def startmeasurement(self): useinstruments.createinstruments(self.listsettings[0]) print 'All instruments loaded.' measurementvectors.createvectors(self.listsettings[0]) measurementvectors.createdatafile(self.listsettings[0]) useinstruments.initinstruments(self.listsettings[0],measurementvectors.v_dac,measurementvectors.v_vec,measurementvectors.instrument_array) measurementvectors.createplots(self.listsettings[0]) qt.mstart() print 'measurement started...' measurementvectors.measurementloop(self.listsettings[0]) useinstruments.rampback(self.listsettings[0]) print 'measurement finished!' print 'ALL other Voltages and Fields hanging at last value' qt.mend() self.delete_from_waitinglist()
def startmeasurement(self):
useinstruments.createinstruments(self.listsettings[0])
print 'All instruments loaded.'
measurementvectors.createvectors(self.listsettings[0])
measurementvectors.createdatafile(self.listsettings[0])
useinstruments.initinstruments(self.listsettings[0],
measurementvectors.v_dac,
measurementvectors.v_vec,
measurementvectors.instrument_array)
measurementvectors.createplots(self.listsettings[0])
qt.mstart()
print 'measurement started...'
measurementvectors.measurementloop(self.listsettings[0])
useinstruments.rampback(self.listsettings[0])
print 'measurement finished!'
print 'ALL other Voltages and Fields hanging at last value'
qt.mend()
self.delete_from_waitinglist()
def on_measure_clicked(self,widget):
from numpy import pi, random, arange, size
# Get entries and save them. Then DONT close the input-window.
self.blank_activate()
initgui.get_entries(self.xml,self.settings)
self.pkl_out_file = open('cleanlastsettings.pkl', 'wb')
pickle.dump(self.settings, self.pkl_out_file)
self.pkl_out_file.close()
if self.settings['number_of_measurements']==0:
print 'no measurement selected'
## self.checkMW = self.settings['checkMW']
## self.checkRF1 = self.settings['checkRF1']
## self.checkRF2 = self.settings['checkRF2']
## self.checkMag = self.settings['checkMag']
## self.checkTemp = self.settings['checkTemp']
## self.checkLaser = self.settings['checkLaser']
# Create instruments 'dac' used as a general term, can be time/field etc
## print 'loading instruments...'
#### self.ivvi = qt.instruments.create('ivvi','IVVI',address='COM1')
## print 'dacs OK'
#### self.NIDev1 = qt.instruments.create('NIDev1','NI_DAQ',id='Dev1',samples=self.settings['num_samples'],freq=self.settings['samplerate'])
## print 'adcs OK'
useinstruments.createinstruments(self.settings)
## if self.checkRF1:
## try:
## print self.HPPulse1.get_all()
## except:
## print 'Pulser 1 not set up yet...'
## self.HPPulse1 = qt.instruments.create('HPPulse1','HP_8131A',address=self.settings['addr1'],reset=False)
## print 'Pulser 1 OK'
##
## if self.checkRF2:
## try:
## print self.HPPulse2.get_all()
## except:
## print 'Pulser 2 not set up yet...'
## self.HPPulse2 = qt.instruments.create('HPPulse2','HP_8131A',address=self.settings['addr2'],reset=False)
## print 'Pulser 2 OK'
##
## if self.checkMW:
## try:
## print self.MWgen.get_all()
## except:
## print 'MW generator not set up yet...'
## self.MWgen = qt.instruments.create('MWgen','Agilent_E8257C',address=self.settings['addr3'],reset=False)
## print 'MW generator OK'
##
## if self.checkMag:
## try:
## print self.OXMag.get_all()
## except:
## print 'Magnet not set up yet...'
## self.OXMag = qt.instruments.create('OXMag','OxfordInstruments_IPS120',address=self.settings['addr4'])
## print 'Magnet OK'
##
## if self.checkTemp:
## ##try:
## ##print self.OXtemp.get_all()
## ##except:
## ##print 'Instrument not set up yet...'
## ##self.OXtemp = qt.instruments.create('?','?',address=self.settings['addr5'])
## print 'Temperature controller cannot be used at the moment'
##
## if self.checkLaser:
## try:
## print self.jdsu.get_all()
## except:
## print 'Laser not set up yet...'
## self.jdsu = qt.instruments.create('jdsu','JDSU_SWS15101',address=self.settings['addr6'])
## print 'Laser OK'
print 'All instruments loaded.'
