use_ae = False # hyperparameter for use ae architecture instead of simple NN random_state = 10 # if C is set to None use random_state # Generate sample data X_train, X_test, y_train, y_test = \ generate_data(n_train=n_train, n_test=n_test, n_features=n_features, contamination=contamination, random_state=42) # train DeepSVDD detector (Without-AE) clf_name = 'DeepSVDD' clf = DeepSVDD(use_ae=use_ae, epochs=5, contamination=contamination, random_state=random_state) clf.fit(X_train) # get the prediction labels and outlier scores of the training data y_train_pred = clf.labels_ # binary labels (0: inliers, 1: outliers) y_train_scores = clf.decision_scores_ # raw outlier scores # get the prediction on the test data y_test_pred = clf.predict(X_test) # outlier labels (0 or 1) y_test_scores = clf.decision_function(X_test) # outlier scores # evaluate and print the results print("\nOn Training Data:") evaluate_print(clf_name, y_train, y_train_scores) print("\nOn Test Data:") evaluate_print(clf_name, y_test, y_test_scores)
class TestDeepSVDD(unittest.TestCase): def setUp(self): self.n_train = 6000 self.n_test = 1000 self.n_features = 300 self.contamination = 0.1 self.roc_floor = 0.5 self.X_train, self.X_test, self.y_train, self.y_test = generate_data( n_train=self.n_train, n_test=self.n_test, n_features=self.n_features, contamination=self.contamination, random_state=42) self.clf = DeepSVDD(epochs=10, hidden_neurons=[64, 32], contamination=self.contamination, random_state=2021) self.clf_ae = DeepSVDD(epochs=5, use_ae=True, output_activation='relu', hidden_neurons=[16, 8, 4], contamination=self.contamination, preprocessing=False) self.clf.fit(self.X_train) self.clf_ae.fit(self.X_train) def test_parameters(self): assert (hasattr(self.clf, 'decision_scores_') and self.clf.decision_scores_ is not None) assert (hasattr(self.clf, 'labels_') and self.clf.labels_ is not None) assert (hasattr(self.clf, 'threshold_') and self.clf.threshold_ is not None) assert (hasattr(self.clf, '_mu') and self.clf._mu is not None) assert (hasattr(self.clf, '_sigma') and self.clf._sigma is not None) assert (hasattr(self.clf, 'model_') and self.clf.model_ is not None) def test_train_scores(self): assert_equal(len(self.clf.decision_scores_), self.X_train.shape[0]) def test_prediction_scores(self): pred_scores = self.clf.decision_function(self.X_test) # check score shapes assert_equal(pred_scores.shape[0], self.X_test.shape[0]) # check performance assert (roc_auc_score(self.y_test, pred_scores) >= self.roc_floor) def test_prediction_labels(self): pred_labels = self.clf.predict(self.X_test) assert_equal(pred_labels.shape, self.y_test.shape) def test_prediction_proba(self): pred_proba = self.clf.predict_proba(self.X_test) assert (pred_proba.min() >= 0) assert (pred_proba.max() <= 1) def test_prediction_proba_linear(self): pred_proba = self.clf.predict_proba(self.X_test, method='linear') assert (pred_proba.min() >= 0) assert (pred_proba.max() <= 1) def test_prediction_proba_unify(self): pred_proba = self.clf.predict_proba(self.X_test, method='unify') assert (pred_proba.min() >= 0) assert (pred_proba.max() <= 1) def test_prediction_proba_parameter(self): with assert_raises(ValueError): self.clf.predict_proba(self.X_test, method='something') def test_prediction_labels_confidence(self): pred_labels, confidence = self.clf.predict(self.X_test, return_confidence=True) assert_equal(pred_labels.shape, self.y_test.shape) assert_equal(confidence.shape, self.y_test.shape) assert (confidence.min() >= 0) assert (confidence.max() <= 1) def test_prediction_proba_linear_confidence(self): pred_proba, confidence = self.clf.predict_proba(self.X_test, method='linear', return_confidence=True) assert (pred_proba.min() >= 0) assert (pred_proba.max() <= 1) assert_equal(confidence.shape, self.y_test.shape) assert (confidence.min() >= 0) assert (confidence.max() <= 1) def test_fit_predict(self): pred_labels = self.clf.fit_predict(self.X_train) assert_equal(pred_labels.shape, self.y_train.shape) def test_fit_predict_score(self): self.clf.fit_predict_score(self.X_test, self.y_test) self.clf.fit_predict_score(self.X_test, self.y_test, scoring='roc_auc_score') self.clf.fit_predict_score(self.X_test, self.y_test, scoring='prc_n_score') with assert_raises(NotImplementedError): self.clf.fit_predict_score(self.X_test, self.y_test, scoring='something') def test_model_clone(self): clone_clf = clone(self.clf) clone_clf = clone(self.clf_ae) def tearDown(self): pass