) def loadMatrix(self, fileName): """ Opens specified ASCII file in proper format and loads it into a matrix. The interpolation is based on these data return the Numpy matrix read from the fileName provided """ thisDir = config.getString('mantidqt.python_interfaces_directory') input_file = open(thisDir + fileName, 'r') input_lines = [] data_matrix = [] #fix the data formata def convert_mantid_string(mantid_str): mantid_str = mantid_str.replace('.', '') mantid_str = mantid_str.replace(',', '.') return mantid_str for line in iter(input_file.readline, ''): input_lines.append(convert_mantid_string(line)) for line in input_lines: matrix_row = [] line_elems = line.split() for n in line_elems: matrix_row.append(float(n)) data_matrix.append(matrix_row) return data_matrix #python matrix. def interpolate_data(self, data_matrix, energies): """ interpolation based on the small matrices matrix_data """ #create the correct form for the array z values #the values of energy are related to the values on which the interpolation has been made. r = len(data_matrix) c = len(self.frequencies) data_matrix = np.reshape(data_matrix, (r, c)) val_flux = np.transpose(data_matrix) self.ei = self.ui.incidentEnergyValue.text() self.ei = float(self.ei) ei = [self.ei] #linear interpolation self.interpolation = interpolate.RectBivariateSpline( self.frequencies, energies, val_flux, kx=1, ky=1) #spline interpolation over the values of energy given. result = self.interpolation( self.frequencies, ei) #returns the value for the specific energy required ei. return result def letSelected(self): QtGui.QMessageBox.warning( self, "Currently You have to switch gui to select another instrument") self.ui.actionLET.setChecked(True) def otherInstrumentSelected(self, INAME): reply = QtGui.QMessageBox.question(self, 'Selecting : ' + INAME, "Do you want to switch GUI?", QtGui.QMessageBox.Yes, QtGui.QMessageBox.No) if reply == QtGui.QMessageBox.Yes: config['default.instrument'] = INAME self.deleteLater() else: pass #QtGui.QMessageBox.setText(self,'Currently You have to switch GUI to have other instrument selected') def calculate(self): """returns the results of interpolation and prints them in the window. """ self.ei = self.ui.incidentEnergyValue.text() if self.ei == "": QtGui.QMessageBox.warning( self, "LETFlux", "No Ei entered. Please,insert energy value in the range from " + str(self.ei_min) + " to " + str(self.ei_max) + " meV \n") return self else: self.ei = float(self.ei) if self.ei < self.ei_min or self.ei > self.ei_max: self.ei = "" QtGui.QMessageBox.warning( self, "LETFlux", "Energy out of range.\n Please, Provide value between " + str(self.ei_min) + " and " + str(self.ei_max) + " meV \n") else: self.setUpTable() #self.ui.list.clear() string = 'Energy selected:' + ' ' + str(self.ei) self.ui.list.insertItem(0, string) string_title = 'Frequency(Hz) Flux(n/s/cm^2) Resolution[ueV]' self.ui.list.insertItem(1, string_title) t = self.t for i in xrange(0, len(self.frequencies)): string1 = str( self. frequencies[i]) + ' ' + "%e" % t.cell( 2, i + 1) + ' ' + "%e" % t.cell(3, i + 1) self.ui.list.insertItem(2 + i, string1) return self def clearFluxAndRes(self): """ Clear flux and resolution text printed in flux and resolution window """ self.ui.list.clear() def setUpTable(self): flux = self.interpolate_data(self.flux_matrix, self.flux_energies) res = self.interpolate_data(self.res_matrix, self.res_energies) for i in range(0, len(flux)): self.t.setCell(2, i + 1, flux[i]) self.t.setCell(3, i + 1, res[i]) return self def plotData(self): """ Plot flux and resoulution in the new window """ if self.ei == "": return self self.graph = newGraph("Flux and Resolution", 2, 1, 2) l1 = self.graph.layer(1) l1.setAntialiasing() l1.setTitle("Flux") l1.setAxisTitle(Layer.Bottom, "Frequency [Hz]") l1.setAxisTitle(Layer.Left, "Flux [n/s/cm^2]") l1.showGrid() # self.graphFlux.insertCurve(self.t, "Flux/Frequency_2", Layer.Scatter) # legend = self.graphFlux.newLegend(str(self.ei)) l2 = self.graph.layer(2) l2.setAntialiasing() l2.setTitle("Resolution") l2.setAxisTitle(Layer.Bottom, "Frequency [Hz]") l2.setAxisTitle(Layer.Left, "Resolution [ueV]") # legend = self.graphRes.newLegend(str(self.ei)) # self.graphRes.insertCurve(self.t, "Resolution/Frequency_2", Layer.Scatter) l2.showGrid() self.addPlot() self.raise_() self.show() return self def addPlot(self): """ Adds plot to an existing graph """ if self.graph == None: self.plotData() else: self.calculate() if self.ei == "": return try: l1 = self.graph.layer(1) # <- this is activeLayer() except AttributeError: QtGui.QMessageBox.warning( self, "LETFlux", "Plot has been deleted, Can not overplot. Plot graph first\n" ) return l1.addCurves(self.t, (1, 2), Layer.Line, 1, 4) # l1.newLegend(str(self.ei)) l2 = self.graph.layer(2) # <- this is activeLayer() l2.addCurves(self.t, (1, 3), Layer.Line, 1, 4) return