#initialise things
## if self.checkMag:
## self.OXMag.init_magnet(min(self.settings['magrate'],1)) #specify sweeprate in T/min hardlimit of 1T/min
#!! DONT Ramp all dacs back to zero!!
## pauseT1 = float(self.settings['pause1'])
## pauseT2 = float(self.settings['pause2'])
##
## CurrentLim = float(self.settings['current_lim'])
measurementvectors.createvectors(self.settings)
## v_dac = []
## v_vec = []
## number_of_sweeps = self.settings['number_of_sweeps']
## number_of_inputs = self.settings['number_of_measurements']
##
## # Set gain
## self.I_gain = []
## for idx in range(3):
## if self.settings['input'][idx] != 0:
## self.I_gain.append(float(self.settings['inputgain'][idx]))
## else:
## self.I_gain.append('none')
##
## #Create measurement vectors for dacs
## for idx in range(16):
## print self.settings['outputdac'][idx]
## if self.settings['dynamic'][idx] != 0:
## v_dac.append('dac%d' % self.settings['outputdac'][idx])
## incrval = abs(float(self.settings['incr'][idx]))
## if float(self.settings['start'][idx]) - float(self.settings['stop'][idx]) > 0:
## incrval = -1*incrval
## v_vec.append(arange(float(self.settings['start'][idx]),float(self.settings['stop'][idx])+0.01*incrval,incrval))
## elif self.settings['outputdac'][idx] != 0:
## v_dac.append('dac%d' % self.settings['outputdac'][idx])
## v_vec.append(float(self.settings['start'][idx]))
## else:
## v_dac.append('dac0')
## v_vec.append([0])
##
## instrument_array= []
## vector_array= []
## label_array= []
##
## for idx in range(number_of_sweeps):
## for jdx in range(16):
## if self.settings['order'][jdx] == '%d' % (idx+1):
## instrument_array.append(v_dac[jdx])
## vector_array.append(v_vec[jdx])
## label_array.append(self.settings['outputlabel'][jdx])
# Next a new data object is made.
# The file will be placed in the folder:
# <datadir>/<datestamp>/<timestamp>_testmeasurement/
# and will be called:
# <timestamp>_testmeasurement.dat
# to find out what 'datadir' is set to, type: qt.config.get('datadir')
measurementvectors.createdatafile(self.settings)
## data = qt.Data(name=self.settings['filename'])
##
## # Now you provide the information of what data will be saved in the
## # datafile. A distinction is made between 'coordinates', and 'values'.
## # Coordinates are the parameters that you sweep, values are the
## # parameters that you readout (the result of an experiment). This
## # information is used later for plotting purposes.
## # Adding coordinate and value info is optional, but recommended.
## # If you don't supply it, the data class will guess your data format.
##
## for idx in range (self.settings['number_of_sweeps']):
## data.add_coordinate(name=measurementvectors.label_array[idx])
## for idx in range (3):
## if self.settings['input'][idx]!=0:
## data.add_value(name=self.settings['inputlabel'][idx])
## else:
## data.add_value(name='no measurement')
useinstruments.initinstruments(self.settings,measurementvectors.v_dac,measurementvectors.v_vec,measurementvectors.instrument_array)
## for idx,dac in enumerate(v_dac):
## if idx > (number_of_dynamic_dacs-1):
## self.execute_set(dac,v_vec[idx]) print v_vec[idx]
## else:
## self.execute_set(dac,v_vec[idx][0]) print v_vec[idx][0]
## if self.checkRF1:
## self.HPPulse1.on(1)
## self.HPPulse1.on(2)
## if self.checkRF2:
## self.HPPulse2.on(1)
## if self.checkMW:
## self.MWgen.on()
## if self.checkMag:
## heateroff = True
## for idx in range(number_of_sweeps):
## if instrument_array[idx] == ('dac%d' % instrumentsused.Magpos):
## heateroff = False
## # Switch heater off if magnet is not swept
## if heateroff:
## if self.OXMag.get_switch_heater() == 1:
## self.OXMag.set_switch_heater(0)
## if self.checkTemp:
## if self.checkLaser:
measurementvectors.createplots(self.settings)
