Note
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In this example we see how to robustly fit a linear model to faulty data using the RANSAC algorithm.
Out:
Estimated coefficients (true, linear regression, RANSAC): 82.1903908407869 [54.17236387] [82.08533159]
import numpy as np from matplotlib import pyplot as plt from sklearn import linear_model, datasets n_samples = 1000 n_outliers = 50 X, y, coef = datasets.make_regression(n_samples=n_samples, n_features=1, n_informative=1, noise=10, coef=True, random_state=0) # Add outlier data np.random.seed(0) X[:n_outliers] = 3 + 0.5 * np.random.normal(size=(n_outliers, 1)) y[:n_outliers] = -3 + 10 * np.random.normal(size=n_outliers) # Fit line using all data lr = linear_model.LinearRegression() lr.fit(X, y) # Robustly fit linear model with RANSAC algorithm ransac = linear_model.RANSACRegressor() ransac.fit(X, y) inlier_mask = ransac.inlier_mask_ outlier_mask = np.logical_not(inlier_mask) # Predict data of estimated models line_X = np.arange(X.min(), X.max())[:, np.newaxis] line_y = lr.predict(line_X) line_y_ransac = ransac.predict(line_X) # Compare estimated coefficients print("Estimated coefficients (true, linear regression, RANSAC):") print(coef, lr.coef_, ransac.estimator_.coef_) lw = 2 plt.scatter(X[inlier_mask], y[inlier_mask], color='yellowgreen', marker='.', label='Inliers') plt.scatter(X[outlier_mask], y[outlier_mask], color='gold', marker='.', label='Outliers') plt.plot(line_X, line_y, color='navy', linewidth=lw, label='Linear regressor') plt.plot(line_X, line_y_ransac, color='cornflowerblue', linewidth=lw, label='RANSAC regressor') plt.legend(loc='lower right') plt.xlabel("Input") plt.ylabel("Response") plt.show()
Total running time of the script: ( 0 minutes 0.048 seconds)
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http://scikit-learn.org/stable/auto_examples/linear_model/plot_ransac.html