def computeWeights(self, sources, interferers, R_n, epsilon=5e-3): dist_mat = pra.distance(self.R, sources) s_time = dist_mat / pra.c s_dmp = 1. / (4 * np.pi * dist_mat) dist_mat = pra.distance(self.R, interferers) i_time = dist_mat / pra.c i_dmp = 1. / (4 * np.pi * dist_mat) # compute offset needed for decay of sinc by epsilon offset = np.maximum(s_dmp.max(), i_dmp.max()) / (np.pi * self.Fs * epsilon) t_min = np.minimum(s_time.min(), i_time.min()) t_max = np.maximum(s_time.max(), i_time.max()) # adjust timing s_time -= t_min - offset i_time -= t_min - offset Lh = np.ceil((t_max - t_min + 2 * offset) * float(self.Fs)) # the channel matrix K = sources.shape[1] Lg = self.Lg off = (Lg - Lh) / 2 L = self.Lg + Lh - 1 H = np.zeros((Lg * self.M, 2 * L)) As = np.zeros((Lg * self.M, K)) for r in np.arange(self.M): # build constraint matrix hs = pra.lowPassDirac(s_time[r, :, np.newaxis], s_dmp[r, :, np.newaxis], self.Fs, Lh)[:, ::-1] As[r * Lg + off:r * Lg + Lh + off, :] = hs.T # build interferer RIR matrix hx = pra.lowPassDirac(s_time[r, :, np.newaxis], s_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, :L] = pra.convmtx(hx, Lg).T # build interferer RIR matrix hq = pra.lowPassDirac(i_time[r, :, np.newaxis], i_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, L:] = pra.convmtx(hq, Lg).T ones = np.ones((K, 1)) # We first assume the sample are uncorrelated K_x = np.dot(H[:, :L], H[:, :L].T) K_nq = np.dot(H[:, L:], H[:, L:].T) + R_n # Compute the TD filters K_nq_inv = np.linalg.inv(K_x + K_nq) C = np.dot(K_nq_inv, As) B = np.linalg.inv(np.dot(As.T, C)) g_val = np.dot(C, np.dot(B, ones)) self.filters = g_val.reshape((self.M, Lg)) import matplotlib.pyplot as plt plt.figure() plt.subplot(3, 1, 1) plt.plot(np.arange(L) / float(self.Fs), np.dot(H[:, :L].T, g_val)) plt.plot(np.arange(L) / float(self.Fs), np.dot(H[:, L:].T, g_val)) plt.legend(('Channel of desired source', 'Channel of interferer')) plt.subplot(3, 1, 2) for m in np.arange(self.M): plt.plot(np.arange(Lh) / float(self.Fs), H[m * Lg, :Lh]) plt.subplot(3, 1, 3) for m in np.arange(self.M): plt.plot(np.arange(Lh) / float(self.Fs), H[m * Lg, L:L + Lh]) # compute and return SNR A = np.dot(g_val.T, H[:, :L]) num = np.dot(A, A.T) denom = np.dot(np.dot(g_val.T, K_nq), g_val) return num / denom
def computeWeights(self, sources, interferers, R_n, delay=None, epsilon=5e-3): dist_mat = pra.distance(self.R, sources) s_time = dist_mat / pra.c s_dmp = 1. / (4 * np.pi * dist_mat) dist_mat = pra.distance(self.R, interferers) i_time = dist_mat / pra.c i_dmp = 1. / (4 * np.pi * dist_mat) # compute offset needed for decay of sinc by epsilon offset = np.maximum(s_dmp.max(), i_dmp.max()) / (np.pi * self.Fs * epsilon) t_min = np.minimum(s_time.min(), i_time.min()) t_max = np.maximum(s_time.max(), i_time.max()) # adjust timing s_time -= t_min - offset i_time -= t_min - offset Lh = int((t_max - t_min + 2 * offset) * float(self.Fs)) # the channel matrix K = sources.shape[1] Lg = self.Lg off = (Lg - Lh) / 2 L = self.Lg + Lh - 1 H = np.zeros((Lg * self.M, 2 * L)) for r in np.arange(self.M): # build interferer RIR matrix hx = pra.lowPassDirac(s_time[r, :, np.newaxis], s_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, :L] = pra.convmtx(hx, Lg).T # build interferer RIR matrix hq = pra.lowPassDirac(i_time[r, :, np.newaxis], i_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, L:] = pra.convmtx(hq, Lg).T # We first assume the sample are uncorrelated K_s = np.dot(H[:, :L], H[:, :L].T) K_nq = np.dot(H[:, L:], H[:, L:].T) + R_n # Compute TD filters using generalized Rayleigh coefficient maximization SINR, v = la.eigh(K_s, b=K_nq, eigvals=(self.M * Lg - 1, self.M * Lg - 1), overwrite_a=True, overwrite_b=True, check_finite=False) g_val = np.real(v[:, 0]) self.filters = g_val.reshape((self.M, Lg)) ''' import matplotlib.pyplot as plt plt.figure() plt.plot(np.arange(L)/float(self.Fs), np.dot(H[:,:L].T, g_val)) plt.plot(np.arange(L)/float(self.Fs), np.dot(H[:,L:].T, g_val)) plt.legend(('Channel of desired source','Channel of interferer')) ''' # compute and return SNR return SINR[0]
