def test_simulate_3(): """ No photo-physics, spline PSF, sCMOS camera. """ # Only test for Python3 due to pickle incompatibility issues. if (sys.version_info < (3, 0)): return dax_name = storm_analysis.getPathOutputTest("test_sim3.dax") bin_name = storm_analysis.getData("test/data/test_sim.hdf5") cal_name = storm_analysis.getData("test/data/calib.npy") spline_name = storm_analysis.getData("test/data/test_spliner_psf.spline") sim = simulate.Simulate( background_factory=lambda settings, xs, ys, i3data: background. UniformBackground(settings, xs, ys, i3data, photons=20), camera_factory=lambda settings, xs, ys, i3data: camera.SCMOS( settings, xs, ys, i3data, cal_name), photophysics_factory=lambda settings, xs, ys, i3data: photophysics. AlwaysOn(settings, xs, ys, i3data, 2000.0), psf_factory=lambda settings, xs, ys, i3data: psf.Spline( settings, xs, ys, i3data, 160.0, spline_name)) sim.simulate(dax_name, bin_name, 5)
def makeDataPupilFnCMOS(settings, cal_file, dither): """ Pupil function PSF, CMOS camera movies. """ index = 1 for [bg, photons] in settings.photons: wdir = "test_{0:02d}".format(index) print(wdir) if not os.path.exists(wdir): os.makedirs(wdir) bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg) cam_f = lambda s, x, y, i3: camera.SCMOS(s, x, y, i3, cal_file) pp_f = lambda s, x, y, i3: photophysics.AlwaysOn(s, x, y, i3, photons) psf_f = lambda s, x, y, i3: psf.PupilFunction(s, x, y, i3, settings. pixel_size, settings.zmn) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, dither=dither, x_size=settings.x_size, y_size=settings.y_size) sim.simulate(wdir + "/test.tif", "grid_list.hdf5", settings.n_frames) index += 1 makePeakFile(settings)
def makeData(cal_file="calib.npy", dither=False, verbosity=1): index = 1 for [bg, photons] in settings.photons: wdir = "test_{0:02d}".format(index) print(wdir) if not os.path.exists(wdir): os.makedirs(wdir) bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg) cam_f = lambda s, x, y, i3: camera.SCMOS(s, x, y, i3, cal_file) pp_f = lambda s, x, y, i3: photophysics.AlwaysOn(s, x, y, i3, photons) psf_f = lambda s, x, y, i3: psf.GaussianPSF(s, x, y, i3, settings. pixel_size) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, dither=dither, x_size=settings.x_size, y_size=settings.y_size) sim.simulate(wdir + "/test.tif", "grid_list.hdf5", settings.n_frames, verbosity=verbosity) index += 1 makeDataCommon.makePeakFile(settings)
def makeData(): index = 1 # Create HDF5 files for each plane. # for elt in ["grid_list.hdf5", "random_storm.hdf5"]: locs = saH5Py.loadLocalizations(elt) locs["color"] = numpy.random.randint(4, size=locs["x"].size) zo = locs["z"].copy() locs["z"][:] = zo + 1.0e-3 * settings.z_planes[0] saH5Py.saveLocalizations("sim_input_c1_" + elt, locs) for i in range(1, 4): locs["x"] += settings.dx locs["y"] += settings.dy locs["z"][:] = zo + 1.0e-3 * settings.z_planes[i] saH5Py.saveLocalizations("sim_input_c" + str(i + 1) + "_" + elt, locs) if True: # Create a movie for each plane. for [bg, photons] in settings.photons: # Adjust photons by the number of planes. photons = photons / float(len(settings.z_planes)) wdir = "test_{0:02d}".format(index) print(wdir) if not os.path.exists(wdir): os.makedirs(wdir) for i in range(4): bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg) cam_f = lambda s, x, y, i3: camera.SCMOS( s, x, y, i3, "calib.npy") pp_f = lambda s, x, y, i3: photophysics.AlwaysOnMC( s, x, y, i3, color=i, photons=photons) psf_f = lambda s, x, y, i3: psf.PupilFunction( s, x, y, i3, settings.pixel_size, []) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) sim.simulate(wdir + "/test_c" + str(i + 1) + ".dax", "sim_input_c" + str(i + 1) + "_grid_list.hdf5", settings.n_frames) index += 1
def test_simulate_3(): """ No photo-physics, spline PSF, sCMOS camera. """ dax_name = storm_analysis.getPathOutputTest("test_sim3.dax") bin_name = storm_analysis.getData("test/data/test_sim_olist.bin") cal_name = storm_analysis.getData("test/data/calib.npy") spline_name = storm_analysis.getData("test/data/test_spliner_psf.spline") sim = simulate.Simulate(lambda settings, xs, ys, i3data : background.UniformBackground(settings, xs, ys, i3data, photons = 20), lambda settings, xs, ys, i3data : camera.SCMOS(settings, xs, ys, i3data, 100.0, cal_name), lambda settings, xs, ys, i3data : photophysics.AlwaysOn(settings, xs, ys, i3data, 2000.0), lambda settings, xs, ys, i3data : psf.Spline(settings, xs, ys, i3data, 160.0, spline_name)) sim.simulate(dax_name, bin_name, 5)
def makeData(cal_file="calib.npy", dither=False): index = 1 if True: for [bg, photons] in settings.photons: wdir = "test_{0:02d}".format(index) print(wdir) if not os.path.exists(wdir): os.makedirs(wdir) bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg) cam_f = lambda s, x, y, i3: camera.SCMOS(s, x, y, i3, cal_file) pp_f = lambda s, x, y, i3: photophysics.AlwaysOn( s, x, y, i3, photons) psf_f = lambda s, x, y, i3: psf.GaussianPSF( s, x, y, i3, settings.pixel_size) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, dither=dither, x_size=settings.x_size, y_size=settings.y_size) sim.simulate(wdir + "/test.tif", "grid_list.hdf5", settings.n_frames) index += 1 # Create "peak_locations" file if needed. # if hasattr(settings, "peak_locations") and (settings.peak_locations is not None): with saH5Py.SAH5Py("test_01/test_ref.hdf5") as h5: locs = h5.getLocalizationsInFrame(0) if settings.peak_locations.endswith(".hdf5"): saH5Py.saveLocalizations(settings.peak_locations, locs) else: numpy.savetxt( settings.peak_locations, numpy.transpose( numpy.vstack((locs['x'], locs['y'], locs['height'], locs['background']))))
