Facializing dengan Machine Learning

Contoh ini menunjukkan penggunaan berbagai algoritma pembelajaran mesin untuk melengkapi gambar. Tujuannya adalah untuk memprediksi bagian bawah wajah, mengingat bagian atasnya.

Kolom pertama gambar menunjukkan wajah asli. Kolom berikut menggambarkan bagaimana pohon (pohon sangat acak), k tetangga terdekat / metode K-nn, regresi linier dan RidgeCV (regresi ridge selesai) menyelesaikan bagian bawah wajah-wajah ini.

#   import numpy as np import matplotlib.pyplot as plt from sklearn.datasets import fetch_olivetti_faces from sklearn.utils.validation import check_random_state from sklearn.ensemble import ExtraTreesRegressor from sklearn.neighbors import KNeighborsRegressor from sklearn.linear_model import LinearRegression from sklearn.linear_model import RidgeCV #    data = fetch_olivetti_faces() targets = data.target data = data.images.reshape((len(data.images), -1)) train = data[targets < 30] test = data[targets >= 30] # Test on independent people #     n_faces = 5 rng = check_random_state(4) face_ids = rng.randint(test.shape[0], size=(n_faces, )) test = test[face_ids, :] n_pixels = data.shape[1] #    X_train = train[:, :(n_pixels + 1) // 2] #    y_train = train[:, n_pixels // 2:] X_test = test[:, :(n_pixels + 1) // 2] y_test = test[:, n_pixels // 2:] #   ESTIMATORS = { "Extra trees": ExtraTreesRegressor(n_estimators=10, max_features=32, random_state=0), "K-nn": KNeighborsRegressor(), "Linear regression": LinearRegression(), "Ridge": RidgeCV(), } y_test_predict = dict() for name, estimator in ESTIMATORS.items(): estimator.fit(X_train, y_train) y_test_predict[name] = estimator.predict(X_test) #  image_shape = (64, 64) n_cols = 1 + len(ESTIMATORS) plt.figure(figsize=(2. * n_cols, 2.26 * n_faces)) plt.suptitle("       ", size=16) for i in range(n_faces): true_face = np.hstack((X_test[i], y_test[i])) if i: sub = plt.subplot(n_faces, n_cols, i * n_cols + 1) else: sub = plt.subplot(n_faces, n_cols, i * n_cols + 1, title="true faces") sub.axis("off") sub.imshow(true_face.reshape(image_shape), cmap=plt.cm.gray, interpolation="nearest") for j, est in enumerate(sorted(ESTIMATORS)): completed_face = np.hstack((X_test[i], y_test_predict[est][i])) if i: sub = plt.subplot(n_faces, n_cols, i * n_cols + 2 + j) else: sub = plt.subplot(n_faces, n_cols, i * n_cols + 2 + j, title=est) sub.axis("off") sub.imshow(completed_face.reshape(image_shape), cmap=plt.cm.gray, interpolation="nearest") plt.show()