def fig10(template_dir, build_dir, bound_radius=0.6, selectivity_norm=0.07138, size_factor=1.0, show_raster=False): name = 'fig10' if show_raster: return Display(snapshot=name, template_dir=template_dir) times=[2000*i for i in range(6)] template_path, output_dir = setup(name, template_dir, build_dir) pattern = 'jn13_figures/output/Fig10_12/*/*/*.npz' files = lancet.FilePattern('npz_file', pattern) file_info = lancet.FileInfo(files, 'npz_file', lancet.NumpyFile()) filter_times = file_info.dframe['time'].map(lambda x: x in times) selection = file_info.load(file_info.dframe[filter_times]) savefig_opts = dict(transparent=True, format='svg', bbox_inches='tight', pad_inches=0) development_info = [] for (index, row) in selection.iterrows(): time =row['time'] fname = os.path.join(output_dir, '%%s_%.1f.png' % int(time)) bounds = imagen.boundingregion.BoundingBox(radius=0.75) sheetcoords = imagen.SheetCoordinateSystem(bounds, xdensity=98) roi = slice(*sheetcoords.sheet2matrixidx(bound_radius, bound_radius)) # Not applying ROI as new bounds will be used pref = get_pref(row, roi=roi) sel = get_sel(row, roi=roi) (cfs, coords) = row['afferent_CFs'] roi = slice(*sheetcoords.sheet2matrixidx(bound_radius, bound_radius)) # Create the combined preference/selectivity map or_map = rasterplots.OR_map(pref,sel) or_black = rasterplots.black_selectivity(or_map) (dim1,dim2) = pref.shape or_black_resized = rasterplots.resize(or_black, (dim1*4,dim2*4)) # Save the orientation map or_black_resized.save(fname % 'OR') # Save the row of CF images cf_block = rasterplots.cf_image(cfs, coords, border=5, width=8, height=1, pos=(1,4), bg=(255,255,255)) cf_block.save(fname % 'CF') # Save the FFT of the last map if time == times[-1]: normalized_spectrum = analysis.power_spectrum(pref[roi,roi]) fft_im = rasterplots.greyscale(normalized_spectrum) fft_im.save(fname % 'FFT') # Note: ROI not applied and the values of 3 are due to historical reasons development_info.append((time,pref[3:-3, 3:-3], np.mean(sel[3:-3,3:-3]))) ts, prefs, mean_sels = zip(*sorted(development_info)) # We only need the stabilities up till 10000 fname = os.path.join(output_dir, 'model_development.svg') development_fig = vectorplots.map_development_plot(analysis.stability_index(prefs), mean_sels, selectivity_norm) development_fig.savefig(fname, **savefig_opts) vectorplots.close([development_fig]) svg_path = os.path.join(output_dir, '%s.svg' % name) return Display(compose.apply_template(template_path, svg_path, size_factor=size_factor))
def OR_analysis(row, template_dir, build_dir, name='OR_analysis', selectivity=False, contours=False, cfs=True, scalebox = False, size_factor=1.0,): """ Builds a pinwheel analysis of a single orientation map from a template. Used in Figures 3 and 6-9. Displays an annotated map with pinwheels next to the FFT spectrum and corresponding fit. The selectivity channel of the map can be enabled as can pinwheel contours and a column of central connection fields. The map can have either a normal scalebar or a box showing the hypercolumn area. """ template_path, output_dir = setup('OR_analysis', template_dir, build_dir, subdir=name) savefig_opts = dict(transparent=True, format='svg', bbox_inches='tight', pad_inches=0) pref = get_pref(row) sel = get_sel(row) if selectivity else None fname = os.path.join(output_dir, '%%s_%s.%%s' % name) # Save the OR preference and selectivity raster or_map = rasterplots.OR_map(pref, sel) rasterplots.black_selectivity(or_map).save(fname % ('OR','png')) # Save the FFT raster rasterplots.greyscale(analysis.power_spectrum(pref)).save(fname % ('FFT','png')) # Save the histogram SVG overlay hist = vectorplots.FFT_histogram_overlay(row['amplitudes'], row['fit']) hist.savefig(fname % ('HIST', 'svg'), **savefig_opts) # Save the pinwheel contour SVG overlay contours = (row['re_contours'], row['im_contours']) if contours else None contour_fig = vectorplots.pinwheel_overlay(row['pinwheels'], contours=contours) contour_fig.savefig(fname % ('OVERLAY','svg'), **savefig_opts) # Save the CFs (if enabled) if cfs and row['afferent_CFs'] is np.nan: print "No afferent connection fields found in the given row" elif cfs: cf_block = rasterplots.cf_image(*row['afferent_CFs'], border=5, width=1, height=8, pos=(4,1)) cf_block.save(fname % ('CFs', 'png')) # Save the scale bar or scale box SVG overlay scale_overlay = (vectorplots.scale_box_overlay if scalebox else vectorplots.scale_bar_overlay) scale = scale_overlay(row['units_per_hypercolumn']/float(pref.shape[0])) scale.savefig(fname % ('SBOX' if scalebox else 'SBAR', 'svg'), **savefig_opts) vectorplots.close([hist, contour_fig, scale]) layers = {'-scalebox':(not scalebox), '+scalebox':scalebox, '-CFs':(not cfs), '+CFs':cfs} svg_path = os.path.join(output_dir, '%s.svg' % name) return compose.apply_template(template_path, svg_path, mapping={'[LABEL]':name}, layers=layers, size_factor=size_factor)
