Ejemplo n.º 1
0
def OnCycleStart():
    print "Back to start."
    print "Cube 2."
    microscope.MoveCubeToPosition(2)
    microscope.WaitForCube(0.0, 10.0)
    microscope.VisitPoints()
    print "Cube 3."
    microscope.MoveCubeToPosition(3)
    microscope.WaitForCube(0.0, 10.0)
    microscope.VisitPoints()
Ejemplo n.º 2
0
def OnNewPoint(x, y, z, position):
    microscope.MoveOpticalPathToPosition(2)
    microscope.MoveCubeToPosition(1)
    microscope.WaitForCube(0.0, 10.0)
    #    print "Moving Stage ", (x, y, z)
    microscope.SetStagePosition(x, y, z)
    # wait for stage to finish moving (additional delay=0.1 seconds, time out = 1.0 seconds)
    microscope.WaitForStage(0.0, 1.0)
    filename = microscope.ParseSequenceFilename(output[1], position)
    path = output[0] + filename
    print "Performing AutoFocus"
    #microscope.PerformSoftwareAutoFocus(path)
    #microscope.SnapAndSaveImage(path)
    microscope.MoveOpticalPathToPosition(4)
    microscope.MoveCubeToPosition(2)
    microscope.WaitForCube(0.0, 10.0)
    print "Performing SPC"
    microscope.StartSPC(path)
def OnNewPoint(x, y, z, position):

    global core
    global output
    global cube_data
    
    output_directory = output[0]
    filename = output[1]
    filename_ext = output[2]
    
    # Move to first cube to perform autofocus.
    microscope.MoveCubeToPosition(1)
        
    # AutoFocus Once for each new point (centre point)
    print "Performing AutoFocus"
    microscope.PerformSoftwareAutoFocus()
     
    for cube in cubes:
    
        if aborted:
            return;
            
        print "Setting camera exposure to ", exposures[cube - 1]
        microscope.SetExposure(exposures[cube - 1])
        print "Setting camera gain to ", gains[cube - 1]
        microscope.SetGain(gains[cube - 1])
    
        cube_details = cube_data[cube - 1]
        
        print "Moving to cube position ", cube
        microscope.MoveCubeToPosition(cube)
          
        print "Moving to (%d,%d)" % (x, y)
        # Apply focus offset
        microscope.SetStagePosition(x, y, z + focus_offsets[cube - 1])

        # Wait for stage to finish moving (additional delay=0.1 seconds, time out = 1.0 seconds)
        microscope.WaitForStage(0.0, 5.0)
    
        filepath = '%s\\%s_Core%d_%s%s' % (output_directory, filename, core, cube_details["Name"], filename_ext)
        print "Saving file: ", filepath
        microscope.SnapAndSaveImage(filepath) 
        
    core = core + 1
def OnNewPoint(x, y, z, position):
    global aborted, spc

    print "Point: ", position

    if aborted:
        break

    print "Set Fluorescence Mode"
    microscope.MicroscopeSetMode(0)

    for cube in cube_data:

        print "Selecting Cube ", cube['Position'], ": ", cube['Name']
        microscope.MoveCubeToPosition(cube['Position'])

        options = microscope.GetCubeOptions(
            cube['Position'])  # camera exposure, gain and focus offset
        print "Setting camera exposure to ", options[0]
        microscope.SetExposure(options[0])
        print "Setting camera gain to ", options[1]
        microscope.SetGain(options[1])

        # store the focus offset
        offset = options[2]

        if aborted:
            break

        print "Moving to (%0.1f, %0.1f, %0.1f)" % (x, y, z + offset)
        microscope.SetStagePosition(x, y, z + offset)

        # Wait for stage to finish moving (additional delay seconds, time out seconds)
        microscope.WaitForStage(0.0, 1.0)

        output_directory = output[0]
        filename = output[1]

        filename = microscope.ParseSequenceFilename(filename, position)
        filename = microscope.InsertCubeIntoFilename(filename,
                                                     cube['Position'])
        path = output_directory + filename
        print "Acquire with FL cube: ", path
        microscope.SnapAndSaveImage(path)

    if aborted:
        pass

    print "Set Laser Scanning Mode"
    microscope.MicroscopeSetMode(2)  # Laser Scanning
    spc.ClearBoardMemory()
    filename = microscope.ParseSequenceFilename(output[1], position)
    filename = microscope.InsertTextIntoFilename(filename, "spc")
    path = output[0] + filename
    print "Acquire with SPC: ", path
    spc.AcquireAndSaveToFileUsingUIValues(1, path)
def OnNewPoint(x, y, z, position):
    global cubes

    for cube in cubes:
        print "Snapping Image ", (x, y)
        pos = cube['Position']
        print "Moving cube to position: ", pos, "\n"
        microscope.MoveCubeToPosition(pos)
        time.sleep(3)
        microscope.SnapImage()
def OnCycleStart():
    global current_cube_index
    current_cube_index = 0

    for cube in cubes:
        print "Moving to cube position ", cube
        microscope.MoveCubeToPosition(cube)
        print "Setting camera exposure to ", exposures[current_cube_index]
        microscope.SetExposure(exposures[current_cube_index])
        microscope.VisitPoints()
        current_cube_index = current_cube_index + 1
def OnNewPoint(x, y, z, position):

    global core

    # Move to first cube to perform autofocus.
    microscope.MoveCubeToPosition(1)
    SetExposureAndGain(0)

    # AutoFocus Once for each new point (centre point)
    #print "Performing AutoFocus"
    #microscope.PerformSoftwareAutoFocus()

