Beispiel #1
0
    print "Exit"
    sys.exit(handle)

print "Setting up scan...\n"

daq.AdcSetAcq(handle, DaamNShot, 0, SCANS)
#Scan settings
daq.AdcSetScan(handle, channels, gains, flags)
#set scan rate
daq.AdcSetFreq(handle, RATE)
#Set buffer location, size and flag settings
daq.AdcTransferSetBuffer(handle, buffer, SCANS, CHANCOUNT,
                         DatmUpdateSingle + DatmCycleOff)

#Set to trigger immediatly
daq.SetTriggerEvent(handle, STARTSOURCE, DetsRisingEdge, channels[0], gains[0],
                    flags[0], DaqTypeAnalogLocal, 0, 0, DaqStartEvent)
#Set to stop when the requested number of scans is completed
daq.SetTriggerEvent(handle, STOPSOURCE, DetsRisingEdge, channels[0], gains[0],
                    flags[0], DaqTypeAnalogLocal, 0, 0, DaqStopEvent)
#begin data acquisition
print "Scanning...\n"
daq.AdcTransferStart(handle)
daq.AdcArm(handle)

active = 1
while not msvcrt.kbhit() and (active & DaafAcqActive):
    time.sleep(1)
    #transfer data into computer memory and halt acquisition when done
    active, retCount = daq.AdcTransferGetStat(handle)
    print active, retCount
#Setup Channel 0 for count mode
daq.SetOption(
    handle, channels[0], daqh.DcofChannel, daqh.DcotCounterEnhMeasurementMode,
    daqh.DcovCounterEnhMode_Counter + daqh.DcovCounterEnhCounter_ClearOnRead)
#Setup Channel 1 for count mode
daq.SetOption(
    handle, channels[1], daqh.DcofChannel, daqh.DcotCounterEnhMeasurementMode,
    daqh.DcovCounterEnhMode_Counter + daqh.DcovCounterEnhCounter_ClearOnRead)

#Set buffer location, size and flag settings
daq.AdcTransferSetBuffer(handle, buffer, SCANS, CHANCOUNT,
                         daqh.DatmUpdateSingle + daqh.DatmCycleOff)
#Set to Trigger on software trigger
daq.SetTriggerEvent(handle, STARTSOURCE, daqh.DetsRisingEdge, channels[0],
                    gains[0], flags[0], daqh.DaqTypeCounterLocal, 0, 0,
                    daqh.DaqStartEvent)
#Set to Stop when the requested number of scans is completed
daq.SetTriggerEvent(handle, STOPSOURCE, daqh.DetsRisingEdge, channels[0],
                    gains[0], flags[0], daqh.DaqTypeCounterLocal, 0, 0,
                    daqh.DaqStopEvent)

daq.DacSetOutputMode(handle, daqh.DddtLocal, 0, daqh.DdomStaticWave)
daq.DacWaveSetTrig(handle, daqh.DddtLocal, 0, daqh.DdtsImmediate, 0)
daq.DacWaveSetClockSource(handle, daqh.DddtLocal, 0, daqh.DdcsAdcClock)
daq.DacWaveSetFreq(handle, daqh.DddtLocal, 0, FREQ)
daq.DacWaveSetMode(handle, daqh.DddtLocal, 0, daqh.DdwmInfinite, 0)
daq.DacWaveSetBuffer(handle, daqh.DddtLocal, 0, bufx, COUNT,
                     daqh.DdtmUserBuffer)

#begin data acquisition
Beispiel #3
0
    sys.exit(handle)

print "Setting up scan...\n"

daq.AdcSetAcq(handle, daqh.DaamNShot, 0, SCANS)
#Scan settings
daq.AdcSetScan(handle, channels, gains, flags)
#set scan rate
daq.AdcSetFreq(handle, RATE)
#Set buffer location, size and flag settings
daq.AdcTransferSetBuffer(handle, buffer, BUFFSIZE, CHANCOUNT,
                         daqh.DatmUpdateSingle + daqh.DatmCycleOn)

#Set to Trigger on hardware analog
daq.SetTriggerEvent(handle, STARTSOURCE, daqh.DetsRisingEdge, channels[0],
                    gains[0], flags[0], daqh.DaqTypeAnalogLocal, VOLTAGESTART,
                    0, daqh.DaqStartEvent)
#SSet to Stop on software analog
daq.SetTriggerEvent(handle, STOPSOURCE, daqh.DetsFallingEdge, channels[0],
                    gains[0], flags[0], daqh.DaqTypeAnalogLocal, VOLTAGEEND, 0,
                    daqh.DaqStopEvent)

