def filter(self, delta): feature = delta.get_feature() prj = feature.get_coordinate_system().get_projection(self.prj_settings) v = [k.to(self.unit).value for k in delta.get_angular_velocity_vector(prj)] x_dir = self.x_dir if x_dir == 'position_angle': x_dir = prj.p2s(p2i(feature.get_coord())) vx, vy = nputils.vector_projection(v, x_dir) dy, dx = delta.get_delta() vn = np.linalg.norm([vx, vy]) dn = np.linalg.norm([dx, dy]) res = True for v_range, value, v_pix in zip([self.vxrange, self.vyrange, self.normrange], [vx, vy, vn], [dx, dy, dn]): if np.abs(v_pix) < self.pix_limit: continue if v_range is not None and not nputils.in_range(value, v_range): res = False break logger.debug("DeltaRangeFilter: delta=%s, v=%s, vp=%s, res=%s" % (delta.get_delta(), v, [vx, vy], res)) return res
def process(self, prj, res1, res2): delta_t, velocity_pix, tol_pix = self.get_velocity_resolution( prj, res1, res2) max_bounds = max(self.bounds) if self.verbose: print "Processing:", res1.get_epoch(), res2.get_epoch( ), delta_t, velocity_pix, tol_pix if self.debug >= 2: fig, ax_check0 = self.stack.add_subplots("Segments check 1", ncols=1) fig, ax_check1 = self.stack.add_subplots("Segments check 2", ncols=1) epoch_all_mean_ncc = [] for segments1, segments2 in zip(res1, res2): if self.debug >= 2: imshow_segmented_image(ax_check0, segments1, alpha=1, projection=prj) imshow_segmented_image(ax_check1, segments2, alpha=1, projection=prj) scale = segments1.get_scale() # print "Scale %s: %s" % (scale, len(segments1)) all_ncc = [] all_ncc_shape = None for segment1 in segments1: x_dir = self.x_dir if x_dir == 'position_angle': x_dir = prj.p2s(p2i(segment1.get_coord())) elif nputils.is_callable(x_dir): x_dir = self.x_dir(prj.p2s(p2i(segment1.get_coord()))) if self.mode == 'ncc_peaks_direct': region1 = segment1.get_image_region() if min(region1.get_region().shape) <= 3: continue if self.rnd_pos_shift: shift = np.random.normal( 0, self.rnd_pos_factor * segment1.get_coord_error(min_snr=3)) region1.set_shift(shift) i1 = segments2.get_img().get_data() # i1 = nputils.shift2d(i1, np.array([4 / velocity_pix] * 2)) i1 = nputils.zoom(i1, region1.get_center(), [2 * tol_pix, 2 * tol_pix]) i2 = region1.get_region() shape = [ self.factor * (self.bounds[0] + self.bounds[1]), self.factor * (self.bounds[2] + self.bounds[3]) ] data = np.zeros(shape) # print i1.shape, i2.shape ncc = nputils.norm_xcorr2(i1, i2, mode='same') peaks = nputils.find_peaks(ncc, 4, self.ncc_threshold, fit_gaussian=False) if len(peaks) > 0: delta_pix = p2i(peaks - np.array(ncc.shape) / 2) delta = prj.pixel_scales() * np.array( delta_pix) * prj.unit v = delta / self.__get_delta_time(delta_t) if self.vel_trans: v = self.vel_trans( prj.p2s(p2i(segment1.get_coord())), v.T).T if x_dir is not None: vx, vy = nputils.vector_projection(v.T, x_dir) * v.unit else: vx, vy = v.T vx = vx.to(self.unit).value vy = vy.to(self.unit).value d = np.array([vx, vy]) if len(vx) > 0: ix = self.factor * (self.bounds[0] + vx) iy = self.factor * (self.bounds[2] + vy) widths = np.array( [[4 * self.factor * velocity_pix] * 2] * len(peaks)) # widths = np.array([[1] * 2] * len(peaks)) centers = np.array([iy, ix]).T heights = ncc[tuple( np.array([tuple(k) for k in peaks]).T)] # print widths, centers, heights data = imgutils.multiple_gaussian( shape, heights, widths, centers) ncc = data else: ncc = self.ncc_segment(segment1, segments2, 2 * tol_pix) if ncc is not None: # print