def main(): # OPTICS demo with SDRs radius = 10.0 neighbors = 2 epsilon_cutoff = 0.3 file_path = os.path.join( os.getcwd(), 'htm_traces', 'binary_ampl=10.0_mean=0.0_noise=0.0_' 'sp=True_tm=True_tp=False_SDRClassifier.csv') sdrs, cluster_ids = load_sdrs(file_path) (cluster_assignments, sdr_slices) = find_cluster_assignments(sdrs, cluster_ids, ignore_noise=True) sdr_cluster_centroids = get_sdr_cluster_centroids(sdr_slices) # Project SDRs in 2D for visualization purposes distance_mat = distance_matrix(sdr_cluster_centroids, euclidian_distance) sdr_projections = project_clusters_2D(distance_mat, method='mds') # OPTICS SDR results sample_sdr = sdr_projections # or: sdr_cluster_centroids ordering_sdr, clusters_sdr, noise_sdr = analyze(sample_sdr, radius, neighbors) # Plot OPTICS results sample_sdr = sdr_projections plot_results(sample_sdr, ordering_sdr, clusters_sdr, noise_sdr, 'SDR', epsilon_cutoff) # Plot SDR 2D projections title = '2d_projections' output_file = '%s' % ('%s.png' % title) plt = plot_2D_projections(title, output_file, cluster_assignments, sdr_projections) plt.show() # OPTICS demo with 2D vectors radius = 2.0 neighbors = 2 epsilon_cutoff = 0.5 sample_2d = read_sample( FCPS_SAMPLES.SAMPLE_LSUN) # or: gaussian_clusters(3) ordering_2d, clusters_2d, noise_2d = analyze(sample_2d, radius, neighbors) plot_results(sample_2d, ordering_2d, clusters_2d, noise_2d, '2D', epsilon_cutoff) # Plot input data and clustering structure ordering_visualizer.show_ordering_diagram(ordering_sdr) ordering_visualizer.show_ordering_diagram(ordering_2d)
def plot_inter_sequence_distances(output_dir, plot_id, distance_func, sdrs, cluster_ids, ignore_noise): cluster_assignments, sdr_slices = find_cluster_assignments( sdrs, cluster_ids, ignore_noise) distance_mat = cluster_distance_matrix(sdr_slices, distance_func) title = 'distance_matrix_%s' % plot_id output_file = '%s/%s' % (output_dir, '%s.png' % title) plot_distance_mat(distance_mat, title, output_file) projections = project_clusters_2D(distance_mat, method='mds') title = '2d_projections_%s' % plot_id output_file = '%s/%s' % (output_dir, '%s.png' % title) plot_2D_projections(title, output_file, cluster_assignments, projections)
def main(): # OPTICS demo with SDRs radius = 10.0 neighbors = 2 epsilon_cutoff = 0.3 file_path = os.path.join(os.getcwd(), 'htm_traces', 'binary_ampl=10.0_mean=0.0_noise=0.0_' 'sp=True_tm=True_tp=False_SDRClassifier.csv') sdrs, cluster_ids = load_sdrs(file_path) (cluster_assignments, sdr_slices) = find_cluster_assignments(sdrs, cluster_ids, ignore_noise=True) sdr_cluster_centroids = get_sdr_cluster_centroids(sdr_slices) # Project SDRs in 2D for visualization purposes distance_mat = distance_matrix(sdr_cluster_centroids, euclidian_distance) sdr_projections = project_clusters_2D(distance_mat, method='mds') # OPTICS SDR results sample_sdr = sdr_projections # or: sdr_cluster_centroids ordering_sdr, clusters_sdr, noise_sdr = analyze(sample_sdr, radius, neighbors) # Plot OPTICS results sample_sdr = sdr_projections plot_results(sample_sdr, ordering_sdr, clusters_sdr, noise_sdr, 'SDR', epsilon_cutoff) # Plot SDR 2D projections title = '2d_projections' output_file = '%s' % ('%s.png' % title) plt = plot_2D_projections(title, output_file, cluster_assignments, sdr_projections) plt.show() # OPTICS demo with 2D vectors radius = 2.0 neighbors = 2 epsilon_cutoff = 0.5 sample_2d = read_sample(FCPS_SAMPLES.SAMPLE_LSUN) # or: gaussian_clusters(3) ordering_2d, clusters_2d, noise_2d = analyze(sample_2d, radius, neighbors) plot_results(sample_2d, ordering_2d, clusters_2d, noise_2d, '2D', epsilon_cutoff) # Plot input data and clustering structure ordering_visualizer.show_ordering_diagram(ordering_sdr) ordering_visualizer.show_ordering_diagram(ordering_2d)
def plot_inter_sequence_distances(output_dir, plot_id, distance_func, sdrs, cluster_ids, ignore_noise): cluster_assignments, sdr_slices = find_cluster_assignments(sdrs, cluster_ids, ignore_noise) distance_mat = cluster_distance_matrix(sdr_slices, distance_func) title = 'distance_matrix_%s' % plot_id output_file = '%s/%s' % (output_dir, '%s.png' % title) plot_distance_mat(distance_mat, title, output_file) projections = project_clusters_2D(distance_mat, method='mds') title = '2d_projections_%s' % plot_id output_file = '%s/%s' % (output_dir, '%s.png' % title) plot_2D_projections(title, output_file, cluster_assignments, projections)