#begin data acquisition
print "waiting for trigger voltage...\n"
daq.AdcTransferStart(handle)
daq.AdcArm(handle)

active, retCount = daq.AdcTransferGetStat(handle)
while not (active & daqh.DaafAcqTriggered) and (active & daqh.DaafAcqActive):
    time.sleep(0.1)
    active, retCount = daq.AdcTransferGetStat(handle)
Beispiel #4
0
    def raster(self):
        minVolt = -10.0
        maxVolt = 10.0
        freq = 1
        COUNT = 68 * 62
        FREQ = freq * COUNT
        x = []
        y = []
        NS = freq * 1
        i = 0
        while i < 62:
            j = 0
            while j < 62:
                x.append(j)
                y.append(i)
                j += 1
            j = 61
            if i is not 61:
                while j >= 10:
                    j -= 10
                    x.append(j)
                    y.append(i)
            if i is 61:  # The scan now has 62+6 points in each line and when it reaches the last line, it uses the same 6 points to go to beginning point
                while j >= 10:  # For the actual data that we are interested, we have to ignore 6 points after every 62 points
                    j -= 10
                    i -= 10
                    x.append(j)
                    y.append(i)
                i = 61
            i += 1

        cnt_x = ((((np.array(x) * 0.01 - minVolt) * 65535 /
                   (maxVolt - minVolt)))).astype(np.uint16)
        cnt_y = ((((np.array(y) * 0.01 - minVolt) * 65535 /
                   (maxVolt - minVolt)))).astype(np.uint16)

        daq.DacSetOutputMode(handle, daqh.DddtLocal, 1, daqh.DdomStaticWave)
        daq.DacWaveSetTrig(handle, daqh.DddtLocal, 1, daqh.DdtsImmediate, 0)
        daq.DacWaveSetClockSource(handle, daqh.DddtLocal, 1, daqh.DdcsAdcClock)
        daq.DacWaveSetFreq(handle, daqh.DddtLocal, 1, FREQ)
        daq.DacWaveSetMode(handle, daqh.DddtLocal, 1, daqh.DdwmNShot,
                           NS * COUNT)
        daq.DacWaveSetBuffer(handle, daqh.DddtLocal, 1, cnt_x, COUNT,
                             daqh.DdtmUserBuffer)
        daq.DacWaveSetUserWave(handle, daqh.DddtLocal, 1)

        daq.DacSetOutputMode(handle, daqh.DddtLocal, 2, daqh.DdomStaticWave)
        daq.DacWaveSetTrig(handle, daqh.DddtLocal, 2, daqh.DdtsImmediate, 0)
        daq.DacWaveSetClockSource(handle, daqh.DddtLocal, 2, daqh.DdcsAdcClock)
        daq.DacWaveSetFreq(handle, daqh.DddtLocal, 2, FREQ)
        daq.DacWaveSetMode(handle, daqh.DddtLocal, 2, daqh.DdwmNShot,
                           NS * COUNT)
        daq.DacWaveSetBuffer(handle, daqh.DddtLocal, 2, cnt_y, COUNT,
                             daqh.DdtmUserBuffer)
        daq.DacWaveSetUserWave(handle, daqh.DddtLocal, 2)

        self.rasterbuffer = np.ones(NS * COUNT, dtype=np.uint16)

        channels = [0]
        gains = [daqh.DgainDbd3kX1]
        flags = [daqh.DafCtr16]
        daq.AdcSetAcq(handle, daqh.DaamNShot, 0, NS * COUNT)
        daq.AdcSetScan(handle, channels, gains, flags)
        daq.AdcSetFreq(handle, FREQ)
        daq.SetOption(
            handle, 0, daqh.DcofChannel, daqh.DcotCounterEnhMeasurementMode,
            daqh.DcovCounterEnhMode_Counter +
            daqh.DcovCounterEnhCounter_ClearOnRead)
        daq.AdcTransferSetBuffer(handle, self.rasterbuffer, NS * COUNT, 1,
                                 daqh.DatmUpdateSingle + daqh.DatmCycleOff)
        daq.SetTriggerEvent(handle, daqh.DatsExternalTTL, daqh.DetsRisingEdge,
                            0, daqh.DgainDbd3kX1, daqh.DafCtr16,
                            daqh.DaqTypeCounterLocal, 0, 0, daqh.DaqStartEvent)
        daq.SetTriggerEvent(handle, daqh.DatsScanCount, daqh.DetsRisingEdge, 0,
                            daqh.DgainDbd3kX1, daqh.DafCtr16,
                            daqh.DaqTypeCounterLocal, 0, 0, daqh.DaqStopEvent)