ncc.shape, nputils.coord_max(ncc) ncc = zoom(ncc, velocity_pix * self.factor, order=3) # zoom will shift the center ncc = nputils.shift2d( ncc, [-(velocity_pix * self.factor) / 2.] * 2) # print ncc.shape, nputils.coord_max(ncc), velocity_pix * self.factor ncc = nputils.zoom(ncc, np.array(ncc.shape) / 2, [ 2 * max_bounds * self.factor, 2 * max_bounds * self.factor ]) # print ncc.shape, nputils.coord_max(ncc) # ncc = ncc[self.factor * (max_bounds - self.bounds[0]):self.factor * (max_bounds + self.bounds[1]), # self.factor * (max_bounds - self.bounds[2]):self.factor * (max_bounds + self.bounds[3])] # print ncc.shape if x_dir is not None: angle_rad = -np.arctan2(x_dir[1], x_dir[0]) ncc = rotate(ncc, -angle_rad / (2 * np.pi) * 360, reshape=False, order=2) if ncc is not None: if self.debug >= 3: fig, (ax0, ax1, ax2) = self.stack.add_subplots( "Segment %s" % segment1.get_segmentid(), ncols=3) r1 = segment1.get_image_region() ax0.imshow(r1.get_region()) i2 = nputils.zoom(segments2.get_img().get_data(), r1.get_center(), [2 * tol_pix, 2 * tol_pix]) ax1.imshow(i2, norm=plotutils.LogNorm(), extent=(-tol_pix, tol_pix, -tol_pix, tol_pix)) plotutils.img_axis(ax1) ax2.imshow(ncc, extent=self.global_ncc_extent) plotutils.img_axis(ax2) all_ncc.append(ncc) if all_ncc_shape is None: all_ncc_shape = ncc.shape if len(all_ncc) > 0: if scale not in self.global_ncc_scales: self.global_ncc_scales[scale] = [] self.global_ncc_scales_n[scale] = 0 mean_ncc = self.agg_fct(np.array(all_ncc), axis=0) epoch_all_mean_ncc.append(mean_ncc) if self.debug >= 1: fig, ax = self.stack.add_subplots( "Ncc epoch %s vs %s scale %s" % (res1.get_epoch(), res2.get_epoch(), scale)) ax.imshow(mean_ncc, extent=self.global_ncc_extent) plotutils.img_axis(ax) self.global_ncc_scales[scale].append(mean_ncc) self.global_ncc_scales_n[scale] += len(all_ncc) if self.debug >= 0.5 and len(epoch_all_mean_ncc) > 0: epoch_mean_ncc = self.agg_fct(np.array(epoch_all_mean_ncc), axis=0) fig, ax = self.stack.add_subplots( "Ncc epoch %s vs %s" % (res1.get_epoch(), res2.get_epoch())) ax.imshow(epoch_mean_ncc, extent=self.global_ncc_extent) plotutils.img_axis(ax)
def process(self, prj, res1, res2): delta_t, velocity_pix, tol_pix = self.get_velocity_resolution(prj, res1, res2) max_bounds = max(self.bounds) if self.verbose: print "Processing:", res1.get_epoch(), res2.get_epoch(), delta_t, velocity_pix, tol_pix if self.debug >= 2: fig, ax_check0 = self.stack.add_subplots("Segments check 1", ncols=1) fig, ax_check1 = self.stack.add_subplots("Segments check 2", ncols=1) epoch_all_mean_ncc = [] for segments1, segments2 in zip(res1, res2): if self.debug >= 2: imshow_segmented_image(ax_check0, segments1, alpha=1, projection=prj) imshow_segmented_image(ax_check1, segments2, alpha=1, projection=prj) scale = segments1.get_scale() # print "Scale %s: %s" % (scale, len(segments1)) all_ncc = [] all_ncc_shape = None for segment1 in segments1: x_dir = self.x_dir if x_dir == 'position_angle': x_dir = prj.p2s(p2i(segment1.get_coord())) elif nputils.is_callable(x_dir): x_dir = self.x_dir(prj.p2s(p2i(segment1.get_coord()))) if self.mode == 'ncc_peaks_direct': region1 = segment1.get_image_region() if min(region1.get_region().shape) <= 3: continue if self.rnd_pos_shift: shift = np.random.normal(0, self.rnd_pos_factor * segment1.get_coord_error(min_snr=3)) region1.set_shift(shift) i1 = segments2.get_img().get_data() # i1 = nputils.shift2d(i1, np.array([4 / velocity_pix] * 2)) i1 = nputils.zoom(i1, region1.get_center(), [2 * tol_pix, 2 * tol_pix]) i2 = region1.get_region() shape = [self.factor * (self.bounds[0] + self.bounds[1]), self.factor * (self.bounds[2] + self.bounds[3])] data = np.zeros(shape) # print i1.shape, i2.shape ncc = nputils.norm_xcorr2(i1, i2, mode='same') peaks = nputils.find_peaks(ncc, 4, self.ncc_threshold, fit_gaussian=False) if len(peaks) > 0: delta_pix = p2i(peaks - np.array(ncc.shape) / 2) delta = prj.pixel_scales() * np.array(delta_pix) * prj.unit v = delta / self.__get_delta_time(delta_t) if self.vel_trans: v = self.vel_trans(prj.p2s(p2i(segment1.get_coord())), v.T).T if x_dir is not None: vx, vy = nputils.vector_projection(v.T, x_dir) * v.unit else: vx, vy = v.T vx = vx.to(self.unit).value vy = vy.to(self.unit).value d = np.array([vx, vy]) if len(vx) > 0: ix = self.factor * (self.bounds[0] + vx) iy = self.factor * (self.bounds[2] + vy) widths = np.array([[4 * self.factor * velocity_pix] * 2] * len(peaks)) # widths = np.array([[1] * 2] * len(peaks)) centers = np.array([iy, ix]).T heights = ncc[tuple(np.array([tuple(k) for k in peaks]).T)] # print widths, centers, heights data = imgutils.multiple_gaussian(shape, heights, widths, centers) ncc = data else: ncc = self.ncc_segment(segment1, segments2, 2 * tol_pix) if ncc is not None: # print ncc.shape, nputils.coord_max(ncc) ncc = zoom(ncc, velocity_pix * self.factor, order=3) # zoom will shift the center ncc = nputils.shift2d(ncc, [- (velocity_pix * self.factor) / 2.] * 2) # print ncc.shape, nputils.coord_max(ncc), velocity_pix * self.factor ncc = nputils.zoom(ncc, np.array(ncc.shape) / 2, [2 * max_bounds * self.factor, 2 * max_bounds * self.factor]) # print ncc.shape, nputils.coord_max(ncc) # ncc = ncc[self.factor * (max_bounds - self.bounds[0]):self.factor * (max_bounds + self.bounds[1]), # self.factor * (max_bounds - self.bounds[2]):self.factor * (max_bounds + self.bounds[3])] # print ncc.shape if x_dir is not None: angle_rad = - np.arctan2(x_dir[1], x_dir[0]) ncc = rotate(ncc, - angle_rad / (2 * np.pi) * 360, reshape=False, order=2) if ncc is not None: if self.debug >= 3: fig, (ax0, ax1, ax2) = self.stack.add_subplots("Segment %s" % segment1.get_segmentid(), ncols=3) r1 = segment1.get_image_region() ax0.imshow(r1.get_region()) i2 = nputils.zoom(segments2.get_img().get_data(), r1.get_center(), [2 * tol_pix, 2 * tol_pix]) ax1.imshow(i2, norm=plotutils.LogNorm(), extent=(-tol_pix, tol_pix, -tol_pix, tol_pix)) plotutils.img_axis(ax1) ax2.imshow(ncc, extent=self.global_ncc_extent) plotutils.img_axis(ax2) all_ncc.append(ncc) if all_ncc_shape is None: all_ncc_shape = ncc.shape if len(all_ncc) > 0: if scale not in self.global_ncc_scales: self.global_ncc_scales[scale] = [] self.global_ncc_scales_n[scale] = 0 mean_ncc = self.agg_fct(np.array(all_ncc), axis=0) epoch_all_mean_ncc.append(mean_ncc) if self.debug >= 1: fig, ax = self.stack.add_subplots("Ncc epoch %s vs %s scale %s" % (res1.get_epoch(), res2.get_epoch(), scale)) ax.imshow(mean_ncc, extent=self.global_ncc_extent) plotutils.img_axis(ax) self.global_ncc_scales[scale].append(mean_ncc) self.global_ncc_scales_n[scale] += len(all_ncc) if self.debug >= 0.5 and len(epoch_all_mean_ncc) > 0: epoch_mean_ncc = self.agg_fct(np.array(epoch_all_mean_ncc), axis=0) fig, ax = self.stack.add_subplots("Ncc epoch %s vs %s" % (res1.get_epoch(), res2.get_epoch())) ax.imshow(epoch_mean_ncc, extent=self.global_ncc_extent) plotutils.img_axis(ax)