def fcrtest(self, *args, **kwargs):
self.chain = 'fc'
self.wave = SineWaveform()
self.wave.frequency = 1e6
self.generator = RemoteObject(uri = 'agilent')
self.adc = RemoteObject(uri = 'sis33')
self.filename = None
self.waveUpdateUI()
self.adcUpdateUI()
self.update()
class MainWindow(QMainWindow):
def window(self, i = None):
if i is None:
i = int(self.ui.freqBar.value())
if type(i) is int:
return self.signals[i][str(self.ui.windowBox.currentText())]
return i[str(self.ui.windowBox.currentText())]
def __getitem__(self, what):
return self.plots[what][1]
def __init__(self, parent=None):
QMainWindow.__init__(self, parent)
self.ui = MainUI.Ui_MainWindow()
self.ui.setupUi(self)
self.modes = (("Single tone performances", SingleToneSignal, self.updateST),
("Two tones intermodulation", TwoToneSignal, self.updateTT))
self.ui.modeBox.addItems(map(lambda x: x[0], self.modes))
# chain hooks
self.blueprints = {'file': self.filePlan,
'synth': self.synthPlan,
'fc': self.fcPlan,
'adc': self.adcPlan}
self.dataFetch = {'file': self.fetchFile,
'synth': self.fetchSynth,
'fc': self.fetchFC,
'adc': self.fetchADC}
# which chain we are using
self.chain = 'none'
# ADC object
self.adc = None
# Wave object
self.wave = None
# Generator object
self.gen = None
# Signals to show
self.signals = [Signal()]
# Control Boxes settings
self.controlBoxesEnabler = {'file': (False, False, False, True),
'synth': (True, False, True, True),
'fc': (True, True, True, True),
'adc': (False, True, True, True)}
self.controlBoxesWidgets = (self.ui.fsBox, self.ui.acqBox, self.ui.wgBox, self.ui.dataBox)
self.ui.wgFSR.setValue(5.)
self.ui.wgBits.setValue(24)
self.ui.wgFs.setValue(50e6)
self.ui.wgSamples.setValue(8000)
# populate window box
windows = SignalProcessing.WindowFunction.windows.keys()
self.ui.windowBox.addItems(windows)
self.ui.windowBox.currentIndexChanged.connect(self.update) # check if..
self.ui.actionQuit.activated.connect(self.close)
self.ui.actionNew_Analysis.activated.connect(self.test)
self.ui.actionFull_Chain_rapid_test.activated.connect(self.fcrtest)
self.ui.fsGo.clicked.connect(self.update)
self.ui.freqBar.valueChanged.connect(self.updateBar)
self.ui.actionDump.activated.connect(self.dump)
# plot creation
self.plots = {}
self.order = []
self.setupGraph('time', ["&Signal Waveform", "Time [Fs*s]", "Signal"], (False, False))
self.setupGraph('freq', ["Spectral &Analysis", "Frequency [Hz]", "Signal [dB]"], (False, False))
self.setupGraph('dnl', ["&DNL", "Value", "Occurrencies"], (False, False))
self.setupGraph('inl', ["&INL", "Value", "Occurrencies"], (False, False))
self.setupGraph('hist', ["&Histograms", "Value", "Occurrencies"], (False, False))
self.setupGraph('ft1', ["Frequency response (&litude)", "Frequency [Hz]", ""], (False, False))
self.setupGraph('ft2', ["Frequency response (&quality)", "Frequency [Hz]", ""], (False, False))
# self.updateTabs()
# curves creation
self.setupCurve("time", "original", "ADC signal", Qt.blue)
self.setupCurve("time", "theoretical", "Theoretical signal", Qt.yellow)
self.setupCurve("time", "windowed", "Windowed signal", Qt.red)
self.setupCurve("freq", "original", "Amplitude", Qt.blue, QwtPlotCurve.Sticks)
self.setupCurve("dnl", "original", "DNL", Qt.blue )
self.setupCurve("inl", "original", "INL", Qt.blue)
self.setupCurve("hist", "real", "Real Histogram", Qt.blue, QwtPlotCurve.Sticks)
self.setupCurve("hist", "ideal", "Ideal Histogram", Qt.red, QwtPlotCurve.Sticks)