def configure(psf_model, no_splines): # Create parameters file for analysis. # print("Creating XML file.") params = testingParameters(psf_model) params.toXMLFile("multiplane.xml") # Create localization on a grid file. # print("Creating gridded localization.") sim_path = os.path.dirname(inspect.getfile(storm_analysis)) + "/simulator/" subprocess.call([ "python", sim_path + "emitters_on_grid.py", "--bin", "grid_list.hdf5", "--nx", str(settings.nx), "--ny", str(settings.ny), "--spacing", "20", "--zrange", str(settings.test_z_range), "--zoffset", str(settings.test_z_offset) ]) # Create randomly located localizations file. # print("Creating random localization.") subprocess.call([ "python", sim_path + "emitters_uniform_random.py", "--bin", "random_list.hdf5", "--density", "1.0", "--margin", str(settings.margin), "--sx", str(settings.x_size), "--sy", str(settings.y_size), "--zrange", str(settings.test_z_range) ]) # Create sparser grid for PSF measurement. # print("Creating data for PSF measurement.") sim_path = os.path.dirname(inspect.getfile(storm_analysis)) + "/simulator/" subprocess.call([ "python", sim_path + "emitters_on_grid.py", "--bin", "psf_list.hdf5", "--nx", "6", "--ny", "3", "--spacing", "40" ]) # Create sCMOS camera calibration files. # numpy.save("calib.npy", [ numpy.zeros( (settings.y_size, settings.x_size)) + settings.camera_offset, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_variance, numpy.ones((settings.y_size, settings.x_size)) * settings.camera_gain, numpy.ones((settings.y_size, settings.x_size)), 2 ]) # Create mapping file. with open("map.map", 'wb') as fp: pickle.dump(settings.mappings, fp) if no_splines: return multiplane_path = os.path.dirname( inspect.getfile(storm_analysis)) + "/multi_plane/" # Create pupil functions for 'pupilfn'. if (psf_model == "pupilfn"): pupilfn_path = os.path.dirname( inspect.getfile(storm_analysis)) + "/pupilfn/" print("Creating pupil functions.") for i in range(len(settings.z_planes)): subprocess.call([ "python", pupilfn_path + "make_pupil_fn.py", "--filename", "c" + str(i + 1) + "_pupilfn.pfn", "--size", str(settings.psf_size), "--pixel-size", str(settings.pixel_size), "--zmn", str(settings.pupil_fn), "--z-offset", str(-settings.z_planes[i]) ]) # Both 'spline' and 'psf_fft' need measured PSFs. else: # Create localization files for PSF measurement. # locs = saH5Py.loadLocalizations("psf_list.hdf5") for i, z_offset in enumerate(settings.z_planes): cx = settings.mappings["0_" + str(i) + "_x"] cy = settings.mappings["0_" + str(i) + "_y"] locs_temp = { "x": locs["x"].copy(), "y": locs["y"].copy(), "z": locs["z"].copy() } xi = locs_temp["x"] yi = locs_temp["y"] xf = cx[0] + cx[1] * xi + cx[2] * yi yf = cy[0] + cy[1] * xi + cy[2] * yi locs_temp["x"] = xf locs_temp["y"] = yf locs_temp["z"][:] = z_offset saH5Py.saveLocalizations("c" + str(i + 1) + "_psf.hdf5", locs_temp) # Create drift file, this is used to displace the localizations in the # PSF measurement movie. # dz = numpy.arange(-settings.spline_z_range, settings.spline_z_range + 0.001, 0.01) drift_data = numpy.zeros((dz.size, 3)) drift_data[:, 2] = dz numpy.savetxt("drift.txt", drift_data) # Also create the z-offset file. # z_offset = numpy.ones((dz.size, 2)) z_offset[:, 1] = dz numpy.savetxt("z_offset.txt", z_offset) # Create simulated data for PSF measurements. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") drift_f = lambda s, x, y, h5: drift.DriftFromFile( s, x, y, h5, "drift.txt") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 20000.0) psf_f = lambda s, x, y, h5: psf.PupilFunction( s, x, y, h5, settings.pixel_size, settings.pupil_fn) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, drift_factory=drift_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) for i in range(len(settings.z_planes)): sim.simulate("c" + str(i + 1) + "_zcal.dax", "c" + str(i + 1) + "_psf.hdf5", dz.size) # Measure the PSF. # print("Measuring PSFs.") psf_fft_path = os.path.dirname( inspect.getfile(storm_analysis)) + "/psf_fft/" spliner_path = os.path.dirname( inspect.getfile(storm_analysis)) + "/spliner/" for i in range(len(settings.z_planes)): subprocess.call([ "python", multiplane_path + "psf_zstack.py", "--movie", "c" + str(i + 1) + "_zcal.dax", "--bin", "c" + str(i + 1) + "_psf.hdf5", "--zstack", "c" + str(i + 1) + "_zstack", "--scmos_cal", "calib.npy", "--aoi_size", str(int(settings.psf_size / 2) + 1) ]) # Measure PSF and calculate spline for Spliner. # if (psf_model == "spline"): # PSFs are independently normalized. # if settings.independent_heights: for i in range(len(settings.z_planes)): subprocess.call([ "python", multiplane_path + "measure_psf.py", "--zstack", "c" + str(i + 1) + "_zstack.npy", "--zoffsets", "z_offset.txt", "--psf_name", "c" + str(i + 1) + "_psf_normed.psf", "--z_range", str(settings.spline_z_range), "--normalize", "True" ]) # PSFs are normalized to each other. # else: for i in range(len(settings.z_planes)): subprocess.call([ "python", multiplane_path + "measure_psf.py", "--zstack", "c" + str(i + 1) + "_zstack.npy", "--zoffsets", "z_offset.txt", "--psf_name", "c" + str(i + 1) + "_psf.psf", "--z_range", str(settings.spline_z_range) ]) norm_args = [ "python", multiplane_path + "normalize_psfs.py", "--psfs", "c1_psf.psf" ] for i in range(len(settings.z_planes) - 1): norm_args.append("c" + str(i + 2) + "_psf.psf") subprocess.call(norm_args) # Measure the spline for Spliner. # print("Measuring Spline.") for i in range(len(settings.z_planes)): subprocess.call([ "python", spliner_path + "psf_to_spline.py", "--psf", "c" + str(i + 1) + "_psf_normed.psf", "--spline", "c" + str(i + 1) + "_psf.spline", "--spline_size", str(settings.psf_size) ]) # Measure PSF and downsample for PSF FFT. # elif (psf_model == "psf_fft"): # PSFs are independently normalized. # if settings.independent_heights: for i in range(len(settings.z_planes)): subprocess.call([ "python", multiplane_path + "measure_psf.py", "--zstack", "c" + str(i + 1) + "_zstack.npy", "--zoffsets", "z_offset.txt", "--psf_name", "c" + str(i + 1) + "_psf_normed.psf", "--z_range", str(settings.psf_z_range), "--z_step", str(settings.psf_z_step), "--normalize", "True" ]) # PSFs are normalized to each other. # else: for i in range(len(settings.z_planes)): subprocess.call([ "python", multiplane_path + "measure_psf.py", "--zstack", "c" + str(i + 1) + "_zstack.npy", "--zoffsets", "z_offset.txt", "--psf_name", "c" + str(i + 1) + "_psf.psf", "--z_range", str(settings.psf_z_range), "--z_step", str(settings.psf_z_step) ]) norm_args = [ "python", multiplane_path + "normalize_psfs.py", "--psfs", "c1_psf.psf" ] for i in range(len(settings.z_planes) - 1): norm_args.append("c" + str(i + 2) + "_psf.psf") subprocess.call(norm_args) # Downsample the PSF to 1x for PSF FFT. print("Downsampling PSF.") for i in range(len(settings.z_planes)): subprocess.call([ "python", psf_fft_path + "downsample_psf.py", "--spliner_psf", "c" + str(i + 1) + "_psf_normed.psf", "--psf", "c" + str(i + 1) + "_psf_fft.psf", "--pixel-size", str(settings.pixel_size) ]) # Calculate Cramer-Rao weighting. # print("Calculating weights.") subprocess.call([ "python", multiplane_path + "plane_weighting.py", "--background", str(settings.photons[0][0]), "--photons", str(settings.photons[0][1]), "--output", "weights.npy", "--xml", "multiplane.xml", "--no_plots" ])
def configure(): # Get relevant paths. mm_path = os.path.dirname(inspect.getfile(storm_analysis)) + "/micrometry/" mp_path = os.path.dirname( inspect.getfile(storm_analysis)) + "/multi_plane/" sp_path = os.path.dirname(inspect.getfile(storm_analysis)) + "/spliner/" # Create analysis XML files. # print("Creating XML files.") params = testingParametersSCMOS() params.toXMLFile("scmos.xml") params = testingParametersMC() params.toXMLFile("multicolor.xml") # Useful variables aoi_size = int(settings.psf_size / 2) + 1 # Create sCMOS data and HDF5 files we'll need for the simulation. # if True: # Create sCMOS camera calibration files. # numpy.save("calib.npy", [ numpy.zeros( (settings.y_size, settings.x_size)) + settings.camera_offset, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_variance, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_gain, 1 ]) # Create localization on a grid file. # print("Creating gridded localizations.") sim_path = os.path.dirname( inspect.getfile(storm_analysis)) + "/simulator/" subprocess.call([ "python", sim_path + "emitters_on_grid.py", "--bin", "grid_list.hdf5", "--nx", str(settings.nx), "--ny", str(settings.ny), "--spacing", "20", "--zrange", str(settings.test_z_range), "--zoffset", str(settings.test_z_offset) ]) # Create randomly located localizations file (for STORM movies). # print("Creating random localizations.") subprocess.call([ "python", sim_path + "emitters_uniform_random.py", "--bin", "random_storm.hdf5", "--density", "1.0", "--margin", str(settings.margin), "--sx", str(settings.x_size), "--sy", str(settings.y_size), "--zrange", str(settings.test_z_range) ]) # Create randomly located localizations file (for mapping measurement). # print("Creating random localizations.") subprocess.call([ "python", sim_path + "emitters_uniform_random.py", "--bin", "random_map.hdf5", "--density", "0.0003", "--margin", str(settings.margin), "--sx", str(settings.x_size), "--sy", str(settings.y_size) ]) # Create sparser grid for PSF measurement. # print("Creating data for PSF measurement.") sim_path = os.path.dirname( inspect.getfile(storm_analysis)) + "/simulator/" subprocess.call([ "python", sim_path + "emitters_on_grid.py", "--bin", "psf_list.hdf5", "--nx", "6", "--ny", "3", "--spacing", "40" ]) ## This part makes / tests measuring the mapping. ## if True: print("Measuring mapping.") # Make localization files for simulations. # locs = saH5Py.loadLocalizations("random_map.hdf5") locs["z"][:] = 1.0e-3 * settings.z_planes[0] saH5Py.saveLocalizations("c1_random_map.hdf5", locs) for i in range(1, 4): locs["x"] += settings.dx locs["y"] += settings.dy locs["z"][:] = settings.z_planes[i] saH5Py.saveLocalizations("c" + str(i + 1) + "_random_map.hdf5", locs) # Make localization files for simulations. # locs = saH5Py.loadLocalizations("random_map.hdf5") locs["z"][:] = 1.0e-3 * settings.z_planes[0] saH5Py.saveLocalizations("c1_random_map.hdf5", locs) for i in range(1, 4): locs["x"] += settings.dx locs["y"] += settings.dy locs["z"][:] = settings.z_planes[i] saH5Py.saveLocalizations("c" + str(i + 1) + "_random_map.hdf5", locs) # Make simulated mapping data. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 20000.0) psf_f = lambda s, x, y, i3: psf.GaussianPSF(s, x, y, i3, settings. pixel_size) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) for i in range(4): sim.simulate("c" + str(i + 1) + "_map.dax", "c" + str(i + 1) + "_random_map.hdf5", 1) # Analyze simulated mapping data # for i in range(4): scmos.analyze("c" + str(i + 1) + "_map.dax", "c" + str(i + 1) + "_map.hdf5", "scmos.xml") # Measure mapping. # for i in range(3): subprocess.call([ "python", mm_path + "micrometry.py", "--locs1", "c1_map.hdf5", "--locs2", "c" + str(i + 2) + "_map.hdf5", "--results", "c1_c" + str(i + 2) + "_map.map", "--no_plots" ]) # Merge mapping. # subprocess.call([ "python", mm_path + "merge_maps.py", "--results", "map.map", "--maps", "c1_c2_map.map", "c1_c3_map.map", "c1_c4_map.map" ]) # Print mapping. # if True: print("Mapping is:") subprocess.call([ "python", mp_path + "print_mapping.py", "--mapping", "map.map" ]) print("") # Check that mapping is close to what we expect (within 5%). # with open("map.map", 'rb') as fp: mappings = pickle.load(fp) for i in range(3): if not numpy.allclose(mappings["0_" + str(i + 1) + "_x"], numpy.array( [settings.dx * (i + 1), 1.0, 0.0]), rtol=0.05, atol=0.05): print("X mapping difference for channel", i + 1) if not numpy.allclose(mappings["0_" + str(i + 1) + "_y"], numpy.array( [settings.dy * (i + 1), 0.0, 1.0]), rtol=0.05, atol=0.05): print("Y mapping difference for channel", i + 1) ## This part measures / test the PSF measurement. ## if True: # Create drift file, this is used to displace the localizations in the # PSF measurement movie. # dz = numpy.arange(-settings.psf_z_range, settings.psf_z_range + 0.05, 0.01) drift_data = numpy.zeros((dz.size, 3)) drift_data[:, 2] = dz numpy.savetxt("drift.txt", drift_data) # Also create the z-offset file. # z_offset = numpy.ones((dz.size, 2)) z_offset[:, 1] = dz numpy.savetxt("z_offset.txt", z_offset) # Create simulated data for PSF measurements. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") drift_f = lambda s, x, y, h5: drift.DriftFromFile( s, x, y, h5, "drift.txt") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 20000.0) psf_f = lambda s, x, y, h5: psf.PupilFunction(s, x, y, h5, settings. pixel_size, []) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, drift_factory=drift_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) if True: for i in range(4): sim.simulate("c" + str(i + 1) + "_zcal.dax", "c" + str(i + 1) + "_random_map.hdf5", dz.size) # Get localizations to use for PSF measurement. # subprocess.call([ "python", mp_path + "psf_localizations.py", "--bin", "c1_map_ref.hdf5", "--map", "map.map", "--aoi_size", str(aoi_size) ]) # Create PSF z stacks. # for i in range(4): subprocess.call([ "python", mp_path + "psf_zstack.py", "--movie", "c" + str(i + 1) + "_zcal.dax", "--bin", "c1_map_ref_c" + str(i + 1) + "_psf.hdf5", "--zstack", "c" + str(i + 1) + "_zstack", "--scmos_cal", "calib.npy", "--aoi_size", str(aoi_size) ]) # Measure PSF. # for i in range(4): subprocess.call([ "python", mp_path + "measure_psf.py", "--zstack", "c" + str(i + 1) + "_zstack.npy", "--zoffsets", "z_offset.txt", "--psf_name", "c" + str(i + 1) + "_psf_normed.psf", "--z_range", str(settings.psf_z_range), "--normalize" ]) ## This part creates the splines. ## if True: print("Measuring Splines.") for i in range(4): subprocess.call([ "python", sp_path + "psf_to_spline.py", "--psf", "c" + str(i + 1) + "_psf_normed.psf", "--spline", "c" + str(i + 1) + "_psf.spline", "--spline_size", str(settings.psf_size) ]) ## This part measures the Cramer-Rao weights. ## if True: print("Calculating weights.") subprocess.call([ "python", mp_path + "plane_weighting.py", "--background", str(settings.photons[0][0]), "--photons", str(settings.photons[0][1]), "--output", "weights.npy", "--xml", "multicolor.xml", "--no_plots" ])
def makeData(): index = 1 if True: # Create .bin files for each plane. h5_locs = saH5Py.loadLocalizations("grid_list.hdf5") # Load channel to channel mapping file. with open("map.map", 'rb') as fp: mappings = pickle.load(fp) for i, z_plane in enumerate(settings.z_planes): cx = mappings["0_" + str(i) + "_x"] cy = mappings["0_" + str(i) + "_y"] xi = h5_locs["x"].copy() yi = h5_locs["y"].copy() zi = h5_locs["z"].copy() xf = cx[0] + cx[1] * xi + cx[2] * yi yf = cy[0] + cy[1] * xi + cy[2] * yi zf = zi + z_plane h5_temp = {"x": xf, "y": yf, "z": zf} saH5Py.saveLocalizations("sim_input_c" + str(i + 1) + ".hdf5", h5_temp) # Create a movie for each plane. for [bg, photons] in settings.photons: # Adjust photons by the number of planes. photons = photons / float(len(settings.z_planes)) wdir = "test_{0:02d}".format(index) print(wdir) if not os.path.exists(wdir): os.makedirs(wdir) bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg) cam_f = lambda s, x, y, i3: camera.SCMOS(s, x, y, i3, "calib.npy") pp_f = lambda s, x, y, i3: photophysics.AlwaysOn( s, x, y, i3, photons) psf_f = lambda s, x, y, i3: psf.PupilFunction( s, x, y, i3, settings.pixel_size, settings.pupil_fn) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) for i in range(len(settings.z_planes)): sim.simulate(wdir + "/test_c" + str(i + 1) + ".dax", "sim_input_c" + str(i + 1) + ".hdf5", settings.n_frames) index += 1 # Create "peak_locations" file if needed. # if hasattr(settings, "peak_locations") and (settings.peak_locations is not None): with saH5Py.SAH5Py("test_01/test_c1_ref.hdf5") as h5: locs = h5.getLocalizationsInFrame(0) if settings.peak_locations.endswith(".hdf5"): saH5Py.saveLocalizations(settings.peak_locations, locs) else: numpy.savetxt( settings.peak_locations, numpy.transpose( numpy.vstack((locs['x'], locs['y'], locs['height'], locs['background']))))
