wavelet_val = wavelet_distance.wt1.values wavelet_slope = wavelet_distance.wt1.slope # Wavelet with a break wave_break = Wavelet(dataset1['moment0']).run(xhigh=7 * u.pix, brk=5.5 * u.pix) wavelet_slope_wbrk = wave_break.slope wavelet_brk_wbrk = wave_break.brk.value # MVC from turbustat.statistics import MVC_Distance, MVC mvc_distance = MVC_Distance(dataset1, dataset2).distance_metric() mvc = MVC(dataset1["centroid"], dataset1["moment0"], dataset1["linewidth"]) mvc.run() mvc_val = mvc.ps1D mvc_slope = mvc.slope mvc_slope2D = mvc.slope2D # Spatial Power Spectrum/ Bispectrum from turbustat.statistics import (PSpec_Distance, BiSpectrum_Distance, BiSpectrum, PowerSpectrum) pspec_distance = \ PSpec_Distance(dataset1["moment0"], dataset2["moment0"]).distance_metric()
genus = Genus(moment0, lowdens_percent=15, highdens_percent=85, smoothing_radii=u.Quantity([0.04 * u.pc]), distance=250 * u.pc) genus.run(verbose=True, min_size=40 * u.AU**2, save_name=osjoin(fig_path, "genus_design4_physunits.png")) # MVC if run_mvc: from turbustat.statistics import MVC moment0 = fits.open(osjoin(data_path, "Design4_flatrho_0021_00_radmc_moment0.fits"))[0] centroid = fits.open(osjoin(data_path, "Design4_flatrho_0021_00_radmc_centroid.fits"))[0] lwidth = fits.open(osjoin(data_path, "Design4_flatrho_0021_00_radmc_linewidth.fits"))[0] mvc = MVC(centroid, moment0, lwidth) mvc.run(verbose=True, xunit=u.pix**-1, save_name=osjoin(fig_path, 'mvc_design4.png')) # With bounds mvc.run(verbose=True, xunit=u.pix**-1, low_cut=0.02 / u.pix, high_cut=0.1 / u.pix, save_name=osjoin(fig_path, 'mvc_design4_limitedfreq.png')) # With a break mvc = MVC(centroid, moment0, lwidth, distance=250 * u.pc) mvc.run(verbose=True, xunit=u.pix**-1, low_cut=0.02 / u.pix, high_cut=0.4 / u.pix, fit_kwargs=dict(brk=0.1 / u.pix), fit_2D=False, save_name=osjoin(fig_path, "mvc_design4_breakfit.png"))
def generate_unitvals(): import numpy as np import astropy.units as u # The machine producing these values should have emcee installed! try: import emcee except ImportError: raise ImportError("Install emcee to generate unit test data.") from turbustat.tests._testing_data import dataset1, dataset2 # Wavelet Transform from turbustat.statistics import Wavelet_Distance, Wavelet wavelet_distance = \ Wavelet_Distance(dataset1["moment0"], dataset2["moment0"]).distance_metric() wavelet_val = wavelet_distance.wt1.values wavelet_slope = wavelet_distance.wt1.slope # Wavelet with a break wave_break = Wavelet(dataset1['moment0']).run(xhigh=7 * u.pix, brk=5.5 * u.pix) wavelet_slope_wbrk = wave_break.slope wavelet_brk_wbrk = wave_break.brk.value # MVC from turbustat.statistics import MVC_Distance, MVC mvc_distance = MVC_Distance(dataset1, dataset2).distance_metric() mvc = MVC(dataset1["centroid"], dataset1["moment0"], dataset1["linewidth"]) mvc.run() mvc_val = mvc.ps1D mvc_slope = mvc.slope mvc_slope2D = mvc.slope2D # Spatial Power Spectrum/ Bispectrum from turbustat.statistics import (PSpec_Distance, Bispectrum_Distance, Bispectrum, PowerSpectrum) pspec_distance = \ PSpec_Distance(dataset1["moment0"], dataset2["moment0"]).distance_metric() pspec = PowerSpectrum(dataset1['moment0']) pspec.run() pspec_val = pspec.ps1D pspec_slope = pspec.slope pspec_slope2D = pspec.slope2D bispec_distance = \ Bispectrum_Distance(dataset1["moment0"], dataset2["moment0"]).distance_metric() bispec_val = bispec_distance.bispec1.bicoherence azimuthal_slice = bispec_distance.bispec1.azimuthal_slice( 16, 10, value='bispectrum_logamp', bin_width=5 * u.deg) bispec_azim_bins = azimuthal_slice[16][0] bispec_azim_vals = azimuthal_slice[16][1] bispec_azim_stds = azimuthal_slice[16][2] bispec_meansub = Bispectrum(dataset1['moment0']) bispec_meansub.run(mean_subtract=True) bispec_val_meansub = bispec_meansub.bicoherence # Genus from turbustat.statistics import GenusDistance, Genus smooth_scales = np.linspace(1.0, 0.1 * min(dataset1["moment0"][0].shape), 5) genus_distance = \ GenusDistance(dataset1["moment0"], dataset2["moment0"], lowdens_percent=20, genus_kwargs=dict(match_kernel=True)).distance_metric() # The distance method requires standardizing the data. Make a # separate version that isn't genus = Genus(dataset1['moment0'], smoothing_radii=smooth_scales) genus.run(match_kernel=True) genus_val = genus.genus_stats # Delta-Variance from turbustat.statistics import DeltaVariance_Distance, DeltaVariance delvar_distance = \ DeltaVariance_Distance(dataset1["moment0"], dataset2["moment0"], weights1=dataset1["moment0_error"][0], weights2=dataset2["moment0_error"][0], delvar_kwargs=dict(xhigh=11 * u.pix)) delvar_distance.distance_metric() delvar = DeltaVariance(dataset1["moment0"], weights=dataset1['moment0_error'][0]).run(xhigh=11 * u.pix) delvar_val = delvar.delta_var delvar_slope = delvar.slope # Test with a break point delvar_wbrk = \ DeltaVariance(dataset1["moment0"], weights=dataset1['moment0_error'][0]).run(xhigh=11 * u.pix, brk=6 * u.pix) delvar_slope_wbrk = delvar_wbrk.slope delvar_brk = delvar_wbrk.brk.value # Change boundary conditions delvar_fill = \ DeltaVariance(dataset1["moment0"], weights=dataset1['moment0_error'][0]).run(xhigh=11 * u.pix, boundary='fill', nan_treatment='interpolate') delvar_fill_val = delvar_fill.delta_var delvar_fill_slope = delvar_fill.slope # VCA/VCS from turbustat.statistics import VCA_Distance, VCS_Distance, VCA vcs_distance = VCS_Distance(dataset1["cube"], dataset2["cube"], fit_kwargs=dict(high_cut=0.3 / u.pix, low_cut=3e-2 / u.pix)) vcs_distance.distance_metric() vcs_val = vcs_distance.vcs1.ps1D vcs_slopes = vcs_distance.vcs1.slope vca_distance = VCA_Distance(dataset1["cube"], dataset2["cube"]).distance_metric() vca = VCA(dataset1['cube']) vca.run() vca_val = vca.ps1D vca_slope = vca.slope vca_slope2D = vca.slope2D # Tsallis from turbustat.statistics import Tsallis tsallis_kwargs = {"sigma_clip": 5, "num_bins": 100} tsallis = Tsallis(dataset1['moment0'], lags=[1, 2, 4, 8, 16] * u.pix) tsallis.run(periodic=True, **tsallis_kwargs) tsallis_val = tsallis.tsallis_params tsallis_stderrs = tsallis.tsallis_stderrs tsallis_noper = Tsallis(dataset1['moment0'], lags=[1, 2, 4, 8, 16] * u.pix) tsallis_noper.run(periodic=False, num_bins=100) tsallis_val_noper = tsallis_noper.tsallis_params # High-order stats from turbustat.statistics import StatMoments_Distance, StatMoments moment_distance = \ StatMoments_Distance(dataset1["moment0"], dataset2["moment0"]).distance_metric() kurtosis_val = moment_distance.moments1.kurtosis_hist[1] skewness_val = moment_distance.moments1.skewness_hist[1] # Save a few from the non-distance version tester = StatMoments(dataset1["moment0"]) tester.run() kurtosis_nondist_val = tester.kurtosis_hist[1] skewness_nondist_val = tester.skewness_hist[1] # Non-periodic tester = StatMoments(dataset1["moment0"]) tester.run(periodic=False) kurtosis_nonper_val = tester.kurtosis_hist[1] skewness_nonper_val = tester.skewness_hist[1] # PCA from turbustat.statistics import PCA_Distance, PCA pca_distance = PCA_Distance(dataset1["cube"], dataset2["cube"]).distance_metric() pca = PCA(dataset1["cube"], distance=250 * u.pc) pca.run(mean_sub=True, eigen_cut_method='proportion', min_eigval=0.75, spatial_method='contour', spectral_method='walk-down', fit_method='odr', brunt_beamcorrect=False, spectral_output_unit=u.m / u.s) pca_val = pca.eigvals pca_spectral_widths = pca.spectral_width().value pca_spatial_widths = pca.spatial_width().value pca_fit_vals = { "index": pca.index, "gamma": pca.gamma, "intercept": pca.intercept().value, "sonic_length": pca.sonic_length()[0].value } # Now get those values using mcmc pca.run(mean_sub=True, eigen_cut_method='proportion', min_eigval=0.75, spatial_method='contour', spectral_method='walk-down', fit_method='bayes', brunt_beamcorrect=False, spectral_output_unit=u.m / u.s) pca_fit_vals["index_bayes"] = pca.index pca_fit_vals["gamma_bayes"] = pca.gamma pca_fit_vals["intercept_bayes"] = pca.intercept().value pca_fit_vals["sonic_length_bayes"] = pca.sonic_length()[0].value # Record the number of eigenvalues kept by the auto method pca.run(mean_sub=True, n_eigs='auto', min_eigval=0.001, eigen_cut_method='value', decomp_only=True) pca_fit_vals["n_eigs_value"] = pca.n_eigs # Now w/ the proportion of variance cut pca.run(mean_sub=True, n_eigs='auto', min_eigval=0.99, eigen_cut_method='proportion', decomp_only=True) pca_fit_vals["n_eigs_proportion"] = pca.n_eigs # SCF from turbustat.statistics import SCF_Distance, SCF scf_distance = SCF_Distance(dataset1["cube"], dataset2["cube"], size=11).distance_metric() scf = SCF(dataset1['cube'], size=11).run() scf_val = scf.scf_surface scf_spectrum = scf.scf_spectrum scf_slope = scf.slope scf_slope2D = scf.slope2D # Now run the SCF when the boundaries aren't continuous scf_distance_cut_bound = SCF_Distance(dataset1["cube"], dataset2["cube"], size=11, boundary='cut').distance_metric() scf_val_noncon_bound = scf_distance_cut_bound.scf1.scf_surface scf_fitlims = SCF(dataset1['cube'], size=11) scf_fitlims.run(boundary='continuous', xlow=1.5 * u.pix, xhigh=4.5 * u.pix) scf_slope_wlimits = scf_fitlims.slope scf_slope_wlimits_2D = scf_fitlims.slope2D # Cramer Statistic from turbustat.statistics import Cramer_Distance cramer_distance = Cramer_Distance( dataset1["cube"], dataset2["cube"], noise_value1=0.1, noise_value2=0.1).distance_metric(normalize=False) cramer_val = cramer_distance.data_matrix1 # Dendrograms from turbustat.statistics import Dendrogram_Distance, Dendrogram_Stats min_deltas = np.logspace(-1.5, 0.5, 40) dendro_distance = Dendrogram_Distance( dataset1["cube"], dataset2["cube"], min_deltas=min_deltas).distance_metric() dendrogram_val = dendro_distance.dendro1.numfeatures # With periodic boundaries dendro = Dendrogram_Stats(dataset1['cube'], min_deltas=min_deltas) dendro.run(periodic_bounds=True) dendrogram_periodic_val = dendro.numfeatures # PDF from turbustat.statistics import PDF_Distance pdf_distance = \ PDF_Distance(dataset1["moment0"], dataset2["moment0"], min_val1=0.05, min_val2=0.05, weights1=dataset1["moment0_error"][0]**-2., weights2=dataset2["moment0_error"][0]**-2., do_fit=False, normalization_type='standardize') pdf_distance.distance_metric() pdf_val = pdf_distance.PDF1.pdf pdf_ecdf = pdf_distance.PDF1.ecdf pdf_bins = pdf_distance.bins # Do a fitted version of the PDF pca pdf_fit_distance = \ PDF_Distance(dataset1["moment0"], dataset2["moment0"], min_val1=0.05, min_val2=0.05, do_fit=True, normalization_type=None) pdf_fit_distance.distance_metric() np.savez_compressed('checkVals', wavelet_val=wavelet_val, wavelet_slope=wavelet_slope, wavelet_slope_wbrk=wavelet_slope_wbrk, wavelet_brk_wbrk=wavelet_brk_wbrk, mvc_val=mvc_val, mvc_slope=mvc_slope, mvc_slope2D=mvc_slope2D, pspec_val=pspec_val, pspec_slope=pspec_slope, pspec_slope2D=pspec_slope2D, bispec_val=bispec_val, bispec_azim_bins=bispec_azim_bins, bispec_azim_vals=bispec_azim_vals, bispec_azim_stds=bispec_azim_stds, bispec_val_meansub=bispec_val_meansub, genus_val=genus_val, delvar_val=delvar_val, delvar_slope=delvar_slope, delvar_slope_wbrk=delvar_slope_wbrk, delvar_brk=delvar_brk, delvar_fill_val=delvar_fill_val, delvar_fill_slope=delvar_fill_slope, vcs_val=vcs_val, vcs_slopes=vcs_slopes, vca_val=vca_val, vca_slope=vca_slope, vca_slope2D=vca_slope2D, tsallis_val=tsallis_val, tsallis_stderrs=tsallis_stderrs, tsallis_val_noper=tsallis_val_noper, kurtosis_val=kurtosis_val, skewness_val=skewness_val, kurtosis_nondist_val=kurtosis_nondist_val, skewness_nondist_val=skewness_nondist_val, kurtosis_nonper_val=kurtosis_nonper_val, skewness_nonper_val=skewness_nonper_val, pca_val=pca_val, pca_fit_vals=pca_fit_vals, pca_spectral_widths=pca_spectral_widths, pca_spatial_widths=pca_spatial_widths, scf_val=scf_val, scf_slope_wlimits=scf_slope_wlimits, scf_slope_wlimits_2D=scf_slope_wlimits_2D, scf_val_noncon_bound=scf_val_noncon_bound, scf_spectrum=scf_spectrum, scf_slope=scf_slope, scf_slope2D=scf_slope2D, cramer_val=cramer_val, dendrogram_val=dendrogram_val, dendrogram_periodic_val=dendrogram_periodic_val, pdf_val=pdf_val, pdf_bins=pdf_bins, pdf_ecdf=pdf_ecdf) np.savez_compressed( 'computed_distances', mvc_distance=mvc_distance.distance, pca_distance=pca_distance.distance, vca_distance=vca_distance.distance, pspec_distance=pspec_distance.distance, scf_distance=scf_distance.distance, wavelet_distance=wavelet_distance.distance, delvar_curve_distance=delvar_distance.curve_distance, delvar_slope_distance=delvar_distance.slope_distance, # tsallis_distance=tsallis_distance.distance, kurtosis_distance=moment_distance.kurtosis_distance, skewness_distance=moment_distance.skewness_distance, cramer_distance=cramer_distance.distance, genus_distance=genus_distance.distance, vcs_distance=vcs_distance.distance, bispec_mean_distance=bispec_distance.mean_distance, bispec_surface_distance=bispec_distance.surface_distance, dendrohist_distance=dendro_distance.histogram_distance, dendronum_distance=dendro_distance.num_distance, pdf_hellinger_distance=pdf_distance.hellinger_distance, pdf_ks_distance=pdf_distance.ks_distance, pdf_lognorm_distance=pdf_fit_distance.lognormal_distance)
min_size=40 * u.AU**2, save_name=osjoin(fig_path, "genus_design4_physunits.png")) # MVC if run_mvc: from turbustat.statistics import MVC moment0 = fits.open( osjoin(data_path, "Design4_flatrho_0021_00_radmc_moment0.fits"))[0] centroid = fits.open( osjoin(data_path, "Design4_flatrho_0021_00_radmc_centroid.fits"))[0] lwidth = fits.open( osjoin(data_path, "Design4_flatrho_0021_00_radmc_linewidth.fits"))[0] mvc = MVC(centroid, moment0, lwidth) mvc.run(verbose=True, xunit=u.pix**-1, save_name=osjoin(fig_path, 'mvc_design4.png')) # With bounds mvc.run(verbose=True, xunit=u.pix**-1, low_cut=0.02 / u.pix, high_cut=0.1 / u.pix, save_name=osjoin(fig_path, 'mvc_design4_limitedfreq.png')) # With a break mvc = MVC(centroid, moment0, lwidth, distance=250 * u.pc) mvc.run(verbose=True, xunit=u.pix**-1,
wavelet_val = wavelet_distance.wt1.values wavelet_slope = wavelet_distance.wt1.slope # Wavelet with a break wave_break = Wavelet(dataset1['moment0']).run(xhigh=7 * u.pix, brk=5.5 * u.pix) wavelet_slope_wbrk = wave_break.slope wavelet_brk_wbrk = wave_break.brk.value # MVC from turbustat.statistics import MVC_Distance, MVC mvc_distance = MVC_Distance(dataset1, dataset2).distance_metric() mvc = MVC(dataset1["centroid"], dataset1["moment0"], dataset1["linewidth"]) mvc.run() mvc_val = mvc.ps1D mvc_slope = mvc.slope mvc_slope2D = mvc.slope2D # Spatial Power Spectrum/ Bispectrum from turbustat.statistics import (PSpec_Distance, Bispectrum_Distance, Bispectrum, PowerSpectrum) pspec_distance = \ PSpec_Distance(dataset1["moment0"], dataset2["moment0"]).distance_metric()