Beispiel #1
0
from nidaqmx.task import Task
from nidaqmx import constants
import numpy as np
from numpy import pi
import matplotlib.pylab as plt

samp_rate = 1000000
duration = 1
sample_num = 1000000
time = np.linspace(0, duration, sample_num)
freq = 1000

test_task = Task('ao_test')
test_task.ao_channels.add_ao_voltage_chan('/Dev1/ao1')
test_task.timing.cfg_samp_clk_timing(
    rate=samp_rate,
    #source = '/Dev1/ai/SampleClock', \
    samps_per_chan=sample_num,
    sample_mode=constants.AcquisitionType.CONTINUOUS)
pulse_data = np.sin(2 * pi * freq * time)
test_task.write(pulse_data)
test_task.start()

#test_task.wait_until_done()
test_task.stop()
test_task.close()
Beispiel #2
0
class MainWindow(QMainWindow):
    def __init__(self, *args, **kwargs):
        super(MainWindow, self).__init__()

        self.setWindowTitle('Dissolution DNP Measurement (NSOR project)')
        self.setWindowIcon(
            QIcon(BASE_FOLDER + r"\pyqt_analysis\icons\window_icon.png"))
        '''
        --------------------------setting menubar-------------------------------
        '''
        mainMenu = self.menuBar()  #create a menuBar
        fileMenu = mainMenu.addMenu('&File')  #add a submenu to the menu bar
        '''
        --------------------------setting toolbar-------------------------------
        '''
        self.toolbar = self.addToolBar(
            'nsor_toolbar')  #add a tool bar to the window
        self.toolbar.setIconSize(QSize(100, 100))

        self.statusBar()  #create a status bar
        '''
        --------------------------setting matplotlib----------------------------
        axes are contained in one dictionary
        ax['time']
        ax['freq']
        also initiate the vertical lines
        vline['time_l']
        vline['time_r']
        vline['freq_l']
        vline['freq_r']
        '''
        if app.desktop().screenGeometry().height() == 2160:
            matplotlib.rcParams.update({'font.size': 28})
        elif app.desktop().screenGeometry().height() == 1080:
            matplotlib.rcParams.update({'font.size': 14})
        canvas = FigureCanvas(Figure(figsize=(50, 15)))

        self.ax = {}
        self.vline = {}
        self.ax['nmr_time'] = canvas.figure.add_subplot(221)
        self.ax['nmr_freq'] = canvas.figure.add_subplot(222)
        self.ax['nsor_time'] = canvas.figure.add_subplot(223)
        self.ax['nsor_freq'] = canvas.figure.add_subplot(224)

        for axis in self.ax.values():
            if app.desktop().screenGeometry().height() == 2160:
                axis.tick_params(pad=20)
            elif app.desktop().screenGeometry().height() == 1080:
                axis.tick_params(pad=10)
        '''
        use pyqtgraph for optical detector because of the fast drawing speed
        '''
        self.optical_graph = pg.PlotWidget()
        self.optical_data = np.zeros(500)
        self.optical_data += 1
        self.optical_curve = self.optical_graph.plot(self.optical_data)
        self.optical_graph.setYRange(-0.1, 1.1)
        print(self.optical_graph.size)
        '''
        --------------------------setting widgets-------------------------------
        '''
        exitProgram = QAction(
            QIcon(BASE_FOLDER + r'\pyqt_analysis\icons\exit_program.png'),
            '&Exit', self)
        exitProgram.setShortcut("Ctrl+W")
        exitProgram.setStatusTip('Close the Program')
        exitProgram.triggered.connect(self.exit_program)
        fileMenu.addAction(exitProgram)

        editParameters = QAction('&Edit Parameter', self)
        editParameters.setShortcut('Ctrl+E')
        editParameters.setStatusTip('open and edit the parameter file')
        editParameters.triggered.connect(self.edit_parameters)

        saveParameters = QAction('&Save Parameter', self)
        saveParameters.setShortcut('Ctrl+S')
        saveParameters.setStatusTip('save the parameters on screen to file')
        saveParameters.triggered.connect(self.save_parameters)
        parameterMenu = mainMenu.addMenu('&Parameter')
        parameterMenu.addAction(editParameters)
        parameterMenu.addAction(saveParameters)

        startExpBtn = QPushButton('START', self)
        startExpBtn.clicked.connect(self.fluid_detector_read)
        calibrateBtn = QPushButton('CALIBRATE', self)
        calibrateBtn.clicked.connect(self.calibrate_fluid_detector)
        self.readyBtn = QRadioButton('READY', self)
        self.stopBtn = QPushButton('STOP', self)
        self.stopBtn.setCheckable(True)

        injBtn = QPushButton('INJECT', self)
        injBtn.clicked.connect(lambda: self.switch_mode('inject'))
        loadBtn = QPushButton('LOAD', self)
        loadBtn.clicked.connect(lambda: self.switch_mode('load'))
        '''
        --------------------------setting layout/mix widget set-----------------
        '''
        tabs = QTabWidget()
        tabs.setDocumentMode(True)
        tabs.setTabPosition(QTabWidget.North)
        tabs.setMovable(True)