def makeSampleData(mappings=None): # Create sample bead data for mapping measurement. # # Create randomly located localizations file (for STORM movies). # print("Creating random localizations.") emittersUniformRandom.emittersUniformRandom("random.hdf5", density, margin, x_size, y_size, 0.0) # Create mapping, if not specified. # if mappings is None: mappings = { "0_0_x": numpy.array([0.0, 1.0, 0.0]), "0_0_y": numpy.array([0.0, 0.0, 1.0]), "0_1_x": numpy.array([2.0, 1.0, 0.0]), "0_1_y": numpy.array([5.0, 0.0, 1.0]), "1_0_x": numpy.array([-2.0, 1.0, 0.0]), "1_0_y": numpy.array([-5.0, 0.0, 1.0]) } # Figure out number of planes in the mapping. # n_planes = 0 for elt in mappings: [i, j] = map(int, elt.split("_")[:2]) if (i > n_planes): n_planes = i n_planes += 1 print(n_planes) # Create localization files for PSF measurement. # locs = saH5Py.loadLocalizations("random.hdf5") for i in range(n_planes): cx = mappings["0_" + str(i) + "_x"] cy = mappings["0_" + str(i) + "_y"] locs_temp = { "x": locs["x"].copy(), "y": locs["y"].copy(), "z": locs["z"].copy() } xi = locs_temp["x"] yi = locs_temp["y"] xf = cx[0] + cx[1] * xi + cx[2] * yi yf = cy[0] + cy[1] * xi + cy[2] * yi locs_temp["x"] = xf locs_temp["y"] = yf saH5Py.saveLocalizations("c" + str(i + 1) + "_map.hdf5", locs_temp) # Create simulated data for PSF measurements. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 10000.0) psf_f = lambda s, x, y, h5: psf.PupilFunction(s, x, y, h5, pixel_size, []) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=x_size, y_size=y_size) for i in range(n_planes): sim.simulate("c" + str(i + 1) + "_map.dax", "c" + str(i + 1) + "_map.hdf5", 2)
def makeSampleData(): # Create sample bead data for PSF measurement. # # Create sparser grid for PSF measurement. # print("Creating data for PSF measurement.") emittersOnGrid.emittersOnGrid("psf_locs.hdf5", 6, 3, 1.5, 40, 0.0, 0.0) # Create localization files for PSF measurement. # locs = saH5Py.loadLocalizations("psf_locs.hdf5") for i, z_offset in enumerate(z_planes): cx = mappings["0_" + str(i) + "_x"] cy = mappings["0_" + str(i) + "_y"] locs_temp = { "x": locs["x"].copy(), "y": locs["y"].copy(), "z": locs["z"].copy() } xi = locs_temp["x"] yi = locs_temp["y"] xf = cx[0] + cx[1] * xi + cx[2] * yi yf = cy[0] + cy[1] * xi + cy[2] * yi locs_temp["x"] = xf locs_temp["y"] = yf locs_temp["z"][:] = z_offset saH5Py.saveLocalizations("c" + str(i + 1) + "_psf.hdf5", locs_temp) # Create drift file, this is used to displace the localizations in the # PSF measurement movie. # dz = numpy.arange(-spline_z_range, spline_z_range + 0.001, 0.01) drift_data = numpy.zeros((dz.size, 3)) drift_data[:, 2] = dz numpy.savetxt("drift.txt", drift_data) # Also create the z-offset file. # z_offset = numpy.ones((dz.size, 2)) z_offset[:, 1] = dz numpy.savetxt("z_offset.txt", z_offset) # Create simulated data for PSF measurements. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") drift_f = lambda s, x, y, h5: drift.DriftFromFile(s, x, y, h5, "drift.txt") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 20000.0) psf_f = lambda s, x, y, h5: psf.PupilFunction(s, x, y, h5, pixel_size, []) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, drift_factory=drift_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=x_size, y_size=y_size) for i in range(len(z_planes)): sim.simulate("c" + str(i + 1) + "_zcal.dax", "c" + str(i + 1) + "_psf.hdf5", dz.size)
def makeData(): index = 1 # sCMOS calibration file. if settings.random_variance: variance = numpy.random.exponential(scale=settings.camera_variance, size=(settings.y_size, settings.x_size)) offset = settings.camera_offset + variance numpy.save("calib.npy", [ offset, variance, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_gain, 1 ]) else: numpy.save("calib.npy", [ numpy.zeros( (settings.y_size, settings.x_size)) + settings.camera_offset, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_variance, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_gain, 1 ]) # sCMOS camera movies. # # For these simulations we expect (approximately) these results: # # Analysis Summary: # Total analysis time 10.64 seconds # Recall 0.93726 # Noise 0.05972 # XY Error (nm): # test_01 14.44 14.53 # test_02 8.26 8.24 # # XY Width Error, Mean difference with truth, Standard deviation (pixels): # test_01 0.029 0.116 0.029 0.116 # test_02 0.017 0.105 0.017 0.105 # if True: for [bg, photons] in settings.photons: wdir = "test_{0:02d}".format(index) print(wdir) if not os.path.exists(wdir): os.makedirs(wdir) bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg) cam_f = lambda s, x, y, i3: camera.SCMOS(s, x, y, i3, "calib.npy") pp_f = lambda s, x, y, i3: photophysics.AlwaysOn( s, x, y, i3, photons) psf_f = lambda s, x, y, i3: psf.GaussianPSF( s, x, y, i3, settings.pixel_size) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) sim.simulate(wdir + "/test.tif", "grid_list.hdf5", settings.n_frames) index += 1