##
## # The next command will actually create the dirs and files, based
## # on the information provided above. Additionally a settingsfile
## # is created containing the current settings of all the instruments.
##
## data.create_file()
##
## # Next two plot-objects are created. First argument is the data object
## # that needs to be plotted. To prevent new windows from popping up each
## # measurement a 'name' can be provided so that window can be reused.
## # If the 'name' doesn't already exists, a new window with that name
## # will be created. For 3d plots, a plotting style is set.
##
## if self.settings['plot2d'][0] and self.settings['input'][0]!=0:
## self.plot2d1=(qt.Plot2D(data, name='measure2D_1', coorddim=0, valdim=number_of_sweeps, maxtraces=2))
## if self.settings['plot3d'][0] and number_of_sweeps > 1 and self.settings['input'][0]!=0:
## self.plot3d1=(qt.Plot3D(data, name='measure3D_1', coorddims=(0,1), valdim=number_of_sweeps, style='image'))
## if self.settings['plot2d'][1] and self.settings['input'][1]!=0:
## self.plot2d2 = qt.Plot2D(data, name='measure2D_2', coorddim=0, valdim=number_of_sweeps+1, maxtraces=2)
## if self.settings['plot3d'][1] and number_of_sweeps > 1 and self.settings['input'][1]!=0:
## self.plot3d2 = qt.Plot3D(data, name='measure3D_2', coorddim=(0,1), valdim=number_of_sweeps+1, style='image')
## if self.settings['plot2d'][2] and self.settings['input'][2]!=0:
## self.plot2d3 = qt.Plot2D(data, name='measure2D_3', coorddim=0, valdim=number_of_sweeps+2, maxtraces=2)
## if self.settings['plot3d'][2] and number_of_sweeps > 1 and self.settings['input'][2]!=0:
## self.plot3d3 = qt.Plot3D(data, name='measure3D_3', coorddim=(0,1), valdim=number_of_sweeps+2, style='image')
##
qt.mstart()
print 'measurement started...'
# preparation is done, now start the measurement.
print 'BUGFIX: press ctrl-c once if graph not seen on first run'
measurementvectors.measurementloop(self.settings)
## number_of_traces = 1
## for idx in range(self.settings['number_of_sweeps']-1):
## number_of_traces = number_of_traces*len(measurementvectors.vector_array[idx+1])
##
## print('total number of traces: %d' %(number_of_traces))
## total_traces=number_of_traces
## starttime = time.time()
##
## for v1 in vector_array[number_of_sweeps-1]:
#### execute_set(instrument_array[number_of_sweeps-1],v1)
## if number_of_sweeps > 1:
## for v2 in vector_array[number_of_sweeps-2]:
#### execute_set(instrument_array[number_of_sweeps-2],v2)
## if number_of_sweeps > 2:
## for v3 in vector_array[number_of_sweeps-3]:
#### execute_set(instrument_array[number_of_sweeps-3],v3)
## if number_of_sweeps > 3:
## for v4 in vector_array[number_of_sweeps-4]:
#### execute_set(instrument_array[number_of_sweeps-2],v4)
## if number_of_sweeps > 4:
## for v5 in vector_array[number_of_sweeps-5]:
#### execute_set(instrument_array[number_of_sweeps-5],v5)
## self.measure_inputs()
## data.add_data_point(v5,v4,v3,v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v4,v3,v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## if number_of_sweeps==4:
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v3,v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## if number_of_sweeps==3:
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## if number_of_sweeps==2:
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
##
## if self.settings['plot2d'][0] and self.settings['input'][0]!=0:
## plot2d1_end = qt.Plot2D(data, name='measure2D1_end', coorddim=0, valdim=number_of_sweeps, maxpoints=1e6 ,maxtraces=1e3)
## plot2d1_end.update()
## if self.settings['plot2d'][1] and self.settings['input'][1]!=0:
## plot2d2_end = qt.Plot2D(data, name='measure2D2_end', coorddim=0, valdim=number_of_sweeps+1, maxpoints=1e6 ,maxtraces=1e3)
## plot2d2_end.update()
## if self.settings['plot2d'][2] and self.settings['input'][2]!=0:
## plot2d3_end = qt.Plot2D(data, name='measure2D3_end', coorddim=0, valdim=number_of_sweeps+2, maxpoints=1e6 ,maxtraces=1e3)
