.. DO NOT EDIT. .. THIS FILE WAS AUTOMATICALLY GENERATED BY SPHINX-GALLERY. .. TO MAKE CHANGES, EDIT THE SOURCE PYTHON FILE: .. "11_demos\itom\basics\demo_measurement.py" .. LINE NUMBERS ARE GIVEN BELOW. .. only:: html .. note:: :class: sphx-glr-download-link-note Click :ref:`here ` to download the full example code .. rst-class:: sphx-glr-example-title .. _sphx_glr_11_demos_itom_basics_demo_measurement.py: Measurement ============ This example shows how a typical measurement automation can be realized in ``itom``. Let's say a laser beam is detected by a camera. Different positions are to be approached with a actuator stage and camera images are to be recorded. Afterwards the centroid position distribution of the beam is evaluated. Finally the result is plotted in three different ways using the ``itom.plot1``, ``matplotlib`` and ``plotly`` plot engine. .. GENERATED FROM PYTHON SOURCE LINES 12-26 .. code-block:: default from itom import actuator from itom import dataIO from itom import dataObject from itom import algorithms from itom import plot1 from itom import plot2 from itom import ui from itomUi import ItomUi import numpy as np import matplotlib.pyplot as plt import plotly.express as px .. GENERATED FROM PYTHON SOURCE LINES 28-39 This is the main measurement class consisting of following methods: * **__init__** : Constructor of the class which opens the ``MeasureGUI``, connects to a camera ``DummyGrabber``, connects to a actuator stage ``DummyMotor``. * **on_pushButtonStart_clicked** : Start measurement methods which is connected to the signal ``clicked`` of the button ``pushButtonStart`` of the GUI. * **measurementRoutine** : Measurement routine which moves the actuator ``DummyMotor`` to the given positions, captures the camera ``DummyGrabber`` images and evaluates the centroid distribution. Afterwards the live image of the camera is activated again. .. GENERATED FROM PYTHON SOURCE LINES 39-219 .. code-block:: default class MeasureDemoGUI(ItomUi): def __init__(self): """Constructor method of the MeasureDemoGUI class.""" # init the gui ItomUi.__init__(self, "MeasureGUI.ui", ui.TYPEWINDOW, deleteOnClose=True) # init cam and mot self.cam = dataIO("DummyGrabber", imageType="gaussianSpot") self.mot = actuator("DummyMotor", numAxis=1) self.mot.setParam("speed", 1000) # define widget values self.gui.spinBoxNumZSteps["value"] = 100 self.gui.doubleRangeWidgetZRange["minimum"] = 0.0 self.gui.doubleRangeWidgetZRange["maximum"] = 1000.0 self.gui.doubleRangeWidgetZRange["minimumValue"] = 10.0 self.gui.doubleRangeWidgetZRange["maximumValue"] = 555.0 # show liveimage self.cam.startDevice() self.gui.camPlot["camera"] = self.cam self.gui.camPlot["colorMap"] = "OSIRainbow" self.gui.camPlot["keepAspectRatio"] = True # access motor controller self.gui.MotorAxisController["actuator"] = self.mot self.gui.MotorAxisController["numAxis"] = 1 self.gui.MotorAxisController["defaultAxisType"] = "TypeLinear" # connect # self.gui.pushButtonStart.connect("clicked()", self.startMeasure) # define measure data object self.imageStack = None self.centroidData = None # connect stop button to interrupt self.gui.pushButtonStop.invokeKeyboardInterrupt("clicked()") # show the gui self.gui.show() self.gui.call("statusBar").call("showMessage", "Initialization finished.", 5000) return @ItomUi.autoslot("") def on_pushButtonStart_clicked(self): """Function trigger by pushButtonStart""" self.gui.call("statusBar").call("showMessage", "Start Measurement", 5000) with self.disableGui([self.gui.pushButtonStart], showWaitCursor=False): minVal = self.gui.doubleRangeWidgetZRange["minimumValue"] maxVal = self.gui.doubleRangeWidgetZRange["maximumValue"] steps = self.gui.spinBoxNumZSteps["value"] self.measurementRoutine(minVal, maxVal, steps) self.gui.call("statusBar").call("showMessage", "Stop Measurement", 5000) return def measurementRoutine(self, zMin: float, zMax: float, numZSteps: int): """Measurement