def configure(psf_model, no_splines): # Create parameters file for analysis. # print("Creating XML file.") params = testingParameters(psf_model) params.toXMLFile("multiplane.xml") # Create localization on a grid file. # print("Creating gridded localization.") emittersOnGrid.emittersOnGrid("grid_list.hdf5", settings.nx, settings.ny, 1.5, 20, settings.test_z_range, settings.test_z_offset) # Create randomly located localizations file. # print("Creating random localization.") emittersUniformRandom.emittersUniformRandom("random_list.hdf5", 1.0, settings.margin, settings.x_size, settings.y_size, settings.test_z_range) # Create sparser grid for PSF measurement. # print("Creating data for PSF measurement.") emittersOnGrid.emittersOnGrid("psf_list.hdf5", 6, 3, 1.5, 40, 0.0, 0.0) # Create sCMOS camera calibration files. # numpy.save("calib.npy", [ numpy.zeros( (settings.y_size, settings.x_size)) + settings.camera_offset, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_variance, numpy.ones((settings.y_size, settings.x_size)) * settings.camera_gain, numpy.ones((settings.y_size, settings.x_size)), 2 ]) # Create mapping file. with open("map.map", 'wb') as fp: pickle.dump(settings.mappings, fp) if no_splines: return # Create pupil functions for 'pupilfn'. if (psf_model == "pupilfn"): print("Creating pupil functions.") for i in range(len(settings.z_planes)): makePupilFn.makePupilFunction("c" + str(i + 1) + "_pupilfn.pfn", settings.psf_size, settings.pixel_size * 1.0e-3, settings.pupil_fn, z_offset=-settings.z_planes[i]) # Both 'spline' and 'psf_fft' need measured PSFs. else: # Create localization files for PSF measurement. # locs = saH5Py.loadLocalizations("psf_list.hdf5") for i, z_offset in enumerate(settings.z_planes): cx = settings.mappings["0_" + str(i) + "_x"] cy = settings.mappings["0_" + str(i) + "_y"] locs_temp = { "x": locs["x"].copy(), "y": locs["y"].copy(), "z": locs["z"].copy() } xi = locs_temp["x"] yi = locs_temp["y"] xf = cx[0] + cx[1] * xi + cx[2] * yi yf = cy[0] + cy[1] * xi + cy[2] * yi locs_temp["x"] = xf locs_temp["y"] = yf locs_temp["z"][:] = z_offset saH5Py.saveLocalizations("c" + str(i + 1) + "_psf.hdf5", locs_temp) # Create drift file, this is used to displace the localizations in the # PSF measurement movie. # dz = numpy.arange(-settings.spline_z_range, settings.spline_z_range + 0.001, 0.01) drift_data = numpy.zeros((dz.size, 3)) drift_data[:, 2] = dz numpy.savetxt("drift.txt", drift_data) # Also create the z-offset file. # z_offset = numpy.ones((dz.size, 2)) z_offset[:, 1] = dz numpy.savetxt("z_offset.txt", z_offset) # Create simulated data for PSF measurements. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") drift_f = lambda s, x, y, h5: drift.DriftFromFile( s, x, y, h5, "drift.txt") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 20000.0) psf_f = lambda s, x, y, h5: psf.PupilFunction( s, x, y, h5, settings.pixel_size, settings.pupil_fn) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, drift_factory=drift_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) for i in range(len(settings.z_planes)): sim.simulate("c" + str(i + 1) + "_zcal.dax", "c" + str(i + 1) + "_psf.hdf5", dz.size) # Measure the PSF. # print("Measuring PSFs.") for i in range(len(settings.z_planes)): psfZStack.psfZStack("c" + str(i + 1) + "_zcal.dax", "c" + str(i + 1) + "_psf.hdf5", "c" + str(i + 1) + "_zstack", aoi_size=int(settings.psf_size / 2 + 1)) # Measure PSF and calculate spline for Spliner. # if (psf_model == "spline"): # PSFs are independently normalized. # if settings.independent_heights: for i in range(len(settings.z_planes)): mpMeasurePSF.measurePSF("c" + str(i + 1) + "_zstack.npy", "z_offset.txt", "c" + str(i + 1) + "_psf_normed.psf", z_range=settings.spline_z_range, normalize=True) # PSFs are normalized to each other. # else: for i in range(len(settings.z_planes)): mpMeasurePSF.measurePSF("c" + str(i + 1) + "_zstack.npy", "z_offset.txt", "c" + str(i + 1) + "_psf.psf", z_range=settings.spline_z_range) norm_args = ["c1_psf.psf"] for i in range(len(settings.z_planes) - 1): norm_args.append("c" + str(i + 2) + "_psf.psf") normalizePSFs.normalizePSFs(norm_args) # Measure the spline for Spliner. # print("Measuring Spline.") for i in range(len(settings.z_planes)): psfToSpline.psfToSpline("c" + str(i + 1) + "_psf_normed.psf", "c" + str(i + 1) + "_psf.spline", int(settings.psf_size / 2)) # Measure PSF and downsample for PSF FFT. # elif (psf_model == "psf_fft"): # PSFs are independently normalized. # if settings.independent_heights: for i in range(len(settings.z_planes)): mpMeasurePSF.measurePSF("c" + str(i + 1) + "_zstack.npy", "z_offset.txt", "c" + str(i + 1) + "_psf_normed.psf", z_range=settings.spline_z_range, normalize=True) # PSFs are normalized to each other. # else: for i in range(len(settings.z_planes)): mpMeasurePSF.measurePSF("c" + str(i + 1) + "_zstack.npy", "z_offset.txt", "c" + str(i + 1) + "_psf.psf", z_range=settings.spline_z_range) norm_args = ["c1_psf.psf"] for i in range(len(settings.z_planes) - 1): norm_args.append("c" + str(i + 2) + "_psf.psf") normalizePSFs.normalizePSFs(norm_args) # Calculate Cramer-Rao weighting. # print("Calculating weights.") planeWeighting.runPlaneWeighting("multiplane.xml", "weights.npy", [settings.photons[0][0]], settings.photons[0][1], no_plots=True)
