コード例 #1
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_pipeline_with_nearest_neighbors_transformer():
    # Test chaining NearestNeighborsTransformer and Isomap with
    # neighbors_algorithm='precomputed'
    algorithm = 'auto'
    n_neighbors = 10

    X, _ = datasets.make_blobs(random_state=0)
    X2, _ = datasets.make_blobs(random_state=1)

    # compare the chained version and the compact version
    est_chain = pipeline.make_pipeline(
        neighbors.KNeighborsTransformer(n_neighbors=n_neighbors,
                                        algorithm=algorithm,
                                        mode='distance'),
        manifold.Isomap(n_neighbors=n_neighbors, metric='precomputed'))
    est_compact = manifold.Isomap(n_neighbors=n_neighbors,
                                  neighbors_algorithm=algorithm)

    Xt_chain = est_chain.fit_transform(X)
    Xt_compact = est_compact.fit_transform(X)
    assert_array_almost_equal(Xt_chain, Xt_compact)

    Xt_chain = est_chain.transform(X2)
    Xt_compact = est_compact.transform(X2)
    assert_array_almost_equal(Xt_chain, Xt_compact)
コード例 #2
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_isomap_clone_bug():
    # regression test for bug reported in #6062
    model = manifold.Isomap()
    for n_neighbors in [10, 15, 20]:
        model.set_params(n_neighbors=n_neighbors)
        model.fit(np.random.rand(50, 2))
        assert (model.nbrs_.n_neighbors == n_neighbors)
コード例 #3
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_pipeline():
    # check that Isomap works fine as a transformer in a Pipeline
    # only checks that no error is raised.
    # TODO check that it actually does something useful
    X, y = datasets.make_blobs(random_state=0)
    clf = pipeline.Pipeline([('isomap', manifold.Isomap()),
                             ('clf', neighbors.KNeighborsClassifier())])
    clf.fit(X, y)
    assert .9 < clf.score(X, y)
コード例 #4
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_sparse_input():
    X = sparse_rand(100, 3, density=0.1, format='csr')

    # Should not error
    for eigen_solver in eigen_solvers:
        for path_method in path_methods:
            clf = manifold.Isomap(n_components=2,
                                  eigen_solver=eigen_solver,
                                  path_method=path_method)
            clf.fit(X)
コード例 #5
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_different_metric():
    # Test that the metric parameters work correctly, and default to euclidean
    def custom_metric(x1, x2):
        return np.sqrt(np.sum(x1**2 + x2**2))

    # metric, p, is_euclidean
    metrics = [('euclidean', 2, True), ('manhattan', 1, False),
               ('minkowski', 1, False), ('minkowski', 2, True),
               (custom_metric, 2, False)]

    X, _ = datasets.make_blobs(random_state=0)
    reference = manifold.Isomap().fit_transform(X)

    for metric, p, is_euclidean in metrics:
        embedding = manifold.Isomap(metric=metric, p=p).fit_transform(X)

        if is_euclidean:
            assert_array_almost_equal(embedding, reference)
        else:
            with pytest.raises(AssertionError, match='not almost equal'):
                assert_array_almost_equal(embedding, reference)
コード例 #6
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_transform():
    n_samples = 200
    n_components = 10
    noise_scale = 0.01

    # Create S-curve dataset
    X, y = datasets.make_s_curve(n_samples, random_state=0)

    # Compute isomap embedding
    iso = manifold.Isomap(n_components, 2)
    X_iso = iso.fit_transform(X)

    # Re-embed a noisy version of the points
    rng = np.random.RandomState(0)
    noise = noise_scale * rng.randn(*X.shape)
    X_iso2 = iso.transform(X + noise)

    # Make sure the rms error on re-embedding is comparable to noise_scale
    assert np.sqrt(np.mean((X_iso - X_iso2)**2)) < 2 * noise_scale
コード例 #7
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_isomap_reconstruction_error():
    # Same setup as in test_isomap_simple_grid, with an added dimension
    N_per_side = 5
    Npts = N_per_side**2
    n_neighbors = Npts - 1

    # grid of equidistant points in 2D, n_components = n_dim
    X = np.array(list(product(range(N_per_side), repeat=2)))

    # add noise in a third dimension
    rng = np.random.RandomState(0)
    noise = 0.1 * rng.randn(Npts, 1)
    X = np.concatenate((X, noise), 1)

    # compute input kernel
    G = neighbors.kneighbors_graph(X, n_neighbors, mode='distance').toarray()

    centerer = preprocessing.KernelCenterer()
    K = centerer.fit_transform(-0.5 * G**2)

    for eigen_solver in eigen_solvers:
        for path_method in path_methods:
            clf = manifold.Isomap(n_neighbors=n_neighbors,
                                  n_components=2,
                                  eigen_solver=eigen_solver,
                                  path_method=path_method)
            clf.fit(X)

            # compute output kernel
            G_iso = neighbors.kneighbors_graph(clf.embedding_,
                                               n_neighbors,
                                               mode='distance').toarray()

            K_iso = centerer.fit_transform(-0.5 * G_iso**2)

            # make sure error agrees
            reconstruction_error = np.linalg.norm(K - K_iso) / Npts
            assert_almost_equal(reconstruction_error,
                                clf.reconstruction_error())
コード例 #8
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ファイル: test_isomap.py プロジェクト: ivohashamov/hackaTUM
def test_isomap_simple_grid():
    # Isomap should preserve distances when all neighbors are used
    N_per_side = 5
    Npts = N_per_side**2
    n_neighbors = Npts - 1

    # grid of equidistant points in 2D, n_components = n_dim
    X = np.array(list(product(range(N_per_side), repeat=2)))

    # distances from each point to all others
    G = neighbors.kneighbors_graph(X, n_neighbors, mode='distance').toarray()

    for eigen_solver in eigen_solvers:
        for path_method in path_methods:
            clf = manifold.Isomap(n_neighbors=n_neighbors,
                                  n_components=2,
                                  eigen_solver=eigen_solver,
                                  path_method=path_method)
            clf.fit(X)

            G_iso = neighbors.kneighbors_graph(clf.embedding_,
                                               n_neighbors,
                                               mode='distance').toarray()
            assert_array_almost_equal(G, G_iso)