routine along input z range Args: zMin (float): Minimum z position zMax (float): Maximum z position numZSteps (int): Number of z positions """ # Create z positions vector zVec = np.linspace(zMin, zMax, num=numZSteps) # disable camera auto grabbing self.cam.disableAutoGrabbing() # define measurement data object bpp = self.cam.getParam("bpp") if bpp == 8: dtype = "uint8" else: dtype = "uint16" self.imageStack = dataObject([len(zVec), self.cam.getParam("sizey"), self.cam.getParam("sizex")], dtype) self.centroidData = dataObject([2, len(zVec)], "float32") # centroidMarker dObj centroidMarker = dataObject([2, 1], "float32") # loop for all z positions for idx, z in enumerate(zVec): self.gui.call("statusBar").call("showMessage", "z measurement posotion {}".format(z), 5000) # goto new motor position self.mot.setPosAbs(0, z) # acquire image d = dataObject() self.cam.acquire() self.cam.copyVal(d) # eval the centroid cYI, cXI, cY, cX = algorithms.centroidXY(d) # add to data stack self.imageStack[idx, :, :] = d self.centroidData[0, idx] = cX self.centroidData[1, idx] = cY # plot current image and centroid self.gui.camPlot["source"] = d centroidMarker[0, 0] = cX centroidMarker[1, 0] = cY self.gui.camPlot.call("deleteMarkers") self.gui.camPlot.call("plotMarkers", centroidMarker, "w+25;2", "centroid", 0) self.gui.progressBar["value"] = idx / (len(zVec) - 1) * 100 self.cam.enableAutoGrabbing() self.gui.camPlot.call("deleteMarkers") self.gui.camPlot["camera"] = self.cam # define imageStack self.imageStack.setAxisDescription(0, "z axis of actuator") self.imageStack.setAxisDescription(1, "y axis") self.imageStack.setAxisDescription(2, "x axis") self.imageStack.setAxisUnit(0, "mm") self.imageStack.setAxisUnit(1, "\xb5m") self.imageStack.setAxisUnit(2, "\xb5m") # calc meta info zScale = (zMax - zMin) / (numZSteps - 1) zOffset = -(zVec[0] / zScale) self.imageStack.setAxisScale(0, zScale) self.imageStack.setAxisOffset(0, zOffset) self.imageStack.setAxisScale(1, 17e-3) # pixel pitch of 17 \xb5m self.imageStack.setAxisScale(2, 17e-3) # pixel pitch of 17 \xb5m self.imageStack.valueDescription = "intensity" self.imageStack.valueUnit = "counts" # plot imagestack plot2(self.imageStack) self.centroidData.setAxisScale(1, zScale) self.centroidData.setAxisOffset(1, zOffset) self.centroidData.valueDescription = "centroid position" self.centroidData.valueUnit = "mm" self.centroidData.setTag("legendTitle0", "x centroid") self.centroidData.setTag("legendTitle1", "y centroid") # plot x, y as lines plot1(self.centroidData, properties={"legendPosition": "Right", "grid": "GridMajorXY"}) # plot y vs. x yData = self.centroidData[0, :].squeeze() xData = self.centroidData[1, :].squeeze() yData.valueDescription = "y centroid position" xData.valueDescription = "x centroid position" plot1( yData, xData=xData, properties={ "keepAspectRatio": True, "grid": "GridMajorXY", "lineStyle": "NoPen", "lineSymbol": "XCross", }, ) # plot using matplotlib xData = np.squeeze(np.array(xData)) yData = np.squeeze(np.array(yData)) plt.figure() plt.scatter(xData, yData) plt.xlabel("x centroid /mm") plt.ylabel("y centroid /mm") plt.show() # plot using plotly figly = px.scatter(x=xData, y=yData, labels={"x": "x centroid /mm", "y": "y centroid /mm"}) figly.show() # ------------------------------- if __name__ == "__main__": demo = MeasureDemoGUI() .. GENERATED FROM PYTHON SOURCE LINES 220-222 .. image:: ../../_static/demoMeasurement_1.png :width: 100% .. rst-class:: sphx-glr-timing **Total running time of the script:** ( 0 minutes 0.967 seconds) .. _sphx_glr_download_11_demos_itom_basics_demo_measurement.py: .. only:: html .. container:: sphx-glr-footer sphx-glr-footer-example .. container:: sphx-glr-download sphx-glr-download-python :download:`Download Python source code: demo_measurement.py ` .. container:: sphx-glr-download sphx-glr-download-jupyter :download:`Download Jupyter notebook: demo_measurement.ipynb `