示例#1
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    def FetchMeasurement(
        self,
        channelList="0",
        buf=None,
        timeout=1,
        arrayMeasurement=None,
    ):
        """
        Returns the waveform from a previously initiated acquisition 
        that the digitizer acquires for the specified channel. 
        
        numpy array needs to be Fortran ordered.
        """
        numAcquiredWaveforms = self.ActualNumWfms(channelList)
        numberOfChannels = len(','.split(channelList))
        arrayActualRecordLength = ViInt32(0)
        status = self.CALL('ActualMeasWfmSize', self,
                           ViInt32(arrayMeasurement),
                           byref(arrayActualRecordLength))
        if buf is None:
            buf = zeros([
                arrayActualRecordLength.value,
                numberOfChannels * numAcquiredWaveforms
            ],
                        order="F",
                        dtype=numpy.float64)
            samplesPerRecord = buf.shape[0]
            numberOfRecords = buf.shape[1]
        else:
            samplesPerRecord = buf.shape[0]
            numberOfRecords = buf.shape[1]
            if numberOfRecords < numAcquiredWaveforms * numberOfChannels:
                self.FetchNumberRecords = numberOfRecords / numberOfChannels
            assert numAcquiredWaveforms == numberOfRecords
            assert self.RecordLength >= samplesPerRecord

        data_type = {
            numpy.float64: '',
            numpy.int8: 'Binary8',
            numpy.int16: 'Binary16',
            numpy.int32: 'Binary32'
        }[buf.dtype.type]

        wfmInfoArray = wfmInfo * numAcquiredWaveforms
        self.info = wfmInfoArray()

        status = self.CALL("FetchArrayMeasurement" + data_type, self,
                           ViConstString(channelList), ViReal64(timeout),
                           ViInt32(arrayMeasurement), arrayActualRecordLength,
                           buf.ctypes.data, byref(self.info))
        x = []
        for i in self.info:
            xstart = i.absoluteInitialX.value
            xstep = i.xIncrement.value
            xn = i.actualSamples.value
            x = numpy.append(
                x, [numpy.arange(xstart, xstart + xn * xstep, xstep)])
        xshape = x.reshape((len(self.info), self.info[0].actualSamples.value))
        return xshape, buf.T
示例#2
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 def ConfigureHorizontalTiming(self,
                               sampleRate=20000000,
                               numPts=1000,
                               refPosition=0.5,
                               numRecords=1,
                               enforceRealtime=True):
     """
     Configures the common properties of the horizontal subsystem for
     a multirecord acquisition in terms of minimum sample rate.
     """
     self.RecordLength = numPts
     status = self.CALL('ConfigureHorizontalTiming', self,
                        ViReal64(sampleRate), ViInt32(numPts),
                        ViReal64(refPosition), ViInt32(numRecords),
                        ViBoolean(enforceRealtime))
     return
示例#3
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 def ConfigureAcquisition(self, acqType=VAL.NORMAL):
     """
     Configures how the digitizer acquires data and fills the wave-
     form record.
     """
     acquisitionType = ViInt32(acqType)
     status = self.CALL("ConfigureAcquisition", self, acquisitionType)
示例#4
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    def ExportSignal(self,
                     signal=NISCOPE_VAL_REF_TRIGGER,
                     outputTerminal=NISCOPE_VAL_RTSI_0,
                     signalIdentifier=""):
        """
Configures the digitizer to generate a signal that other devices can detect when
configured for digital triggering or sharing clocks. The signal parameter speci-
fies what condition causes the digitizer to generate the signal. The 
outputTerminal parameter specifies where to send the signal on the hardware 
(such as a PFI connector or RTSI line).

In cases where multiple instances of a particular signal exist, use the 
signalIdentifier input to specify which instance to control. For normal signals,
only one instance exists and you should leave this parameter set to the empty 
string. You can call this function multiple times and set each available line to
a different signal.

To unprogram a specific line on device, call this function with the signal you 
no longer want to export and set outputTerminal to NISCOPE_VAL_NONE.
        """

        status = self.CALL("ExportSignal", self, ViInt32(signal),
                           ViConstString(signalIdentifier),
                           ViConstString(outputTerminal))
        return status
示例#5
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    def Fetch(
        self,
        channelList="0",
        buf=None,
        timeout=1,
    ):
        """
        Returns the waveform from a previously initiated acquisition 
        that the digitizer acquires for the specified channel. 
        
        numpy array needs to be Fortran ordered.
        """
        if six.PY3:
            if isinstance(channelList, str):
                channelList = channelList.encode('ascii')
        numAcquiredWaveforms = self.ActualNumWfms(channelList)
        numberOfChannels = len(b','.split(channelList))
        if buf is None:
            buf = zeros(
                [self.RecordLength, numberOfChannels * numAcquiredWaveforms],
                order="F",
                dtype=numpy.float64)
            samplesPerRecord = buf.shape[0]
            numberOfRecords = buf.shape[1]
        else:
            samplesPerRecord = buf.shape[0]
            numberOfRecords = buf.shape[1]
            if numberOfRecords < numAcquiredWaveforms * numberOfChannels:
                self.FetchNumberRecords = numberOfRecords / numberOfChannels
            assert numAcquiredWaveforms == numberOfRecords
            assert self.RecordLength >= samplesPerRecord

        data_type = {
            numpy.float64: '',
            numpy.int8: 'Binary8',
            numpy.int16: 'Binary16',
            numpy.int32: 'Binary32'
        }[buf.dtype.type]

        wfmInfoArray = wfmInfo * numAcquiredWaveforms
        self.info = wfmInfoArray()

