def test_log_post_pred_k(): np.random.seed(1) # Generate data D = 10 N_1 = 10 N_2 = 5 N_3 = 5 X = 5 * np.random.rand(N_1 + N_2 + N_3, D) - 1 X_1 = X[:N_1] X_2 = X[N_1:N_1 + N_2] X_3 = X[N_1 + N_2:] # Prior var = 1 * np.random.rand(D) mu_0 = 5 * np.random.rand(D) - 2 var_0 = 2 * np.random.rand(D) prior = FixedVarPrior(var, mu_0, var_0) precision = 1. / var precision_0 = 1. / var_0 # Setup GMM assignments = np.concatenate( [np.zeros(N_1), np.ones(N_2), 2 * np.ones(N_3)]) gmm = GaussianComponentsFixedVar(X, prior, assignments=assignments) # Remove everything from component 2 (additional check) for i in range(N_1, N_1 + N_2): gmm.del_item(i) # Calculate posterior for first component by hand x_1 = X_1[0] precision_N_1 = precision_0 + N_1 * precision mu_N_1 = (mu_0 * precision_0 + precision * N_1 * X_1.mean(axis=0)) / precision_N_1 precision_pred = 1. / (1. / precision_N_1 + 1. / precision) expected_posterior = np.sum([ log_norm_pdf(x_1[i], mu_N_1[i], 1. / precision_pred[i]) for i in range(len(x_1)) ]) npt.assert_almost_equal(gmm.log_post_pred_k(0, 0), expected_posterior) # Calculate posterior for second component by hand x_3 = X_3[0] precision_N_3 = precision_0 + N_3 * precision mu_N_3 = (mu_0 * precision_0 + precision * N_3 * X_3.mean(axis=0)) / precision_N_3 precision_pred = 1. / (1. / precision_N_3 + 1. / precision) expected_posterior = np.sum([ log_norm_pdf(x_3[i], mu_N_3[i], 1. / precision_pred[i]) for i in range(len(x_3)) ]) npt.assert_almost_equal(gmm.log_post_pred_k(N_1 + N_2, 1), expected_posterior)
def test_log_post_pred_k(): np.random.seed(1) # Generate data D = 10 N_1 = 10 N_2 = 5 N_3 = 5 X = 5*np.random.rand(N_1 + N_2 + N_3, D) - 1 X_1 = X[:N_1] X_2 = X[N_1:N_1 + N_2] X_3 = X[N_1 + N_2:] # Prior var = 1*np.random.rand(D) mu_0 = 5*np.random.rand(D) - 2 var_0 = 2*np.random.rand(D) prior = FixedVarPrior(var, mu_0, var_0) precision = 1./var precision_0 = 1./var_0 # Setup GMM assignments = np.concatenate([np.zeros(N_1), np.ones(N_2), 2*np.ones(N_3)]) gmm = GaussianComponentsFixedVar(X, prior, assignments=assignments) # Remove everything from component 2 (additional check) for i in range(N_1, N_1 + N_2): gmm.del_item(i) # Calculate posterior for first component by hand x_1 = X_1[0] precision_N_1 = precision_0 + N_1*precision mu_N_1 = (mu_0 * precision_0 + precision*N_1*X_1.mean(axis=0)) / precision_N_1 precision_pred = 1./(1./precision_N_1 + 1./precision) expected_posterior = np.sum( [log_norm_pdf(x_1[i], mu_N_1[i], 1./precision_pred[i]) for i in range(len(x_1))] ) npt.assert_almost_equal(gmm.log_post_pred_k(0, 0), expected_posterior) # Calculate posterior for second component by hand x_3 = X_3[0] precision_N_3 = precision_0 + N_3*precision mu_N_3 = (mu_0 * precision_0 + precision*N_3*X_3.mean(axis=0)) / precision_N_3 precision_pred = 1./(1./precision_N_3 + 1./precision) expected_posterior = np.sum( [log_norm_pdf(x_3[i], mu_N_3[i], 1./precision_pred[i]) for i in range(len(x_3))] ) npt.assert_almost_equal(gmm.log_post_pred_k(N_1 + N_2, 1), expected_posterior)
def test_log_prod_norm(): np.random.seed(1) # Prior D = 10 var = 1*np.random.rand(D) mu_0 = 5*np.random.rand(D) - 2 var_0 = 2*np.random.rand(D) prior = FixedVarPrior(var, mu_0, var_0) # GMM will be used to access `_log_prod_norm` x = 3*np.random.rand(D) + 4 gmm = GaussianComponentsFixedVar(np.array([x]), prior) expected_prior = np.sum([log_norm_pdf(x[i], mu_0[i], var_0[i]) for i in range(len(x))]) npt.assert_almost_equal(gmm.log_prior(0), expected_prior)
def test_log_prod_norm(): np.random.seed(1) # Prior D = 10 var = 1 * np.random.rand(D) mu_0 = 5 * np.random.rand(D) - 2 var_0 = 2 * np.random.rand(D) prior = FixedVarPrior(var, mu_0, var_0) # GMM will be used to access `_log_prod_norm` x = 3 * np.random.rand(D) + 4 gmm = GaussianComponentsFixedVar(np.array([x]), prior) expected_prior = np.sum( [log_norm_pdf(x[i], mu_0[i], var_0[i]) for i in range(len(x))]) npt.assert_almost_equal(gmm.log_prior(0), expected_prior)