## plot2d3_end.update()
##
## # after the measurement ends, you need to close the data file.
##
## data.close_file()
##
## if self.settings['plot2d'][0] and self.settings['input'][0]!=0:
## plot2d1_end.save_png()
## if self.settings['plot2d'][1] and self.settings['input'][1]!=0:
## plot2d2_end.save_png()
## if self.settings['plot2d'][2] and self.settings['input'][2]!=0:
## plot2d3_end.save_png()
## if self.settings['plot3d'][0] and self.settings['input'][0]!=0:
## self.plot3d1.save_png()
## if self.settings['plot3d'][1] and self.settings['input'][1]!=0:
## self.plot3d2.save_png()
## if self.settings['plot3d'][2] and self.settings['input'][2]!=0:
## self.plot3d3.save_png()
#!DONT ramp dacs back to zero!
useinstruments.rampback(self.settings)
## if self.checkMW:
## self.MWgen.off()
## sleep(0.1)
##
## if self.checkRF1:
## pass
## #self.HPPulse1.off()
##
## if self.checkRF2:
## #self.HPPulse2.off(1)
## pass
##
## if self.checkMag:
## if self.OXMag.get_switch_heater() == 1:
## self.OXMag.set_switch_heater(0)
print 'measurement finished!'
print 'ALL other Voltages and Fields hanging at last value'
qt.mend()
def on_stopmeasure_clicked(self,widget): qt.flow.set_abort() print 'you want to stop - could be messy!' print 'attempting to switch off RF and MW' useinstruments.rampback(self.listssettings[0])
def on_measure_clicked(self, widget):
from numpy import pi, random, arange, size
# Get entries and save them. Then DONT close the input-window.
self.blank_activate()
initgui.get_entries(self.xml, self.settings)
self.pkl_out_file = open('cleanlastsettings.pkl', 'wb')
pickle.dump(self.settings, self.pkl_out_file)
self.pkl_out_file.close()
if self.settings['number_of_measurements'] == 0:
print 'no measurement selected'
## self.checkMW = self.settings['checkMW']
## self.checkRF1 = self.settings['checkRF1']
## self.checkRF2 = self.settings['checkRF2']
## self.checkMag = self.settings['checkMag']
## self.checkTemp = self.settings['checkTemp']
## self.checkLaser = self.settings['checkLaser']
# Create instruments 'dac' used as a general term, can be time/field etc
## print 'loading instruments...'
#### self.ivvi = qt.instruments.create('ivvi','IVVI',address='COM1')
## print 'dacs OK'
#### self.NIDev1 = qt.instruments.create('NIDev1','NI_DAQ',id='Dev1',samples=self.settings['num_samples'],freq=self.settings['samplerate'])
## print 'adcs OK'
useinstruments.createinstruments(self.settings)