        # Enclosing CALL into try except because the exception
        # that is likely to be raised is overflow warnings.
        # Without the try-except, no data will be returned at all.
        try:
            status = self.CALL("Fetch" + data_type, self,
                               ViConstString(channelList), ViReal64(timeout),
                               ViInt32(samplesPerRecord), buf.ctypes.data,
                               byref(self.info))
        except Exception as e:
            message = e.args[0]
            if six.PY3:
                message = message.decode('ascii')
            if message.startswith('Warning'):
                warnings.warn(message)
            else:
                raise

        return buf
示例#6
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 def AcquisitionStatus(self):
     """
     Returns status information about the acquisition to the status 
     output parameter.
     """
     acq_status = ViInt32()
     status = self.CALL("AcquisitionStatus", self, byref(acq_status))
     return acq_status.value
示例#7
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 def ActualNumWfms(self, channelList="0"):
     """
     Helps you to declare appropriately sized waveforms. NI-SCOPE 
     handles the channel list parsing for you.
     """
     chan = ViConstString(channelList)
     numWfms = ViInt32()
     self.CALL("ActualNumWfms", self, chan, byref(numWfms))
     return numWfms.value
示例#8
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    def errorHandler(self, errorCode):
        MAX_FUNCTION_NAME_SIZE = 55
        IVI_MAX_MESSAGE_LEN = 255
        IVI_MAX_MESSAGE_BUF_SIZE = IVI_MAX_MESSAGE_LEN + 1
        MAX_ERROR_DESCRIPTION = (IVI_MAX_MESSAGE_BUF_SIZE * 2 +
                                 MAX_FUNCTION_NAME_SIZE + 75)

        errorSource = create_string_buffer(MAX_FUNCTION_NAME_SIZE)
        errorDescription = create_string_buffer(MAX_ERROR_DESCRIPTION)
        self.CALL("errorHandler", self, ViInt32(errorCode), errorSource,
                  errorDescription)
        return errorDescription.value
示例#9
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 def ActualNumWfms(self, channelList="0"):
     """
     Helps you to declare appropriately sized waveforms. NI-SCOPE 
     handles the channel list parsing for you.
     """
     if six.PY3:
         if isinstance(channelList, str):
             channelList = channelList.encode('ascii')
     chan = ViConstString(channelList)
     numWfms = ViInt32()
     self.CALL("ActualNumWfms", self, chan, byref(numWfms))
     return numWfms.value
示例#10
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    def ActualRecordLength(self):
        """
        Returns the actual number of points the digitizer acquires for
        each channel. After configuring the digitizer for an acquisition
        , call this function to determine the size of the waveforms that
        the digitizer acquires. The value is equal to or greater than 
        the minimum number of points specified in any of the Configure 
        Horizontal functions.

        Allocate a ViReal64 array of this size or greater to pass as the
        waveformArray of the ReadWaveform and FetchWaveform functions. 
        """
        record = ViInt32()
        self.CALL("ActualRecordLength", self, byref(record))
        return record.value
示例#11
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 def ConfigureVertical(self,
                       channelList="0",
                       voltageRange=10,
                       offset=0,
                       coupling=COUPLING.DC,
                       probeAttenuation=1,
                       enabled=True):
     """
     Configures the most commonly configured attributes of the digi-
     tizer vertical subsystem, such as the range, offset, coupling, 
     probe attenuation, and the channel.
     """
     status = self.CALL("ConfigureVertical", self,
                        ViConstString(channelList), ViReal64(voltageRange),
                        ViReal64(offset), ViInt32(coupling),
                        ViReal64(probeAttenuation), ViBoolean(enabled))
     return status
示例#12
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    def Fetch(
        self,
        channelList="0",
        buf=None,
        timeout=1,
    ):
        """
        Returns the waveform from a previously initiated acquisition 
        that the digitizer acquires for the specified channel. 
        