def makeData(): # Create .bin files for each plane. h5_locs = saH5Py.loadLocalizations("grid_list.hdf5") # Load channel to channel mapping file. with open("map.map", 'rb') as fp: mappings = pickle.load(fp) # Add z offset to reference localizations. x = h5_locs["x"].copy() y = h5_locs["y"].copy() z = h5_locs["z"].copy() + settings.z_planes[0] h5_temp = {"x" : x, "y" : y, "z" : z} saH5Py.saveLocalizations("sim_input_c1.hdf5", h5_temp) # Create a movie for first plane. [bg, photons] = settings.photons # Adjust photons by the number of planes. photons = photons/float(len(settings.z_planes)) bg_f = lambda s, x, y, i3 : background.UniformBackground(s, x, y, i3, photons = bg) cam_f = lambda s, x, y, i3 : camera.SCMOS(s, x, y, i3, "calib.npy") pp_f = lambda s, x, y, i3 : photophysics.SimpleSTORM(s, x, y, i3, photons = photons, on_time = settings.on_time, off_time = settings.off_time) psf_f = lambda s, x, y, i3 : psf.PupilFunction(s, x, y, i3, settings.pixel_size, settings.pupil_fn) sim = simulate.Simulate(background_factory = bg_f, camera_factory = cam_f, photophysics_factory = pp_f, psf_factory = psf_f, x_size = settings.x_size, y_size = settings.y_size) sim.simulate(os.path.join(settings.wdir, "test_c1.dax"), "sim_input_c1.hdf5", settings.n_frames) # Create other movies. for i in range(1, len(settings.z_planes)): cx = mappings["0_" + str(i) + "_x"] cy = mappings["0_" + str(i) + "_y"] z_offset = settings.z_planes[i] - settings.z_planes[0] pp_f = lambda s, x, y, i3 : photophysics.Duplicate(s, x, y, i3, h5_name = os.path.join(settings.wdir, "test_c1_ref.hdf5"), cx = cx, cy = cy, z_offset = z_offset) sim = simulate.Simulate(background_factory = bg_f, camera_factory = cam_f, photophysics_factory = pp_f, psf_factory = psf_f, x_size = settings.x_size, y_size = settings.y_size) sim.simulate(os.path.join(settings.wdir, "test_c" + str(i+1) + ".dax"), "sim_input_c1.hdf5", # This is not actually used. settings.n_frames) # Remove any old XML files. for elt in glob.glob(os.path.join(settings.wdir, "job*.xml")): os.remove(elt) # Make analysis XML files. splitAnalysisXML.splitAnalysisXML(settings.wdir, "multiplane.xml", 0, settings.n_frames, settings.divisions)
saH5Py.saveLocalizations("sim_input_c" + str(i + 1) + ".hdf5", h5_temp) # Create a movie for each plane. for [bg, photons] in settings.photons: # Adjust photons by the number of planes. photons = photons / float(len(settings.z_planes)) wdir = "test_{0:02d}".format(index) print(wdir) if not os.path.exists(wdir): os.makedirs(wdir) bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg) cam_f = lambda s, x, y, i3: camera.SCMOS(s, x, y, i3, "calib.npy") pp_f = lambda s, x, y, i3: photophysics.AlwaysOn(s, x, y, i3, photons) psf_f = lambda s, x, y, i3: psf.PupilFunction( s, x, y, i3, settings.pixel_size, settings.pupil_fn) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) for i in range(len(settings.z_planes)): sim.simulate(wdir + "/test_c" + str(i + 1) + ".dax", "sim_input_c" + str(i + 1) + ".hdf5", settings.n_frames)
yi = i3_temp["y"] xf = cx[0] + cx[1] * xi + cx[2] * yi yf = cy[0] + cy[1] * xi + cy[2] * yi i3dtype.posSet(i3_temp, "x", xf) i3dtype.posSet(i3_temp, "y", yf) i3dtype.posSet(i3_temp, "z", z_plane + z_value) with writeinsight3.I3Writer("sim_input_c" + str(i) + ".bin") as i3w: i3w.addMolecules(i3_temp) # Create simulator object. bg_photons = int(100.0 / float(len(z_planes))) signal = 6000.0 / float(len(z_planes)) bg_f = lambda s, x, y, i3: background.UniformBackground( s, x, y, i3, photons=bg_photons) cam_f = lambda s, x, y, i3: camera.SCMOS(s, x, y, i3, 0.0, "cam_cal_c0.npy") pp_f = lambda s, x, y, i3: photophysics.AlwaysOn(s, x, y, i3, signal) if (len(z_planes) > 1): psf_f = lambda s, x, y, i3: psf.PupilFunction(s, x, y, i3, 100.0, []) else: psf_f = lambda s, x, y, i3: psf.PupilFunction(s, x, y, i3, 100.0, [[1.3, 2, 2]]) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=x_size, y_size=y_size)
def configure(): # Create analysis XML files. # print("Creating XML files.") params = testingParametersSCMOS() params.toXMLFile("scmos.xml") params = testingParametersMC() params.toXMLFile("multicolor.xml") # Useful variables aoi_size = int(settings.psf_size / 2) + 1 # Create sCMOS data and HDF5 files we'll need for the simulation. # if True: # Create sCMOS camera calibration files. # numpy.save("calib.npy", [ numpy.zeros( (settings.y_size, settings.x_size)) + settings.camera_offset, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_variance, numpy.ones( (settings.y_size, settings.x_size)) * settings.camera_gain, numpy.ones((settings.y_size, settings.x_size)), 2 ]) # Create localization on a grid file. # print("Creating gridded localizations.") emittersOnGrid.emittersOnGrid("grid_list.hdf5", settings.nx, settings.ny, 1.5, 