Esempio n. 1
0
 def test_plot_points_se2():
     points = SpecialEuclidean(n=2, point_type='vector').random_point(4)
     visu = visualization.SpecialEuclidean2(points, point_type='vector')
     ax = visu.set_ax()
     visu.draw(ax)
Esempio n. 2
0
def main():
    r"""Compute and visualize a geodesic regression on the SE(2).

    The generative model of the data is:
    :math:`Z = Exp_{\beta_0}(\beta_1.X)` and :math:`Y = Exp_Z(\epsilon)`
    where:
    - :math:`Exp` denotes the Riemannian exponential,
    - :math:`\beta_0` is called the intercept,
    - :math:`\beta_1` is called the coefficient,
    - :math:`\epsilon \sim N(0, 1)` is a standard Gaussian noise,
    - :math:`X` is the input, :math:`Y` is the target.
    """
    # Generate noise-free data
    n_samples = 20
    X = gs.random.normal(size=(n_samples, ))
    X -= gs.mean(X)

    intercept = SPACE.random_point()
    coef = SPACE.to_tangent(5.0 * gs.random.rand(3, 3), intercept)
    y = METRIC.exp(X[:, None, None] * coef[None], intercept)

    # Generate normal noise in the Lie algebra
    normal_noise = gs.random.normal(size=(n_samples, 3))
    normal_noise = SPACE.lie_algebra.matrix_representation(normal_noise)
    noise = SPACE.tangent_translation_map(y)(normal_noise) / gs.pi

    rss = gs.sum(METRIC.squared_norm(noise, y)) / n_samples

    # Add noise
    y = METRIC.exp(noise, y)

    # True noise level and R2
    estimator = FrechetMean(METRIC)
    estimator.fit(y)
    variance_ = variance(y, estimator.estimate_, metric=METRIC)
    r2 = 1 - rss / variance_

    # Fit geodesic regression
    gr = GeodesicRegression(
        SPACE,
        metric=METRIC,
        center_X=False,
        method="riemannian",
        max_iter=100,
        init_step_size=0.1,
        verbose=True,
        initialization="frechet",
    )
    gr.fit(X, y, compute_training_score=True)

    intercept_hat, beta_hat = gr.intercept_, gr.coef_

    # Measure Mean Squared Error
    mse_intercept = METRIC.squared_dist(intercept_hat, intercept)
    mse_beta = METRIC.squared_norm(
        METRIC.parallel_transport(beta_hat, intercept_hat,
                                  METRIC.log(intercept_hat, intercept)) - coef,
        intercept,
    )

    # Measure goodness of fit
    r2_hat = gr.training_score_

    print(f"MSE on the intercept: {mse_intercept:.2e}")
    print(f"MSE on the initial velocity beta: {mse_beta:.2e}")
    print(f"Determination coefficient: R^2={r2_hat:.2f}")
    print(f"True R^2: {r2:.2f}")

    # Plot
    fitted_data = gr.predict(X)
    fig = plt.figure(figsize=(8, 8))
    ax = fig.add_subplot(111)
    sphere_visu = visualization.SpecialEuclidean2()
    ax = sphere_visu.set_ax(ax=ax)

    path = METRIC.geodesic(initial_point=intercept_hat,
                           initial_tangent_vec=beta_hat)
    regressed_geodesic = path(gs.linspace(min(X), max(X), 100))

    sphere_visu.draw_points(ax, y, marker="o", c="black")
    sphere_visu.draw_points(ax, fitted_data, marker="o", c="gray")
    sphere_visu.draw_points(ax, gs.array([intercept]), marker="x", c="r")
    sphere_visu.draw_points(ax,
                            gs.array([intercept_hat]),
                            marker="o",
                            c="green")

    ax.plot(regressed_geodesic[:, 0, 2], regressed_geodesic[:, 1, 2], c="gray")
    plt.show()