        tab = {'parameter': QWidget(), 'data': QWidget()}
        tab_layout = {'parameter': QVBoxLayout(), 'data': QHBoxLayout()}
        parameter_tab_layout = QFormLayout()
        sub_tab_layout = {'time': QVBoxLayout(), 'freq': QVBoxLayout()}
        optical_layout = QHBoxLayout()
        '''
        importing edits from paramter
        '''
        self.edits = {}
        self.parameters = read_parameter(PARAMETER_FILE)
        for key, value in self.parameters.items():
            if type(value) == list:
                value = str(value[0]) + ' ' + str(value[1])
            self.edits[key] = MyLineEdit(key, value, self)
            self.edits[key].setStatusTip(f'{key}')
            if 'nmr' in key:
                key_str = 'NMR Channel'
            elif 'nsor' in key:
                key_str = 'NSOR Channel'
            else:
                key_str = key.replace('_', ' ').title()

            if not ('time' in key or 'freq' in key):
                '''
                parameter tab layout:
                file_name; pulse_file; samp_rate; iteration; average; pulse_chan;
                nmr_chan; nsor_chan; laser_chan
                '''
                layout_temp = QHBoxLayout()
                layout_temp.addWidget(self.edits[key])
                if 'file' in key:
                    self.edits[key].setFixedWidth(1250)
                else:
                    layout_temp.addStretch(1)

                parameter_tab_layout.addRow(key_str, layout_temp)

            else:
                '''
                data tab layout:
                time_x_limit; time_y_limit; freq_x_limit; freq_y_limit;
                time_cursor; freq_cursor
                '''
                sub_tab_layout[key[0:4]].addWidget(QLabel(key_str, self))
                sub_tab_layout[key[0:4]].addWidget(self.edits[key])
                if 'freq' in key:
                    self.edits[key].setFixedWidth(250)

        for key in sub_tab_layout.keys():
            sub_tab_layout[key].addStretch(1)

        tab_layout['parameter'].addLayout(parameter_tab_layout)
        tab_layout['parameter'].addLayout(optical_layout)

        button_layout = QVBoxLayout()
        button_layout.addWidget(injBtn)
        button_layout.addWidget(loadBtn)
        button_layout.addWidget(startExpBtn)
        button_layout.addWidget(self.stopBtn)
        button_layout.addWidget(calibrateBtn)
        button_layout.addWidget(self.readyBtn)

        button_layout.addStretch(1)

        optical_layout.addLayout(button_layout)
        optical_layout.addWidget(self.optical_graph)

        # tab_layout['parameter'].addStretch(1)
        tab_layout['data'].addLayout(sub_tab_layout['time'])
        tab_layout['data'].addWidget(canvas)
        tab_layout['data'].addLayout(sub_tab_layout['freq'])
        for key in tab.keys():
            tabs.addTab(tab[key], key)
            tab[key].setLayout(tab_layout[key])

        _main = QWidget()
        self.setCentralWidget(_main)
        layout1 = QVBoxLayout(_main)
        layout1.addWidget(tabs)
        '''
        --------------------------Multithreading preparation--------------------
        '''
        self.threadpool = QThreadPool()  #Multithreading
        '''
        --------------------------Daqmx Task initialization---------------------
        '''
        di_line = 'Dev1/port2/line2'
        self.di_task = Task('di_task')
        self.di_task.di_channels.add_di_chan(di_line)

        do_line = 'Dev1/port1/line0, Dev1/port1/line1, Dev1/port1/line5'
        self.do_task = Task('do_task')
        self.do_task.do_channels.add_do_chan(do_line)
        self.do_task.start()
        '''
        -------------------------Menu bar slot----------------------------------
        '''

    def edit_parameters(self):
        os.startfile(PARAMETER_FILE)

    def save_parameters(self):
        for key in self.parameters.keys():
            str = self.edits[key].text()
            if 'freq' in key or 'time' in key:
                self.parameters[key] = str.split(' ')
            else:
                self.parameters[key] = str

        save_parameter(PARAMETER_FILE, **self.parameters)

    def exit_program(self):
        choice = QMessageBox.question(
            self, 'Exiting', 'Are you sure about exit?',
            QMessageBox.Yes | QMessageBox.No)  #Set a QMessageBox when called
        if choice == QMessageBox.Yes:  # give actions when answered the question
            self.do_task.stop()
            self.di_task.stop()
            self.do_task.close()
            self.di_task.close()
            sys.exit()
        '''
        -------------------------button slots-----------------------------------
        '''

    def switch_mode(self, mode):
        worker = SwitchValveWorker(self.do_task, mode)
        self.threadpool.start(worker)
        '''
        --------------------------Multithreading slots--------------------------
        '''

    def fluid_detector_read(self):
        worker = FluidDetectorReadWorker(self.di_task, self.optical_data,
                                         self.readyBtn, self.stopBtn)
        worker.signals.detector_triggered.connect(self.collect_data)
        worker.signals.data.connect(self.update_optical_curve)
        self.threadpool.start(worker)

    def update_optical_curve(self, data):
        self.optical_curve.setData(data)

    def collect_data(self):
        if self.stopBtn.isChecked():
            self.stopBtn.toggle()
        else:
            print('collecting data')
            # injection time
            inj_time = int(self.edits['injection_delay'].text())
            worker = DataRecorderWorker(self.do_task, inj_time)
            self.threadpool.start(worker)

        # self.optical_graph.clear()

    def calibrate_fluid_detector(self):
        worker = CalibrateFluidDetectorWorker(self.do_task)
        self.threadpool.start(worker)