## if self.checkRF1:
## try:
## print self.HPPulse1.get_all()
## except:
## print 'Pulser 1 not set up yet...'
## self.HPPulse1 = qt.instruments.create('HPPulse1','HP_8131A',address=self.settings['addr1'],reset=False)
## print 'Pulser 1 OK'
##
## if self.checkRF2:
## try:
## print self.HPPulse2.get_all()
## except:
## print 'Pulser 2 not set up yet...'
## self.HPPulse2 = qt.instruments.create('HPPulse2','HP_8131A',address=self.settings['addr2'],reset=False)
## print 'Pulser 2 OK'
##
## if self.checkMW:
## try:
## print self.MWgen.get_all()
## except:
## print 'MW generator not set up yet...'
## self.MWgen = qt.instruments.create('MWgen','Agilent_E8257C',address=self.settings['addr3'],reset=False)
## print 'MW generator OK'
##
## if self.checkMag:
## try:
## print self.OXMag.get_all()
## except:
## print 'Magnet not set up yet...'
## self.OXMag = qt.instruments.create('OXMag','OxfordInstruments_IPS120',address=self.settings['addr4'])
## print 'Magnet OK'
##
## if self.checkTemp:
## ##try:
## ##print self.OXtemp.get_all()
## ##except:
## ##print 'Instrument not set up yet...'
## ##self.OXtemp = qt.instruments.create('?','?',address=self.settings['addr5'])
## print 'Temperature controller cannot be used at the moment'
##
## if self.checkLaser:
## try:
## print self.jdsu.get_all()
## except:
## print 'Laser not set up yet...'
## self.jdsu = qt.instruments.create('jdsu','JDSU_SWS15101',address=self.settings['addr6'])
## print 'Laser OK'
print 'All instruments loaded.'
#initialise things
## if self.checkMag:
## self.OXMag.init_magnet(min(self.settings['magrate'],1)) #specify sweeprate in T/min hardlimit of 1T/min
#!! DONT Ramp all dacs back to zero!!
## pauseT1 = float(self.settings['pause1'])
## pauseT2 = float(self.settings['pause2'])
##
## CurrentLim = float(self.settings['current_lim'])
measurementvectors.createvectors(self.settings)
## v_dac = []
## v_vec = []
## number_of_sweeps = self.settings['number_of_sweeps']
## number_of_inputs = self.settings['number_of_measurements']
##
## # Set gain
## self.I_gain = []
## for idx in range(3):
## if self.settings['input'][idx] != 0:
## self.I_gain.append(float(self.settings['inputgain'][idx]))
## else:
## self.I_gain.append('none')
##
## #Create measurement vectors for dacs
## for idx in range(16):
## print self.settings['outputdac'][idx]
## if self.settings['dynamic'][idx] != 0:
## v_dac.append('dac%d' % self.settings['outputdac'][idx])
## incrval = abs(float(self.settings['incr'][idx]))
## if float(self.settings['start'][idx]) - float(self.settings['stop'][idx]) > 0:
## incrval = -1*incrval
## v_vec.append(arange(float(self.settings['start'][idx]),float(self.settings['stop'][idx])+0.01*incrval,incrval))
## elif self.settings['outputdac'][idx] != 0:
## v_dac.append('dac%d' % self.settings['outputdac'][idx])
## v_vec.append(float(self.settings['start'][idx]))
## else:
## v_dac.append('dac0')
## v_vec.append([0])
##
## instrument_array= []
## vector_array= []
## label_array= []
##
## for idx in range(number_of_sweeps):
## for jdx in range(16):
## if self.settings['order'][jdx] == '%d' % (idx+1):
## instrument_array.append(v_dac[jdx])
## vector_array.append(v_vec[jdx])
## label_array.append(self.settings['outputlabel'][jdx])
# Next a new data object is made.
# The file will be placed in the folder:
# <datadir>/<datestamp>/<timestamp>_testmeasurement/
# and will be called:
# <timestamp>_testmeasurement.dat
# to find out what 'datadir' is set to, type: qt.config.get('datadir')
measurementvectors.createdatafile(self.settings)