def computeWeights(self, sources, interferers, R_n, delay=0.03, epsilon=5e-3): dist_mat = pra.distance(self.R, sources) s_time = dist_mat / pra.c s_dmp = 1. / (4 * np.pi * dist_mat) dist_mat = pra.distance(self.R, interferers) i_time = dist_mat / pra.c i_dmp = 1. / (4 * np.pi * dist_mat) # compute offset needed for decay of sinc by epsilon offset = np.maximum(s_dmp.max(), i_dmp.max()) / (np.pi * self.Fs * epsilon) t_min = np.minimum(s_time.min(), i_time.min()) t_max = np.maximum(s_time.max(), i_time.max()) # adjust timing s_time -= t_min - offset i_time -= t_min - offset Lh = int((t_max - t_min + 2 * offset) * float(self.Fs)) # the channel matrix K = sources.shape[1] Lg = self.Lg off = (Lg - Lh) / 2 L = self.Lg + Lh - 1 H = np.zeros((Lg * self.M, 2 * L)) for r in np.arange(self.M): # build interferer RIR matrix hx = pra.lowPassDirac(s_time[r, :, np.newaxis], s_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, :L] = pra.convmtx(hx, Lg).T # build interferer RIR matrix hq = pra.lowPassDirac(i_time[r, :, np.newaxis], i_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, L:] = pra.convmtx(hq, Lg).T # We first assume the sample are uncorrelated K_nq = np.dot(H[:, L:], H[:, L:].T) + R_n # constraint kappa = int(delay * self.Fs) kappa = (Lh + Lg) / 2 A = H[:, :L] b = np.zeros((L, 1)) b[kappa, 0] = 1 # filter computation C = la.cho_factor(K_nq, overwrite_a=True, check_finite=False) B = la.cho_solve(C, A) D = np.dot(A.T, B) C = la.cho_factor(D, overwrite_a=True, check_finite=False) x = la.cho_solve(C, b) g_val = np.dot(B, x) # reshape and store self.filters = g_val.reshape((self.M, self.Lg)) ''' import matplotlib.pyplot as plt plt.figure() plt.plot(np.arange(L)/float(self.Fs), np.dot(H[:,:L].T, g_val)) plt.plot(np.arange(L)/float(self.Fs), np.dot(H[:,L:].T, g_val)) plt.legend(('Channel of desired source','Channel of interferer')) ''' # compute and return SNR A = np.dot(g_val.T, H[:, :L]) num = np.dot(A, A.T) denom = np.dot(np.dot(g_val.T, K_nq), g_val) return num / denom
def computeWeights(self, sources, interferers, R_n, delay=0.03, epsilon=5e-3): dist_mat = pra.distance(self.R, sources) s_time = dist_mat / pra.c s_dmp = 1. / (4 * np.pi * dist_mat) dist_mat = pra.distance(self.R, interferers) i_time = dist_mat / pra.c i_dmp = 1. / (4 * np.pi * dist_mat) # compute offset needed for decay of sinc by epsilon offset = np.maximum(s_dmp.max(), i_dmp.max()) / (np.pi * self.Fs * epsilon) t_min = np.minimum(s_time.min(), i_time.min()) t_max = np.maximum(s_time.max(), i_time.max()) # adjust timing s_time -= t_min - offset i_time -= t_min - offset Lh = int((t_max - t_min + 2 * offset) * float(self.Fs)) # the channel matrix K = sources.shape[1] Lg = self.Lg off = (Lg - Lh) / 2 L = self.Lg + Lh - 1 H = np.zeros((Lg * self.M, 2 * L)) for r in np.arange(self.M): # build interferer RIR matrix hx = pra.lowPassDirac(s_time[r, :, np.newaxis], s_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, :L] = pra.convmtx(hx, Lg).T # build interferer RIR matrix hq = pra.lowPassDirac(i_time[r, :, np.newaxis], i_dmp[r, :, np.newaxis], self.Fs, Lh).sum(axis=0) H[r * Lg:(r + 1) * Lg, L:] = pra.convmtx(hq, Lg).T # Delay of the system in samples kappa = int(delay * self.Fs) precedence = int(0.030 * self.Fs) # the constraint n = np.minimum(L, kappa + precedence) Hnc = H[:, :kappa] Hpr = H[:, kappa:n] Hc = H[:, n:L] A = np.dot(Hpr, Hpr.T) B = np.dot(Hnc, Hnc.T) + np.dot(Hc, Hc.T) + np.dot( H[:, L:], H[:, L:].T) + R_n # solve the problem SINR, v = la.eigh(A, b=B, eigvals=(self.M * Lg - 1, self.M * Lg - 1), overwrite_a=True, overwrite_b=True, check_finite=False) g_val = np.real(v[:, 0]) # reshape and store self.filters = g_val.reshape((self.M, self.Lg)) import matplotlib.pyplot as plt plt.figure() plt.subplot(3, 1, 1) plt.plot(np.arange(L) / float(self.Fs), np.dot(H[:, :L].T, g_val)) plt.plot(np.arange(L) / float(self.Fs), np.dot(H[:, L:].T, g_val)) plt.legend(('Channel of desired source', 'Channel of interferer')) plt.subplot(3, 1, 2) plt.plot(np.abs(np.fft.rfft(np.dot(H[:, :L].T, g_val)))) plt.subplot(3, 1, 3) for m in np.arange(self.M): plt.plot(np.abs(np.fft.rfft(H[m * self.Lg, :L]))) # compute and return SNR return SINR[0]