import numpy as np import math from numpy import random import cv2 def make_gaussians(cluster_n, img_size): points = [] ref_distrs = [] for i in xrange(cluster_n): mean = (0.1 + 0.8*random.rand(2)) * img_size a = (random.rand(2, 2)-0.5)*img_size*0.1 cov = np.dot(a.T, a) + img_size*0.05*np.eye(2) n = 100 + random.randint(900) pts = random.multivariate_normal(mean, cov, n) points.append( pts ) ref_distrs.append( (mean, cov) ) points = np.float32( np.vstack(points) ) return points, ref_distrs def draw_gaussain(img, mean, cov, color): x, y = np.int32(mean) w, u, vt = cv2.SVDecomp(cov) ang = np.arctan2(u[1, 0], u[0, 0])*(180/math.pi) s1, s2 = np.sqrt(w)*3.0 cv2.ellipse(img, (x, y), (s1, s2), ang, 0, 360, color, 1, cv2.CV_AA) if __name__ == '__main__': cluster_n = 5 img_size = 512 print 'press any key to update distributions, ESC - exit\n' while True: print 'sampling distributions...' points, ref_distrs = make_gaussians(cluster_n, img_size) print 'EM (opencv) ...' em = cv2.EM(points, params = dict( nclusters = cluster_n, cov_mat_type = cv2.EM_COV_MAT_GENERIC) ) means = em.getMeans() covs = np.zeros((cluster_n, 2, 2), np.float32) covs = em.getCovs(covs) # FIXME found_distrs = zip(means, covs) print 'ready!\n' img = np.zeros((img_size, img_size, 3), np.uint8) for x, y in np.int32(points): cv2.circle(img, (x, y), 1, (255, 255, 255), -1) for m, cov in ref_distrs: draw_gaussain(img, m, cov, (0, 255, 0)) for m, cov in found_distrs: draw_gaussain(img, m, cov, (0, 0, 255)) cv2.imshow('gaussian mixture', img) ch = cv2.waitKey(0) if ch == 27: break