## data = qt.Data(name=self.settings['filename'])
##
## # Now you provide the information of what data will be saved in the
## # datafile. A distinction is made between 'coordinates', and 'values'.
## # Coordinates are the parameters that you sweep, values are the
## # parameters that you readout (the result of an experiment). This
## # information is used later for plotting purposes.
## # Adding coordinate and value info is optional, but recommended.
## # If you don't supply it, the data class will guess your data format.
##
## for idx in range (self.settings['number_of_sweeps']):
## data.add_coordinate(name=measurementvectors.label_array[idx])
## for idx in range (3):
## if self.settings['input'][idx]!=0:
## data.add_value(name=self.settings['inputlabel'][idx])
## else:
## data.add_value(name='no measurement')
useinstruments.initinstruments(self.settings, measurementvectors.v_dac,
measurementvectors.v_vec,
measurementvectors.instrument_array)
## for idx,dac in enumerate(v_dac):
## if idx > (number_of_dynamic_dacs-1):
## self.execute_set(dac,v_vec[idx]) print v_vec[idx]
## else:
## self.execute_set(dac,v_vec[idx][0]) print v_vec[idx][0]
## if self.checkRF1:
## self.HPPulse1.on(1)
## self.HPPulse1.on(2)
## if self.checkRF2:
## self.HPPulse2.on(1)
## if self.checkMW:
## self.MWgen.on()
## if self.checkMag:
## heateroff = True
## for idx in range(number_of_sweeps):
## if instrument_array[idx] == ('dac%d' % instrumentsused.Magpos):
## heateroff = False
## # Switch heater off if magnet is not swept
## if heateroff:
## if self.OXMag.get_switch_heater() == 1:
## self.OXMag.set_switch_heater(0)
## if self.checkTemp:
## if self.checkLaser:
measurementvectors.createplots(self.settings)
##
## # The next command will actually create the dirs and files, based
## # on the information provided above. Additionally a settingsfile
## # is created containing the current settings of all the instruments.
##
## data.create_file()
##
## # Next two plot-objects are created. First argument is the data object
## # that needs to be plotted. To prevent new windows from popping up each
## # measurement a 'name' can be provided so that window can be reused.
## # If the 'name' doesn't already exists, a new window with that name
## # will be created. For 3d plots, a plotting style is set.
##
## if self.settings['plot2d'][0] and self.settings['input'][0]!=0:
## self.plot2d1=(qt.Plot2D(data, name='measure2D_1', coorddim=0, valdim=number_of_sweeps, maxtraces=2))
## if self.settings['plot3d'][0] and number_of_sweeps > 1 and self.settings['input'][0]!=0:
## self.plot3d1=(qt.Plot3D(data, name='measure3D_1', coorddims=(0,1), valdim=number_of_sweeps, style='image'))
## if self.settings['plot2d'][1] and self.settings['input'][1]!=0:
## self.plot2d2 = qt.Plot2D(data, name='measure2D_2', coorddim=0, valdim=number_of_sweeps+1, maxtraces=2)
## if self.settings['plot3d'][1] and number_of_sweeps > 1 and self.settings['input'][1]!=0:
## self.plot3d2 = qt.Plot3D(data, name='measure3D_2', coorddim=(0,1), valdim=number_of_sweeps+1, style='image')
## if self.settings['plot2d'][2] and self.settings['input'][2]!=0:
## self.plot2d3 = qt.Plot2D(data, name='measure2D_3', coorddim=0, valdim=number_of_sweeps+2, maxtraces=2)
## if self.settings['plot3d'][2] and number_of_sweeps > 1 and self.settings['input'][2]!=0:
## self.plot3d3 = qt.Plot3D(data, name='measure3D_3', coorddim=(0,1), valdim=number_of_sweeps+2, style='image')
##
qt.mstart()
print 'measurement started...'