# self.setupCurve("ttm", "original", "Amplitude", Qt.blue, QwtPlotCurve.Sticks)
self.setupCurve("ft1", "original", "Amplitude", Qt.blue)
self.setupCurve("ft1", "first", "Amplitude [1]", Qt.blue)
self.setupCurve("ft1", "second", "Amplitude [2]", Qt.red)
self.setupCurve("ft2", "imd", "IMD", Qt.blue)
self.setupCurve("ft2", "snr", "SNR", Qt.blue)
self.setupCurve("ft2", "sinad", "SINAD", Qt.black)
self.setupCurve("ft2", "thd", "THD", Qt.red)
for i in self.order:
self.ui.tabWidget.addTab(self.plots[i][0], self.plots[i][1].tabName)
############################################################################
## Dialogs
############################################################################
def getModule(self, k):
ms = ModuleSelector(parent = self, kind = k)
ms.show()
status = ms.exec_() == QDialog.Accepted
if not status:
return None
return ms.generatePrefs()
def test(self, *args, **kwargs):
source = SourceSelector(self)
source.show()
status = source.exec_() == QDialog.Accepted
if not status:
return
# get the output
plan = source.answer()
self.blueprints[plan]()
def dump(self):
a = file('/tmp/alldump.adctest', 'w')
cPickle.dump(self.signals, a)
a.close()
a = file('/tmp/singledump.adctest', 'w')
cPickle.dump(self.signals[int(self.ui.freqBar.value())], a)
a.close()
print 'Dump'
############################################################################
## Plans
############################################################################
def waveGenerate(self, rate = None, bits = None, samples = None):
rate = float(self.ui.wgFs.value())
bits = int(self.ui.wgBits.value())
data = self.wave.generate(float(self.ui.wgFs.value()),
int(self.ui.wgSamples.value()),
int(self.ui.wgBits.value()),
float(self.ui.wgFSR.value()))
return bits, rate, data
def waveUpdateUI(self):
self.ui.fsStart.setValue(self.wave.get('frequency'))
self.ui.fsEnd.setValue(self.wave.get('frequency'))
self.ui.fsSteps.setValue(1)
def adcUpdateUI(self):
temp = self.adc.get('clockFrequencies')
cfs = [str(i) for i in temp]
self.ui.adcFs.clear()
self.ui.adcFs.addItems(cfs)
self.ui.adcFs.setCurrentIndex(temp.index(self.adc.get('clockFrequency')))
self.ui.adcSamples.setValue(2**14)
def adcAcquire(self):
rate = float(self.ui.adcFs.currentText())
bits = self.adc.get('nrBits')
samples = int(self.ui.adcSamples.value())
data = self.adc.readEvent(samples)
return bits, rate, data
def fcCreateList(self):
start = float(self.ui.fsStart.value())
end = float(self.ui.fsEnd.value())
steps = int(self.ui.fsSteps.value())
if steps == 1:
return [start]
s = (end - start)/(float(steps) -1)
return [start + i*s for i in xrange(steps)]
def filePlan(self):
fileName = str(QFileDialog.getOpenFileName(self, caption = "Open file", filter = "*.adc"))
if fileName == "":
return
self.chain = 'file'
self.wave = None
self.generator = None
self.adc = None
self.filename = fileName
#print "Opening", fileName, len(fileName)
#self.signal = [self.modes[self.mode][1](*readFile(fileName))]
self.update()
def synthPlan(self):
wave = self.getModule('waveforms')
if wave is None:
return
self.chain = 'synth'
self.wave = wave[0](**wave[1])
self.generator = None
self.adc = None
self.filename = None
self.waveUpdateUI()
self.update()
def fcPlan(self):
wave = self.getModule('waveforms')
if wave is None:
return
generator = self.getModule('generators')
if generator is None:
return
adc = self.getModule('adcs')
if adc is None:
return
self.chain = 'fc'
