""" ========================= Train error vs Test error ========================= Illustration of how the performance of an estimator on unseen data (test data) is not the same as the performance on training data. As the regularization increases the performance on train decreases while the performance on test is optimal within a range of values of the regularization parameter. The example with an Elastic-Net regression model and the performance is measured using the explained variance a.k.a. R^2. """ print(__doc__) # Author: Alexandre Gramfort # License: BSD 3 clause import numpy as np from sklearn import linear_model ############################################################################### # Generate sample data n_samples_train, n_samples_test, n_features = 75, 150, 500 np.random.seed(0) coef = np.random.randn(n_features) coef[50:] = 0.0 # only the top 10 features are impacting the model X = np.random.randn(n_samples_train + n_samples_test, n_features) y = np.dot(X, coef) # Split train and test data X_train, X_test = X[:n_samples_train], X[n_samples_train:] y_train, y_test = y[:n_samples_train], y[n_samples_train:] ############################################################################### # Compute train and test errors alphas = np.logspace(-5, 1, 60) enet = linear_model.ElasticNet(l1_ratio=0.7) train_errors = list() test_errors = list() for alpha in alphas: enet.set_params(alpha=alpha) enet.fit(X_train, y_train) train_errors.append(enet.score(X_train, y_train)) test_errors.append(enet.score(X_test, y_test)) i_alpha_optim = np.argmax(test_errors) alpha_optim = alphas[i_alpha_optim] print("Optimal regularization parameter : %s" % alpha_optim) # Estimate the coef_ on full data with optimal regularization parameter enet.set_params(alpha=alpha_optim) coef_ = enet.fit(X, y).coef_ ############################################################################### # Plot results functions import pylab as pl pl.subplot(2, 1, 1) pl.semilogx(alphas, train_errors, label='Train') pl.semilogx(alphas, test_errors, label='Test') pl.vlines(alpha_optim, pl.ylim()[0], np.max(test_errors), color='k', linewidth=3, label='Optimum on test') pl.legend(loc='lower left') pl.ylim([0, 1.2]) pl.xlabel('Regularization parameter') pl.ylabel('Performance') # Show estimated coef_ vs true coef pl.subplot(2, 1, 2) pl.plot(coef, label='True coef') pl.plot(coef_, label='Estimated coef') pl.legend() pl.subplots_adjust(0.09, 0.04, 0.94, 0.94, 0.26, 0.26) pl.show()