    DoRegionScan(x, y, z, position)

    core = core + 1
def DoRegionScan(x, y, z, position):
    global aborted
    global output
    global cube_data
    global action

    if aborted:
        return

    rs_points = []

    rs_points.append((x - xoffset, y - yoffset))
    rs_points.append((x, y - yoffset))
    rs_points.append((x + xoffset, y - yoffset))
    rs_points.append((x + xoffset, y))
    rs_points.append((x, y))
    rs_points.append((x - xoffset, y))
    rs_points.append((x - xoffset, y + yoffset))
    rs_points.append((x, y + yoffset))
    rs_points.append((x + xoffset, y + yoffset))

    rs_point_count = 1
    # Loop region scan points
    for rs_point in rs_points:

        if aborted:
            return

        for cube in cubes:

            if aborted:
                return

            microscope.MoveCubeToPosition(cube)
            SetExposureAndGain(cube - 1)

            if cube == 1:
                Move(rs_point[0], rs_point[1], z, cube - 1)

                # We are on the first cube so we do an autofocus
                print "Performing AutoFocus"
                microscope.PerformSoftwareAutoFocus()

            SnapAndSave(cube - 1, rs_point_count)

        rs_point_count = rs_point_count + 1
Ejemplo n.º 9
0
def OnCycleStart():
    global current_cube_index, camera_acq
    current_cube_index = 0

    print "Fluorescence Mode"
    microscope.MicroscopeSetMode(0)  # FLuorescence
    camera_acq = 1  # do the widefield camera images now
    for cube in cubes:
        print "Moving to cube position ", cube
        microscope.MoveCubeToPosition(cube)
        print "Setting camera exposure to ", exposures[current_cube_index]
        microscope.SetExposure(exposures[current_cube_index])
        microscope.VisitPoints()
        current_cube_index = current_cube_index + 1

    print "Laser Scanning Mode"
    camera_acq = 0  # do the flim images now
    microscope.MicroscopeSetMode(2)  # Laser Scanning
    microscope.VisitPoints()
Ejemplo n.º 10
0
def OnCycleStart():
    global cube_data, cube, aborted, offset

    for cube in cube_data:

        if aborted:
            break

        print "Selecting Cube ", cube['Position'], ": ", cube['Name']
        microscope.MoveCubeToPosition(cube['Position'])

        options = microscope.GetCubeOptions(
            cube['Position'])  # camera exposure, gain and focus offset
        print "Setting camera exposure to ", options[0]
        microscope.SetExposure(options[0])
        print "Setting camera gain to ", options[1]
        microscope.SetGain(options[1])

        # store the focus offset
        offset = options[2]

        microscope.VisitPoints()
Ejemplo n.º 11
0
def OnNewPoint(x, y, z, position):
    global aborted, cube_data

    print "Point: ", position

    if aborted:
        pass

    output_directory = output[0]
    filename_ext = output[2]
    subdir = '%sRegion%d\\' % (
        output_directory, position
    )  # all cubes in one folder for Mosaic to make a composite RGB mosaic
    #subdir = '%s\\Region%d_%s\\' % (output_directory, position, time.strftime("%d%b%Y_%Hh%Mm%Ss", time.localtime(time.time())))  # use this to time stamp each region mosaic

    try:
        os.makedirs(subdir)
    except (OSError):
        print 'os.makedirs(' + subdir + ') FAILED - folder may exist already.'

    for cube in cube_data:

        if aborted:
            break

        print "Moving to region centre (%d,%d)" % (x, y)
        microscope.SetStagePosition(
            x, y, z)  # no need to apply z offset here, use it below

        # Wait for stage to finish moving (additional delay seconds, time out seconds)
        microscope.WaitForStage(0.0, 1.0)

        print "Selecting Cube ", cube['Position'], ": ", cube['Name']
        microscope.MoveCubeToPosition(cube['Position'])

        options = microscope.GetCubeOptions(
            cube['Position'])  # camera exposure, gain and focus offset
        print "Setting camera exposure to ", options[0]
        microscope.SetExposure(options[0])
        print "Setting camera gain to ", options[1]
        microscope.SetGain(options[1])

        #filename = output[1]
        #filename = microscope.InsertCubeIntoFilename(filename, cube['Position']) # do not use this here as filename from the simple select dialog does not have an extension, safer is the following
        filename = output[1] + "_" + cube['Name']
        print filename

        # individual folders for cubes
        #subdir = '%sCube%d\\Region%d\\' % (output_directory, cube['Position'], position)
        #try:
        #    os.makedirs(subdir)
        #except (OSError):
        #    print 'os.makedirs(' + subdir + ') FAILED'

        # get the focal plane options for this region and transfer to the region scan module
        print "Offset focal plane by ", options[2]
        rs.SetFocalPlaneOptions(microscope.GetFocalPlaneOptions()
                                )  # timelapse based focal plane/options
        rs.SetFocalPlaneOffset(options[2])  # cube based offset

        # Set region scan with the region width and height
        print "Scanning Region"
        rs.SetRelativeRoiFromTimelapse(microscope.GetTimeLapseRegion())
        rs.Start(action, subdir, filename, filename_ext)
        rs.Hide()