        daq.AdcTransferStart(handle)
        daq.AdcArm(handle)
        print "waiting for Scan trigger...\n"
        daq.DacWaveArm(handle, daqh.DddtLocal)

        tm.sleep(1)
        handle1.Ctrig()

        print("Scanning...\n")

        active, retCount = daq.DacTransferGetStat(handle, daqh.DddtLocal, 1)
        while active & daqh.DdafTransferActive:
            active, retCount = daq.DacTransferGetStat(handle, daqh.DddtLocal,
                                                      1)
            #print(active, retCount)
        tm.sleep(
            0.1
        )  # Sometimes Data Acquisition isn't finished yet even though the DAC output is complete. Don't know why??? (Update frequencies and # of data points are the same)
        daq.AdcDisarm(handle)
        daq.DacWaveDisarm(handle, daqh.DddtLocal)

        print(self.rasterbuffer, len(self.rasterbuffer))
        imagedata = np.zeros((62, 62))
        i = j = k = 0
        while k < len(self.rasterbuffer):
            imagedata[j, i] = self.rasterbuffer[k]
            i += 1
            if i % 62 is 0:
                k += 6
                j += 1
                i = 0
            k += 1
        print(imagedata)

        plt.clf()
        plt.imshow(imagedata, cmap=cm.Greys_r)
        plt.show()
Beispiel #5
0
    def setup(self):
        # DAC:
        #   Use channel 0 for z-axis output
        #   Use PortAB for digital output streaming (provide a sync pulse indicating the start of the scan)
        #   run DAC output and ADC input (counters) synchronously at a low frequency (traditionally we used a binning frequency of 50000Hz/80 ~ 625Hz
        # dz/dV slope of piezo controller
        self.dz_dV = 15.0  # um/V (depends on controller and is an approximate value)
        self.z0 = 15.0  # um; z-offset (has to be positive to not damage the piezo)
        self.delz = 24.0  # um; typical travel of a z-scan
        self.T = float(
            input(
                "Enter the desired time, in seconds, for one complete zscan\n "
            ))  # s;  half period = time to complete an up (or down) ramp
        self.N = int(
            input("How many scans do you wish to perform in single run?\n"))
        self.Thalf = self.T / 2
        self.resolution = 1 << 16  # =2**16 (shift bit to left); 16-bit DAC
        self.resolution_half = 1 << 15  # =2**15
        self.Vrange = 20.0  # V; +-10V output range of DAC
        self.dV_DAC = self.Vrange / self.resolution
        self.vz = self.delz / self.Thalf  # speed of the ramp um/s

        # calculate the minimum update rate of DAC to ensure that voltage changes of dV_DAC result in an output update
        self.delV = self.delz / self.dz_dV  # voltage amplitude of ramp
        self.V0 = form.voltage  # voltage offset
        self.freq_min = self.delV / self.dV_DAC / self.Thalf  # minimum update frequency
        self.FREQ = max(1000,
                        self.freq_min)  # set a lower floor for freq of 1kHz
        # make sure the freq is compatible (commensurable) with the number of data point per scan
        self.nwavehalf = int(
            round(self.FREQ *
                  self.Thalf))  # number of data points in half of waveform
        self.nwave = self.nwavehalf * 2
        self.FREQ = self.nwavehalf / self.Thalf

        # generate scan waveform
        self.Vtup = (np.ones(self.nwavehalf).cumsum() - 1) / (
            self.nwavehalf - 1) * self.delV  # up-ramp voltage waveform
        self.Vtdown = np.fliplr([self.Vtup])[0]  # down-ramp voltage waveform
        self.l = len(
            self.Vtup
        ) / 2  # facilitates to make a ramp that starts from middle rather than bottom or top
        self.Vtmid = self.Vtup[self.l]
        self.Vtadjust = self.V0 - self.Vtmid  # facilitates the mid-ramp to start at the focus point set by piezo
        self.Vt = np.concatenate([
            self.Vtup[self.l:] + self.Vtadjust, self.Vtdown + self.Vtadjust,
            self.Vtup[:self.l] + self.Vtadjust
        ])
        self.Vt = np.tile(self.Vt, self.N)

        # convert Vt into DAC count waveform (-10V = 0,  0V = 32768,  +9.99969482421875V = 65535)
        # ((65535 - 32768 - 65535) + count) * dV_DAC = (count - 32768)*dV_DAC
        self.DACwave = np.around(self.Vt / self.dV_DAC +
                                 self.resolution_half).astype('uint16')