        numpy array needs to be Fortran ordered.
        """
        numAcquiredWaveforms = self.ActualNumWfms(channelList)
        numberOfChannels = len(','.split(channelList))
        if buf is None:
            buf = zeros(
                [self.RecordLength, numberOfChannels * numAcquiredWaveforms],
                order="F",
                dtype=numpy.float64)
            samplesPerRecord = buf.shape[0]
            numberOfRecords = buf.shape[1]
        else:
            samplesPerRecord = buf.shape[0]
            numberOfRecords = buf.shape[1]
            if numberOfRecords < numAcquiredWaveforms * numberOfChannels:
                self.FetchNumberRecords = numberOfRecords / numberOfChannels
            assert numAcquiredWaveforms == numberOfRecords
            assert self.RecordLength >= samplesPerRecord

        data_type = {
            numpy.float64: '',
            numpy.int8: 'Binary8',
            numpy.int16: 'Binary16',
            numpy.int32: 'Binary32'
        }[buf.dtype.type]

        wfmInfoArray = wfmInfo * numAcquiredWaveforms
        self.info = wfmInfoArray()

        status = self.CALL("Fetch" + data_type, self,
                           ViConstString(channelList), ViReal64(timeout),
                           ViInt32(samplesPerRecord), buf.ctypes.data,
                           byref(self.info))
        return buf
示例#13
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 def ConfigureTrigger(self, trigger_type='Immediate', **settings):
     """
     Configures scope trigger type and settings. For each trigger 
     type distinct settings must be defined.
     
     Parameter       Valid Values
     
     trigger_type        'Edge'
                 'Hysteresis'
                 'Window'
                 'Window'
                 'Software'
                 'Immediate'
                 'Digital'
                 'Video'
 
 
     Trigger Type    Settings    Default Value   
     
     'Immediate' N/A
     
     'Edge'      triggerSource   TRIGGER_SOURCE.EXTERNAL
             level       0
             slope       SLOPE.POSITIVE
             triggerCoupling COUPLING.DC
             holdoff     0
             delay       0
     
     'Hysteresis'    triggerSource  '0'
             level       0
             hysteresis  0.05
             slope       SLOPE.POSITIVE
             triggerCoupling COUPLING.DC
             holdoff     0
             delay       0
         
     'Window'    triggerSource   '0'                
                     lowLevel    0                       
                     highLevel   0.1                                     windowMode  TRIGGER_WINDOW.ENTERING_WINDOW  
             triggerCoupling COUPLING.DC             
             holdoff     0
             delay       0       
             
     'Software'  holdoff     0
             delay       0   
     
     'Digital'   triggerSource   '0'
             slope       SLOPE.POSITIVE
             holdoff     0
             delay       0
     
     'Video'     triggerSource   '0'
             enableDCRestore False                               signalFormat    TV_TRIGGER_SIGNAL_FORMAT.VAL_PAL                event       TV_TRIGGER_EVENT.FIELD1 
             lineNumber  0
             polarity    TV_TRIGGER_POLARITY.TV_POSITIVE
             triggerCoupling COUPLING.DC
             holdoff     0
             delay           0 
     """
     args = {
         'Edge':
         lambda triggerSource=TRIGGER_SOURCE.EXTERNAL, level=0, slope=SLOPE.
         POSITIVE, triggerCoupling=COUPLING.DC, holdoff=0, delay=0:
         (ViConstString(triggerSource), ViReal64(level), ViInt32(slope),
          ViInt32(triggerCoupling), ViReal64(holdoff), ViReal64(delay)),
         'Hysteresis':
         lambda triggerSource='0', level=0, hysteresis=0.05, slope=SLOPE.
         POSITIVE, triggerCoupling=COUPLING.DC, holdoff=0, delay=0:
         (ViConstString(triggerSource), ViReal64(level), ViReal64(
             hysteresis), ViInt32(slope), ViInt32(triggerCoupling),
          ViReal64(holdoff), ViReal64(delay)),
         'Window':
         lambda triggerSource='0', lowLevel=0, highLevel=0.1, windowMode=
         TRIGGER_WINDOW.ENTERING_WINDOW, triggerCoupling=COUPLING.DC,
         holdoff=0, delay=0:
         (ViConstString(triggerSource), ViReal64(lowLevel),
          ViReal64(highLevel), ViInt32(windowMode), ViInt32(
              triggerCoupling), ViReal64(holdoff), ViReal64(delay)),
         'Software':
         lambda holdoff=0, delay=0: (ViReal64(holdoff), ViReal64(delay)),
         'Immediate':
         lambda: (),
         'Digital':
         lambda triggerSource='0', slope=SLOPE.POSITIVE, holdoff=0, delay=0:
         (ViConstString(triggerSource), ViInt32(slope), ViReal64(holdoff),
          ViReal64(delay)),
         'Video':
         lambda triggerSource='0', enableDCRestore=False, signalFormat=
         TV_TRIGGER_SIGNAL_FORMAT.VAL_PAL, event=TV_TRIGGER_EVENT.FIELD1,
         lineNumber=0, polarity=TV_TRIGGER_POLARITY.POSITIVE,
         triggerCoupling=COUPLING.DC, holdoff=0, delay=0:
         (ViConstString(triggerSource), ViBoolean(enableDCestore),
          ATTR_TV_TRIGGER_SIGNAL_FORMAT(signalFormat), ViInt32(event),
          ViInt32(lineNumber), ViInt32(polarity), ViInt32(triggerCoupling),
          ViReal64(holdoff), ViReal64(delay)),
     }[trigger_type](**settings)
     status = self.CALL("ConfigureTrigger" + trigger_type, self, *args)