20, settings.test_z_range, settings.test_z_offset) # Create randomly located localizations file (for STORM movies). # print("Creating random localizations.") emittersUniformRandom.emittersUniformRandom("random_storm.hdf5", 1.0, settings.margin, settings.x_size, settings.y_size, settings.test_z_range) # Create randomly located localizations file (for mapping measurement). # print("Creating random localizations.") emittersUniformRandom.emittersUniformRandom("random_map.hdf5", 0.0003, settings.margin, settings.x_size, settings.y_size, settings.test_z_range) # Create sparser grid for PSF measurement. # print("Creating data for PSF measurement.") emittersOnGrid.emittersOnGrid("psf_list.hdf5", 6, 3, 1.5, 40, 0.0, 0.0) ## This part makes / tests measuring the mapping. ## if True: print("Measuring mapping.") # Make localization files for simulations. # locs = saH5Py.loadLocalizations("random_map.hdf5") locs["z"][:] = 1.0e-3 * settings.z_planes[0] saH5Py.saveLocalizations("c1_random_map.hdf5", locs) for i in range(1, 4): locs["x"] += settings.dx locs["y"] += settings.dy locs["z"][:] = settings.z_planes[i] saH5Py.saveLocalizations("c" + str(i + 1) + "_random_map.hdf5", locs) # Make localization files for simulations. # locs = saH5Py.loadLocalizations("random_map.hdf5") locs["z"][:] = 1.0e-3 * settings.z_planes[0] saH5Py.saveLocalizations("c1_random_map.hdf5", locs) for i in range(1, 4): locs["x"] += settings.dx locs["y"] += settings.dy locs["z"][:] = settings.z_planes[i] saH5Py.saveLocalizations("c" + str(i + 1) + "_random_map.hdf5", locs) # Make simulated mapping data. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 20000.0) psf_f = lambda s, x, y, i3: psf.GaussianPSF(s, x, y, i3, settings. pixel_size) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) for i in range(4): sim.simulate("c" + str(i + 1) + "_map.dax", "c" + str(i + 1) + "_random_map.hdf5", 1) # Analyze simulated mapping data # for i in range(4): h5_name = "c" + str(i + 1) + "_map.hdf5" if os.path.exists(h5_name): os.remove(h5_name) scmos.analyze("c" + str(i + 1) + "_map.dax", h5_name, "scmos.xml") # Measure mapping. # for i in range(3): micrometry.runMicrometry("c1_map.hdf5", "c" + str(i + 2) + "_map.hdf5", "c1_c" + str(i + 2) + "_map.map", min_size=5.0, max_size=100.0, max_neighbors=20, tolerance=1.0e-2, no_plots=True) # Merge mapping and save results. # merged_map = mergeMaps.mergeMaps( ["c1_c2_map.map", "c1_c3_map.map", "c1_c4_map.map"]) with open("map.map", 'wb') as fp: pickle.dump(merged_map, fp) # Print mapping. # if True: print("Mapping is:") printMapping.printMapping("map.map") print("") # Check that mapping is close to what we expect (within 5%). # with open("map.map", 'rb') as fp: mappings = pickle.load(fp) for i in range(3): if not numpy.allclose(mappings["0_" + str(i + 1) + "_x"], numpy.array( [settings.dx * (i + 1), 1.0, 0.0]), rtol=0.05, atol=0.05): print("X mapping difference for channel", i + 1) if not numpy.allclose(mappings["0_" + str(i + 1) + "_y"], numpy.array( [settings.dy * (i + 1), 0.0, 1.0]), rtol=0.05, atol=0.05): print("Y mapping difference for channel", i + 1) ## This part measures / test the PSF measurement. ## if True: # Create drift file, this is used to displace the localizations in the # PSF measurement movie. # dz = numpy.arange(-settings.psf_z_range, settings.psf_z_range + 0.05, 0.01) drift_data = numpy.zeros((dz.size, 3)) drift_data[:, 2] = dz numpy.savetxt("drift.txt", drift_data) # Also create the z-offset file. # z_offset = numpy.ones((dz.size, 2)) z_offset[:, 1] = dz numpy.savetxt("z_offset.txt", z_offset) # Create simulated data for PSF measurements. # bg_f = lambda s, x, y, h5: background.UniformBackground( s, x, y, h5, photons=10) cam_f = lambda s, x, y, h5: camera.SCMOS(s, x, y, h5, "calib.npy") drift_f = lambda s, x, y, h5: drift.DriftFromFile( s, x, y, h5, "drift.txt") pp_f = lambda s, x, y, h5: photophysics.AlwaysOn(s, x, y, h5, 20000.0) psf_f = lambda s, x, y, h5: psf.PupilFunction(s, x, y, h5, settings. pixel_size, []) sim = simulate.Simulate(background_factory=bg_f, camera_factory=cam_f, drift_factory=drift_f, photophysics_factory=pp_f, psf_factory=psf_f, x_size=settings.x_size, y_size=settings.y_size) if True: for i in range(4): sim.simulate("c" + str(i + 1) + "_zcal.dax", "c" + str(i + 1) + "_random_map.hdf5", dz.size) # Get localizations to use for PSF measurement. # psfLocalizations.psfLocalizations("c1_map_ref.hdf5", "map.map", aoi_size=aoi_size) # Create PSF z stacks. # for i in range(4): psfZStack.psfZStack("c" + str(i + 1) + "_zcal.dax", "c1_map_ref_c" + str(i + 1) + "_psf.hdf5", "c" + str(i + 1) + "_zstack", aoi_size=aoi_size) # Measure PSF. # for i in range(4): mpMeasurePSF.measurePSF("c" + str(i + 1) + "_zstack.npy", "z_offset.txt", "c" + str(i + 1) + "_psf_normed.psf", z_range=settings.psf_z_range, normalize=True) ## This part creates the splines. ## if True: print("Measuring Splines.") for i in range(4): psfToSpline.psfToSpline("c" + str(i + 1) + "_psf_normed.psf", "c" + str(i + 1) + "_psf.spline", int(settings.psf_size / 2)) ## This part measures the Cramer-Rao weights. ## if True: print("Calculating weights.") planeWeighting.runPlaneWeighting("multicolor.xml", "weights.npy", [settings.photons[0][0]], settings.photons[0][1], no_plots=True)