Exemplo n.º 1
0
    def __init__(self, parameters):

        # Member variables.
        self.background = None                                              # Current estimate of the image background.
        self.image = None                                                   # The original image.
        self.iterations = parameters.iterations                             # Maximum number of cycles of peak finding, fitting and subtraction to perform.
        self.margin = PeakFinderFitter.margin                               # Size of the unanalyzed "edge" around the image.
        self.neighborhood = PeakFinder.unconverged_dist * parameters.sigma  # Radius for marking neighbors as unconverged.
        self.new_peak_radius = PeakFinder.new_peak_dist                     # Minimum allowed distance between new peaks and current peaks.
        self.parameters = parameters                                        # Keep access to the parameters object.
        self.peak_locations = None                                          # Initial peak locations, as explained below.
        self.peak_mask = None                                               # Mask for limiting peak identification to a particular AOI.
        self.sigma = parameters.sigma                                       # Peak sigma (in pixels).
        self.taken = None                                                   # Spots in the image where a peak has already been added.
        self.threshold = parameters.threshold                               # Peak minimum threshold (height, in camera units).
        self.z_value = 0.0                                                  # The starting z value to use for peak fitting.

        # Radius (in pixels) over which the maxima is maximal.
        if hasattr(parameters, "find_max_radius"):
            self.find_max_radius = float(parameters.find_max_radius)
        else:
            self.find_max_radius = 5

        #
        # This is for is you already know where your want fitting to happen, as
        # for example in a bead calibration movie and you just want to use the
        # approximate locations as inputs for fitting.
        #
        # peak_locations is a text file with the peak x, y, height and background
        # values as white spaced columns (x and y positions are in pixels as
        # determined using visualizer).
        #
        # 1.0 2.0 1000.0 100.0
        # 10.0 5.0 2000.0 200.0
        # ...
        #
        if hasattr(parameters, "peak_locations"):
            print "Using peak starting locations specified in", parameters.peak_locations

            # Only do one cycle of peak finding as we'll always return the same locations.
            if (self.iterations != 1):
                print "WARNING: setting number of iterations to 1!"
                self.iterations = 1

            # Load peak x,y locations.
            peak_locs = numpy.loadtxt(parameters.peak_locations, ndmin = 2)
            print peak_locs.shape

            # Create peak array.
            self.peak_locations = numpy.zeros((peak_locs.shape[0],
                                               util_c.getNResultsPar()))
            self.peak_locations[:,util_c.getXCenterIndex()] = peak_locs[:,1] + self.margin
            self.peak_locations[:,util_c.getYCenterIndex()] = peak_locs[:,0] + self.margin
            self.peak_locations[:,util_c.getHeightIndex()] = peak_locs[:,2]
            self.peak_locations[:,util_c.getBackgroundIndex()] = peak_locs[:,3]

            self.peak_locations[:,util_c.getXWidthIndex()] = numpy.ones(peak_locs.shape[0]) * self.sigma
            self.peak_locations[:,util_c.getYWidthIndex()] = numpy.ones(peak_locs.shape[0]) * self.sigma
Exemplo n.º 2
0
    def analyzeImage(self, new_image, save_residual=False, verbose=False):
        [image, residual] = self.newImage(new_image)

        self.peak_finder.newImage(image)
        self.peak_fitter.newImage(image)

        if save_residual:
            resid_dax = daxwriter.DaxWriter("residual.dax", residual.shape[0],
                                            residual.shape[1])

        peaks = False
        for i in range(self.iterations):
            if save_residual:
                resid_dax.addFrame(residual)

            [found_new_peaks,
             peaks] = self.peak_finder.findPeaks(residual, peaks)
            if (type(peaks) == type(numpy.array([]))):
                [peaks, residual] = self.peak_fitter.fitPeaks(peaks)

            residual = self.peak_finder.subtractBackground(residual)

            if verbose:
                if (type(peaks) == type(numpy.array([]))):
                    print " peaks:", i, found_new_peaks, peaks.shape[0]
                else:
                    print " peaks:", i, found_new_peaks, "NA"

            if not found_new_peaks:
                break

        if save_residual:
            resid_dax.addFrame(residual)
            resid_dax.close()

        if (type(peaks) == type(numpy.array([]))):
            peaks[:, util_c.getXCenterIndex()] -= float(self.margin)
            peaks[:, util_c.getYCenterIndex()] -= float(self.margin)

        return [peaks, residual]
Exemplo n.º 3
0
    def analyzeImage(self, new_image, save_residual = False, verbose = False):
        [image, residual] = self.newImage(new_image)

        self.peak_finder.newImage(image)
        self.peak_fitter.newImage(image)

        if save_residual:
            resid_dax = daxwriter.DaxWriter("residual.dax",
                                            residual.shape[0],
                                            residual.shape[1])

        peaks = False
        for i in range(self.iterations):
            if save_residual:
                resid_dax.addFrame(residual)