        # prepare waveform for digital output; used to mark the start of the scan
        # Note: make sure that the output port is initialized to LOW before start of waveform
        self.COUNT = self.N * self.nwave  # = SCANS
        self.bufSYNC = np.zeros(self.COUNT, dtype=np.uint16)
        self.bufSYNC[
            0] = 1  # |^|________ single pulse at start of digital waveform
        # to read SYNC connect A0 to CNT1

        # prepare ADC readSCAN
        self.SCANS = self.N * self.nwave  # = COUNT
        self.CHANCOUNT = 2
        self.channels = [0, 1]  # 16 bit counter, 16 bit counter
        self.gains = [daqh.DgainDbd3kX1, daqh.DgainDbd3kX1]  # ignored
        self.flags = [daqh.DafCtr16, daqh.DafCtr16]

        # get read buffer for photoncounts and sync pulses
        self.readbuffer = np.ones((self.SCANS * self.CHANCOUNT, ),
                                  dtype=np.uint16)

        # set start and stop conditions of readSCAN
        self.STARTSOURCE = daqh.DatsExternalTTL
        self.STOPSOURCE = daqh.DatsScanCount

        print "Setting up ADC scan...\n"
        daq.AdcSetAcq(handle, daqh.DaamNShot, 0, self.SCANS)
        # Scan settings
        daq.AdcSetScan(handle, self.channels, self.gains, self.flags)
        # set scan rate
        daq.AdcSetFreq(handle, self.FREQ)
        # Setup Channel 0 (photon counts) for count mode 16 bit, clear on read
        daq.SetOption(
            handle, self.channels[0], daqh.DcofChannel,
            daqh.DcotCounterEnhMeasurementMode,
            daqh.DcovCounterEnhMode_Counter +
            daqh.DcovCounterEnhCounter_ClearOnRead)
        # Setup Channel 1 (SYNC pulse read) for count mode 16 bit, clear on read
        daq.SetOption(
            handle, self.channels[1], daqh.DcofChannel,
            daqh.DcotCounterEnhMeasurementMode,
            daqh.DcovCounterEnhMode_Counter +
            daqh.DcovCounterEnhCounter_ClearOnRead)
        # Set buffer location, size and flag settings
        daq.AdcTransferSetBuffer(handle, self.readbuffer, self.SCANS,
                                 self.CHANCOUNT,
                                 daqh.DatmUpdateSingle + daqh.DatmCycleOff)
        # Set to Trigger on hardware trigger
        daq.SetTriggerEvent(handle, self.STARTSOURCE, daqh.DetsRisingEdge,
                            self.channels[0], self.gains[0], self.flags[0],
                            daqh.DaqTypeCounterLocal, 0, 0, daqh.DaqStartEvent)
        # Set to Stop when the requested number of scans is completed
        daq.SetTriggerEvent(handle, self.STOPSOURCE, daqh.DetsRisingEdge,
                            self.channels[0], self.gains[0], self.flags[0],
                            daqh.DaqTypeCounterLocal, 0, 0, daqh.DaqStopEvent)
        print("Setup complete.\n")
Beispiel #6
0
print "Setting up scan...\n"

daq.AdcSetAcq(handle, daqh.DaamInfinitePost, 0, READSCANS)
#Scan settings
daq.AdcSetScan(handle, channels, gains, flags)
#set scan rate
daq.AdcSetFreq(handle, RATE)
#Set buffer size and flag settings
#for circular driver buffer, set location to NULL, and set a size larger than the number of scans per second
daq.AdcTransferSetBuffer(
    handle, None, READSCANS * RATE, CHANCOUNT,
    daqh.DatmUpdateSingle + daqh.DatmCycleOn + daqh.DatmDriverBuf)
#Set to Trigger Immediatly
daq.SetTriggerEvent(handle, STARTSOURCE, TRIGSENSE, channels[0], gains[0],
                    flags[0], daqh.DaqTypeAnalogLocal, 0, 0,
                    daqh.DaqStartEvent)
#Set to Stop when scan is complete
daq.SetTriggerEvent(handle, STOPSOURCE, TRIGSENSE, channels[0], gains[0],
                    flags[0], daqh.DaqTypeAnalogLocal, 0, 0, daqh.DaqStopEvent)

#begin data acquisition
daq.AdcTransferStart(handle)
daq.AdcArm(handle)
print "\nTrigger Armed..."
key = raw_input("Hit return to issue software trigger...\n")
daq.AdcSoftTrig(handle)  #issue software trigger
print "--triggered--\n"

maxVolt = 10.0
scale = [