self.wave = wave[0](**wave[1])
self.generator = generator[0](**generator[1])
self.adc = adc[0](**adc[1])
self.filename = None
self.waveUpdateUI()
self.adcUpdateUI()
self.update()
def adcPlan(self):
adc = self.getModule('adcs')
if adc is None:
return
self.chain = 'adc'
self.wave = None
self.generator = None
self.adc = adc[0](**adc[1])
self.filename = None
self.adcUpdateUI()
self.update()
def fcrtest(self, *args, **kwargs):
self.chain = 'fc'
self.wave = SineWaveform()
self.wave.frequency = 1e6
self.generator = RemoteObject(uri = 'agilent')
self.adc = RemoteObject(uri = 'sis33')
self.filename = None
self.waveUpdateUI()
self.adcUpdateUI()
self.update()
def update(self, *args, **kwargs):
print 'Fetching data:', self.chain
bits, rate, data = self.dataFetch[self.chain]()
print 'Data fetch complete, elaboration is beginning'
print self.wave.getType()
if self.chain in ('adc', 'file'):
self.decision = self.modes[self.ui.modeBox.currentIndex()][1]
else:
if self.wave.getType() == SineWaveform:
self.decision = SingleToneSignal
else:
self.decision = TwoToneSignal
self.signals = [self.decision(bits, rate, i) for i in data]
if len(data) > 1:
avgItems = self.signals[0].items()
d = array(map(lambda x: x[2], avgItems))
for s in self.signals[1:]:
d += array(map(lambda x: x[2], s.items()))
d = d/float(len(self.signals))
for j in xrange(len(d)):
avgItems[j] = ('Avg. ' + avgItems[j][0], avgItems[j][1], d[j])
if self.decision == SingleToneSignal:
avgItems2 = self.signals[0][None].items()
d = array(map(lambda x: x[2], avgItems2))
for s in self.signals[1:]:
d += array(map(lambda x: x[2], s[None].items()))
d = d/float(len(self.signals))
for j in xrange(len(d)):
avgItems2[j] = ('Avg. ' + avgItems2[j][0], avgItems2[j][1], d[j])
else:
avgItems2 = []
self.ui.avgList.clear()
self.avgItems = [QTreeWidgetItem([i[0], i[1] % i[2]]) for i in (avgItems + avgItems2)]
self.ui.avgList.addTopLevelItems(self.avgItems[:])
self.ui.avgList.show()
self.ui.freqBar.show()
else:
self.ui.avgList.hide()
self.ui.freqBar.hide()
self.ui.freqBar.blockSignals(True)
self.ui.freqBar.setMinimum(0)
self.ui.freqBar.setMaximum(len(data) -1)
self.ui.freqBar.setValue(0)
self.ui.freqBar.blockSignals(False)
self.updatePlots()
def updatePlots(self, *args, **kwargs):
if self.decision == SingleToneSignal:
self.updateST()
else:
self.updateTT()
def fetchFile(self):
return readFile(self.fileName)
def fetchSynth(self):
self.frequencies = frequencies = self.fcCreateList()
print frequencies
output = []
for i in frequencies:
print i
self.wave.frequency = i
bits, rate, data = self.waveGenerate()
output.append(data)
print data
return bits, rate, output
def fetchFC(self):
# if the generator cannot directly support this
playable = self.generator.adaptKeys()
if type(self.wave) not in playable:
fsr = float(self.ui.wgFSR.value())
bits = self.adc.get('nrBits')
data, f = self.wave.generatePeriod(bits, 1000, fsr)
self.generator.set('frequency', f)
self.generator.play(data)
def play():
data, f = self.wave.generatePeriod(bits, 1000, fsr)
self.generator.set('frequency', f)
else:
def play():
self.generator.play(self.wave)
# play the wave
self.frequencies = frequencies = self.fcCreateList()
output = []
for i in frequencies:
self.wave.frequency = i
play()
time.sleep(0.5)
bits, rate, wave = self.adcAcquire()
output.append(wave)
return bits, rate, output
def fetchADC(self):
bits, rate, wave = self.adcAcquire()
return bits, rate, (wave, )