# preparation is done, now start the measurement.
print 'BUGFIX: press ctrl-c once if graph not seen on first run'
measurementvectors.measurementloop(self.settings)
## number_of_traces = 1
## for idx in range(self.settings['number_of_sweeps']-1):
## number_of_traces = number_of_traces*len(measurementvectors.vector_array[idx+1])
##
## print('total number of traces: %d' %(number_of_traces))
## total_traces=number_of_traces
## starttime = time.time()
##
## for v1 in vector_array[number_of_sweeps-1]:
#### execute_set(instrument_array[number_of_sweeps-1],v1)
## if number_of_sweeps > 1:
## for v2 in vector_array[number_of_sweeps-2]:
#### execute_set(instrument_array[number_of_sweeps-2],v2)
## if number_of_sweeps > 2:
## for v3 in vector_array[number_of_sweeps-3]:
#### execute_set(instrument_array[number_of_sweeps-3],v3)
## if number_of_sweeps > 3:
## for v4 in vector_array[number_of_sweeps-4]:
#### execute_set(instrument_array[number_of_sweeps-2],v4)
## if number_of_sweeps > 4:
## for v5 in vector_array[number_of_sweeps-5]:
#### execute_set(instrument_array[number_of_sweeps-5],v5)
## self.measure_inputs()
## data.add_data_point(v5,v4,v3,v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v4,v3,v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## if number_of_sweeps==4:
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v3,v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## if number_of_sweeps==3:
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v2,v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
## if number_of_sweeps==2:
## data.new_block()
## self.update_3d_plots()
## sleep(pauseT1)
## totaltime= number_of_traces*(time.time()-starttime)/(total_traces-number_of_traces+1)
## print ('Time of measurement left: %d hours, %d minutes and %d seconds' %(floor(totaltime/3600),floor(fmod(totaltime,3600)/60),fmod(totaltime,60)))
## number_of_traces= number_of_traces-1
## else:
## self.measure_inputs()
## data.add_data_point(v1,self.result[0],self.result[1],self.result[2])
## self.update_2d_plots()
## sleep(pauseT2)
##
## if self.settings['plot2d'][0] and self.settings['input'][0]!=0:
## plot2d1_end = qt.Plot2D(data, name='measure2D1_end', coorddim=0, valdim=number_of_sweeps, maxpoints=1e6 ,maxtraces=1e3)
## plot2d1_end.update()
## if self.settings['plot2d'][1] and self.settings['input'][1]!=0:
## plot2d2_end = qt.Plot2D(data, name='measure2D2_end', coorddim=0, valdim=number_of_sweeps+1, maxpoints=1e6 ,maxtraces=1e3)
## plot2d2_end.update()
## if self.settings['plot2d'][2] and self.settings['input'][2]!=0:
## plot2d3_end = qt.Plot2D(data, name='measure2D3_end', coorddim=0, valdim=number_of_sweeps+2, maxpoints=1e6 ,maxtraces=1e3)
## plot2d3_end.update()
##
## # after the measurement ends, you need to close the data file.
##
## data.close_file()
##
## if self.settings['plot2d'][0] and self.settings['input'][0]!=0:
## plot2d1_end.save_png()
## if self.settings['plot2d'][1] and self.settings['input'][1]!=0:
## plot2d2_end.save_png()
## if self.settings['plot2d'][2] and self.settings['input'][2]!=0:
## plot2d3_end.save_png()
## if self.settings['plot3d'][0] and self.settings['input'][0]!=0:
## self.plot3d1.save_png()
## if self.settings['plot3d'][1] and self.settings['input'][1]!=0:
## self.plot3d2.save_png()
## if self.settings['plot3d'][2] and self.settings['input'][2]!=0:
## self.plot3d3.save_png()
#!DONT ramp dacs back to zero!
useinstruments.rampback(self.settings)
## if self.checkMW:
## self.MWgen.off()
## sleep(0.1)
##
## if self.checkRF1:
## pass
## #self.HPPulse1.off()
##
## if self.checkRF2:
## #self.HPPulse2.off(1)
## pass
##
## if self.checkMag:
## if self.OXMag.get_switch_heater() == 1:
## self.OXMag.set_switch_heater(0)
print 'measurement finished!'
print 'ALL other Voltages and Fields hanging at last value'
qt.mend()
def on_stopmeasure_clicked(self, widget):
qt.flow.set_abort()
print 'you want to stop - could be messy!'
print 'attempting to switch off RF and MW'
useinstruments.rampback(self.listssettings[0])