            [found_new_peaks, peaks] = self.peak_finder.findPeaks(residual, peaks)
            if (type(peaks) == type(numpy.array([]))):
                [peaks, residual] = self.peak_fitter.fitPeaks(peaks)

            residual = self.peak_finder.subtractBackground(residual)

            if verbose:
                if (type(peaks) == type(numpy.array([]))):
                    print " peaks:", i, found_new_peaks, peaks.shape[0]
                else:
                    print " peaks:", i, found_new_peaks, "NA"

            if not found_new_peaks:
                break

        if save_residual:
            resid_dax.addFrame(residual)
            resid_dax.close()

        if (type(peaks) == type(numpy.array([]))):
            peaks[:,util_c.getXCenterIndex()] -= float(self.margin)
            peaks[:,util_c.getYCenterIndex()] -= float(self.margin)

        return [peaks, residual]
Exemplo n.º 4
0
    def __init__(self, parameters):

        # Member variables.
        self.background = None  # Current estimate of the image background.
        self.image = None  # The original image.
        self.iterations = parameters.iterations  # Maximum number of cycles of peak finding, fitting and subtraction to perform.
        self.margin = PeakFinderFitter.margin  # Size of the unanalyzed "edge" around the image.
        self.neighborhood = PeakFinder.unconverged_dist * parameters.sigma  # Radius for marking neighbors as unconverged.
        self.new_peak_radius = PeakFinder.new_peak_dist  # Minimum allowed distance between new peaks and current peaks.
        self.parameters = parameters  # Keep access to the parameters object.
        self.peak_locations = None  # Initial peak locations, as explained below.
        self.peak_mask = None  # Mask for limiting peak identification to a particular AOI.
        self.sigma = parameters.sigma  # Peak sigma (in pixels).
        self.taken = None  # Spots in the image where a peak has already been added.
        self.threshold = parameters.threshold  # Peak minimum threshold (height, in camera units).
        self.z_value = 0.0  # The starting z value to use for peak fitting.

        # Radius (in pixels) over which the maxima is maximal.
        if hasattr(parameters, "find_max_radius"):
            self.find_max_radius = float(parameters.find_max_radius)
        else:
            self.find_max_radius = 5

        #
        # This is for is you already know where your want fitting to happen, as
        # for example in a bead calibration movie and you just want to use the
        # approximate locations as inputs for fitting.
        #
        # peak_locations is a text file with the peak x, y, height and background
        # values as white spaced columns (x and y positions are in pixels as
        # determined using visualizer).
        #
        # 1.0 2.0 1000.0 100.0
        # 10.0 5.0 2000.0 200.0
        # ...
        #
        if hasattr(parameters, "peak_locations"):
            print "Using peak starting locations specified in", parameters.peak_locations

            # Only do one cycle of peak finding as we'll always return the same locations.
            if (self.iterations != 1):
                print "WARNING: setting number of iterations to 1!"
                self.iterations = 1

            # Load peak x,y locations.
            peak_locs = numpy.loadtxt(parameters.peak_locations, ndmin=2)
            print peak_locs.shape

            # Create peak array.
            self.peak_locations = numpy.zeros(
                (peak_locs.shape[0], util_c.getNResultsPar()))
            self.peak_locations[:, util_c.getXCenterIndex(
            )] = peak_locs[:, 1] + self.margin
            self.peak_locations[:, util_c.getYCenterIndex(
            )] = peak_locs[:, 0] + self.margin
            self.peak_locations[:, util_c.getHeightIndex()] = peak_locs[:, 2]
            self.peak_locations[:, util_c.getBackgroundIndex()] = peak_locs[:,
                                                                            3]

            self.peak_locations[:, util_c.getXWidthIndex()] = numpy.ones(
                peak_locs.shape[0]) * self.sigma
            self.peak_locations[:, util_c.getYWidthIndex()] = numpy.ones(
                peak_locs.shape[0]) * self.sigma