############################################################################
## GUI setup
############################################################################
def updateBar(self, *args, **kwargs):
bar = self.ui.freqBar
label = self.ui.freqLabel
i = int(bar.value())
label.setText("%g Hz" % self.frequencies[i])
self.updatePlots()
def updateTabs(self):
self.ui.tabWidget.clear()
for i in zip(self.tabs[self.mode], self.order):
if i[0]:
self.ui.tabWidget.addTab(self.plots[i[1]][0], self.plots[i[1]][1].tabName)
def updateControlBoxes(self):
for (en, cb) in zip(self.controlBoxesEnabler[self.mode], self.controlBoxesWidgets):
cb.setEnabled(en)
def setupCurve(self, name, cname, title, pencolor = Qt.blue, cs = QwtPlotCurve.Lines):
plot = self[name]
curve = QwtPlotCurve(title)
plot.curves[cname] = curve
curve.setStyle(cs)
curve.setRenderHint(QwtPlotItem.RenderAntialiased)
curve.setPen(QPen(pencolor))
curve.setYAxis(QwtPlot.yLeft)
curve.attach(plot)
def setupGraph(self, name, title, isLog):
w = QWidget()
graph = QwtPlot(w)
graph.curves = {}
graph.tabName = title[0][:]
title[0] = title[0].replace("&", "")
w.myLayout = QVBoxLayout()
w.myLayout.addWidget(graph)
w.setLayout(w.myLayout)
self.plots[name] = (w, graph)
self.order.append(name)
graph.grid = QwtPlotGrid()
graph.grid.enableXMin(True)
graph.grid.enableYMin(True)
graph.grid.enableX(True)
graph.grid.enableY(True)
graph.grid.setMajPen(QPen(Qt.black, 0, Qt.DotLine))
graph.grid.setMinPen(QPen(Qt.gray, 0 , Qt.DotLine))
graph.setTitle(title[0])
graph.legend = QwtLegend()
graph.legend.setFrameStyle(QFrame.Box | QFrame.Sunken)
graph.legend.setItemMode(QwtLegend.ClickableItem)
graph.insertLegend(graph.legend, QwtPlot.BottomLegend)
graph.setAxisTitle(QwtPlot.xBottom, title[1])
graph.setAxisTitle(QwtPlot.yLeft, title[2])
if isLog[0]:
graph.setAxisScaleEngine(QwtPlot.xBottom, QwtLog10ScaleEngine())
else:
graph.setAxisScaleEngine(QwtPlot.xBottom, QwtLinearScaleEngine())
if isLog[1]:
graph.setAxisScaleEngine(QwtPlot.yLeft, QwtLog10ScaleEngine())
else:
graph.setAxisScaleEngine(QwtPlot.yLeft, QwtLinearScaleEngine())
graph.grid.attach(graph)
graph.zoomers = []
if True:
zoomer = QwtPlotZoomer(
QwtPlot.xBottom,
QwtPlot.yLeft,
QwtPicker.DragSelection,
QwtPicker.AlwaysOff,
graph.canvas())
zoomer.setRubberBandPen(QPen(Qt.green))
graph.zoomers.append(zoomer)
zoomer = QwtPlotZoomer(
QwtPlot.xTop,
QwtPlot.yRight,
QwtPicker.PointSelection | QwtPicker.DragSelection,
QwtPicker.AlwaysOff,
graph.canvas())
zoomer.setRubberBand(QwtPicker.NoRubberBand)
graph.zoomers.append(zoomer)
graph.picker = QwtPlotPicker(
QwtPlot.xBottom,
QwtPlot.yLeft,
QwtPicker.PointSelection | QwtPicker.DragSelection,
QwtPlotPicker.CrossRubberBand,
QwtPicker.AlwaysOn,
graph.canvas())
graph.picker.setRubberBandPen(QPen(Qt.black))
graph.picker.setTrackerPen(QPen(Qt.black))
############################################################################
## Load data
############################################################################
def fetchTD(self):
i = int(self.ui.freqBar.value())
enabled = self.signals[i].nsamples != 0
return enabled, self.signals[i].data, self.window().data, self.window().th
def fetchFFT(self):
i = int(self.ui.freqBar.value())
enabled = self.signals[i].nsamples != 0
data = self.window()
if enabled:
peaks = list(data.logHarmonicPeaksGenerator(2, 2 + self.ui.peaksBox.value()))
else:
peaks = []
return enabled, data, peaks
def fetchHist(self):
i = int(self.ui.freqBar.value())