def OR_analysis( row, template_dir, build_dir, name='OR_analysis', selectivity=False, contours=False, cfs=True, scalebox=False, size_factor=1.0, ): """ Builds a pinwheel analysis of a single orientation map from a template. Used in Figures 3 and 6-9. Displays an annotated map with pinwheels next to the FFT spectrum and corresponding fit. The selectivity channel of the map can be enabled as can pinwheel contours and a column of central connection fields. The map can have either a normal scalebar or a box showing the hypercolumn area. """ template_path, output_dir = setup('OR_analysis', template_dir, build_dir, subdir=name) savefig_opts = dict(transparent=True, format='svg', bbox_inches='tight', pad_inches=0) pref = get_pref(row) sel = get_sel(row) if selectivity else None fname = os.path.join(output_dir, '%%s_%s.%%s' % name) # Save the OR preference and selectivity raster or_map = rasterplots.OR_map(pref, sel) rasterplots.black_selectivity(or_map).save(fname % ('OR', 'png')) # Save the FFT raster rasterplots.greyscale(analysis.power_spectrum(pref)).save(fname % ('FFT', 'png')) # Save the histogram SVG overlay hist = vectorplots.FFT_histogram_overlay(row['amplitudes'], row['fit']) hist.savefig(fname % ('HIST', 'svg'), **savefig_opts) # Save the pinwheel contour SVG overlay contours = (row['re_contours'], row['im_contours']) if contours else None contour_fig = vectorplots.pinwheel_overlay(row['pinwheels'], contours=contours) contour_fig.savefig(fname % ('OVERLAY', 'svg'), **savefig_opts) # Save the CFs (if enabled) if cfs and row['afferent_CFs'] is np.nan: print "No afferent connection fields found in the given row" elif cfs: cf_block = rasterplots.cf_image(*row['afferent_CFs'], border=5, width=1, height=8, pos=(4, 1)) cf_block.save(fname % ('CFs', 'png')) # Save the scale bar or scale box SVG overlay scale_overlay = (vectorplots.scale_box_overlay if scalebox else vectorplots.scale_bar_overlay) scale = scale_overlay(row['units_per_hypercolumn'] / float(pref.shape[0])) scale.savefig(fname % ('SBOX' if scalebox else 'SBAR', 'svg'), **savefig_opts) vectorplots.close([hist, contour_fig, scale]) layers = { '-scalebox': (not scalebox), '+scalebox': scalebox, '-CFs': (not cfs), '+CFs': cfs } svg_path = os.path.join(output_dir, '%s.svg' % name) return compose.apply_template(template_path, svg_path, mapping={'[LABEL]': name}, layers=layers, size_factor=size_factor)
def fig10(template_dir, build_dir, bound_radius=0.6, selectivity_norm=0.07138, size_factor=1.0, show_raster=False): name = 'fig10' if show_raster: return Display(snapshot=name, template_dir=template_dir) times = [2000 * i for i in range(6)] template_path, output_dir = setup(name, template_dir, build_dir) pattern = 'jn13_figures/output/Fig10_12/*/*/*.npz' files = lancet.FilePattern('npz_file', pattern) file_info = lancet.FileInfo(files, 'npz_file', lancet.NumpyFile()) filter_times = file_info.dframe['time'].map(lambda x: x in times) selection = file_info.load(file_info.dframe[filter_times]) savefig_opts = dict(transparent=True, format='svg', bbox_inches='tight', pad_inches=0) development_info = [] for (index, row) in selection.iterrows(): time = row['time'] fname = os.path.join(output_dir, '%%s_%.1f.png' % int(time)) bounds = imagen.boundingregion.BoundingBox(radius=0.75) sheetcoords = imagen.SheetCoordinateSystem(bounds, xdensity=98) roi = slice(*sheetcoords.sheet2matrixidx(bound_radius, bound_radius)) # Not applying ROI as new bounds will be used pref = get_pref(row, roi=roi) sel = get_sel(row, roi=roi) (cfs, coords) = row['afferent_CFs'] roi = slice(*sheetcoords.sheet2matrixidx(bound_radius, bound_radius)) # Create the combined preference/selectivity map or_map = rasterplots.OR_map(pref, sel) or_black = rasterplots.black_selectivity(or_map) (dim1, dim2) = pref.shape or_black_resized = rasterplots.resize(or_black, (dim1 * 4, dim2 * 4)) # Save the orientation map or_black_resized.save(fname % 'OR') # Save the row of CF images cf_block = rasterplots.cf_image(cfs, coords, border=5, width=8, height=1, pos=(1, 4), bg=(255, 255, 255)) cf_block.save(fname % 'CF') # Save the FFT of the last map if time == times[-1]: normalized_spectrum = analysis.power_spectrum(pref[roi, roi]) fft_im = rasterplots.greyscale(normalized_spectrum) fft_im.save(fname % 'FFT') # Note: ROI not applied and the values of 3 are due to historical reasons development_info.append((time, pref[3:-3, 3:-3], np.mean(sel[3:-3, 3:-3]))) ts, prefs, mean_sels = zip(*sorted(development_info)) # We only need the stabilities up till 10000 fname = os.path.join(output_dir, 'model_development.svg') development_fig = vectorplots.map_development_plot( analysis.stability_index(prefs), mean_sels, selectivity_norm) development_fig.savefig(fname, **savefig_opts) vectorplots.close([development_fig]) svg_path = os.path.join(output_dir, '%s.svg' % name) return Display( compose.apply_template(template_path, svg_path, size_factor=size_factor))