enabled = self.signals[i].nsamples != 0
# ?
return enabled, self.realHistogram, self.idealHistogram, self.DNL, self.maxDNL, self.INL, self.maxINL
def redrawPlotsST(self, *args, **kwargs):
i = int(self.ui.freqBar.value())
x = self.signals[i].nsamples
timeRange = arange(x)
self['time'].curves['original'].setData(timeRange, self.signals[i].data)
self['time'].curves['windowed'].setData(timeRange, self.window().data)
self['time'].curves['theoretical'].setData(timeRange, self.window().th)
self['time'].curves['windowed'].show()
self['time'].curves['theoretical'].show()
self['time'].replot()
freqRange = arange(x/2)
self['freq'].curves['original'].setData(freqRange, self.window().ldft[:x/2])
self['freq'].replot()
hRange = arange(len(self.signals[i].DNL))
self['dnl'].curves['original'].setData(hRange, self.signals[i].DNL)
self['dnl'].curves['original'].show()
self['dnl'].replot()
self['inl'].curves['original'].setData(hRange, self.signals[i].INL)
self['inl'].curves['original'].show()
self['inl'].replot()
hRange = arange(len(self.signals[i].realHistogram))
self['hist'].curves['real'].setData(hRange, self.signals[i].realHistogram)
self['hist'].replot()
self['hist'].curves['ideal'].setData(hRange, self.signals[i].idealHistogram)
self['hist'].replot()
m = len(self.signals)
if m == 1:
for c in self['ft1'].curves.values():
c.hide()
for c in self['ft2'].curves.values():
c.hide()
else:
f = array(self.frequencies)
amp = array([i.amplitude for i in self.signals])
snr = array([self.window(i).SNR for i in self.signals])
sinad = array([self.window(i).SINAD for i in self.signals])
thd = array([self.window(i).THD for i in self.signals])
self['ft1'].curves['original'].setData(f, amp)
self['ft1'].curves['original'].show()
self['ft1'].curves['first'].hide()
self['ft1'].curves['second'].hide()
self['ft2'].curves['snr'].setData(f, snr)
self['ft2'].curves['sinad'].setData(f, sinad)
self['ft2'].curves['thd'].setData(f, thd)
self['ft2'].curves['snr'].show()
self['ft2'].curves['sinad'].show()
self['ft2'].curves['thd'].show()
self['ft2'].curves['imd'].hide()
self['ft1'].replot()
self['ft2'].replot()
def redrawPlotsTT(self, *args, **kwargs):
i = int(self.ui.freqBar.value())
x = self.signals[i].nsamples
timeRange = arange(x)
self['time'].curves['original'].setData(timeRange, self.signals[i].data)
self['time'].curves['windowed'].hide()
self['time'].curves['theoretical'].hide()
self['time'].replot()
freqRange = arange(x/2)
self['freq'].curves['original'].setData(freqRange, self.signals[i].lfft[:x/2])
self['freq'].replot()
# hide stuff
self['dnl'].curves['original'].hide()
self['hist'].replot()
self['inl'].curves['original'].hide()
self['hist'].replot()
m = len(self.signals)
if m == 1:
for c in self['ft1'].curves.values():
c.hide()
for c in self['ft2'].curves.values():
c.hide()
else:
f = array(self.frequencies)
amp1 = array([i.amplitude1 for i in self.signals])
amp2 = array([i.amplitude2 for i in self.signals])
imd = array([i.imd for i in self.signals])
self['ft1'].curves['first'].setData(f, amp1)
self['ft1'].curves['second'].setData(f, amp2)
self['ft1'].curves['original'].hide()
self['ft1'].curves['first'].show()
self['ft1'].curves['second'].show()
self['ft2'].curves['imd'].setData(f, imd)
self['ft2'].curves['snr'].hide()
self['ft2'].curves['sinad'].hide()
self['ft2'].curves['thd'].hide()
self['ft2'].curves['imd'].show()
self['ft1'].replot()
self['ft2'].replot()
############################################################################
## Various
############################################################################
def updateST(self, *args, **kwargs):
I = int(self.ui.freqBar.value())
self.ui.propertiesList.clear()
if self.signals[I].nsamples > 0:
peaks = list(self.window().logHarmonicPeaksGenerator(2, 2 + self.ui.peaksBox.value()))
items = [QTreeWidgetItem([i[0], i[1] % i[2]]) for i in self.signals[I].items()]
self.ui.propertiesList.addTopLevelItems(items)
items = [QTreeWidgetItem([i[0], i[1] % i[2]]) for i in self.window().items()]
self.ui.propertiesList.addTopLevelItems(items)
for x in xrange(len(peaks)):
self.ui.propertiesList.addTopLevelItem(QTreeWidgetItem(["Harmonic no. %d" % (x +2), "%.6f dB" % peaks[x][2]]))
self.redrawPlotsST()
def updateTT(self, *args, **kwargs):
I = int(self.ui.freqBar.value())
self.ui.propertiesList.clear()
if self.signals[I].nsamples > 0 :
items = [QTreeWidgetItem([i[0], i[1] % i[2]]) for i in self.signals[I].items()]
self.ui.propertiesList.addTopLevelItems(items)
self.redrawPlotsTT()
############################################################################
## Open file
############################################################################
def slotOpenfile(self):
fileName = str(QFileDialog.getOpenFileName(self, caption = "Open file", filter = "*.txt"))
if fileName != "":
self.loadSignal(fileName)
def loadSignal(self, fileName):
print "Opening", fileName, len(fileName)
self.signal = self.modes[self.mode][1](*readFile(fileName))
self.update()
