def sample_plane(plane, n, width, noise = 0):
  plane_repok(plane)
  e1, e2, _ = np.eye(3)
  v1 = e1 if (plane[0] == 0 and plane[1] == 0) else ut.normalized(np.array([-plane[1], plane[0], 0], 'd'))
  v2 = ut.normalized(np.cross(plane[:3], v1))
  #print 'dot', np.dot(v1, plane[:3]),   np.dot(v2, plane[:3])
  #print 'sample', np.sum(np.dot(np.array([v1, v2]).T, np.random.uniform(-width/2, width/2, (2, n))).T * plane[:3], 1)
  center = -plane[3]*plane[:3]
  #print 'dot2', np.dot(center, plane[:3]) + plane[3], plane
  pts = np.dot(np.array([v1, v2]).T, np.random.uniform(-width/2, width/2, (2, n))).T + center
  #print 'ins', len(plane_inliers(plane, pts, 0.05))
  pts += np.random.randn(*pts.shape)*noise
  return pts
Esempio n. 2
0
def parallel_axes(plane):
    x, y, z = plane[:3]
    a = np.array
    if x == 0:
        u = a([0., z, -y])
    elif y == 0:
        u = a([z, 0., -x])
    else:
        u = a([-y, x, 0.])
    v = ut.normalized(np.cross(plane[:3], u))
    return a([u, v])
Esempio n. 3
0
def test_plane_H():
    if 1:
        npts = 20
        n = ut.normalized(np.array([1., 1, -1]))
        d = 2.
        X = pylab.randn(3, npts)
        # X[:2,:]*n[:2] + d + n[2]*X[2] = 0 ==> X[2] = (-d - X[:2,:]*n[:2])/n[2]
        X[2] = (-d - np.sum(X[:2] * n[:2, np.newaxis], axis=0)) / n[2]
        assert np.all(np.abs(np.dot(X.T, n) + d) <= 0.001)

        K1 = np.eye(3)
        P1 = compose_P(K1, np.eye(3), np.zeros(3))
        x1 = ut.homog_transform(P1, X)

        K2 = 2 * np.eye(3)
        R2 = np.eye(3)
        t2 = np.array([0.5, 0, 0])
        P2 = compose_P(K2, R2, t2)
        x2 = ut.homog_transform(P2, X)

        H = plane_H(n, d, K1, K2, R2, t2)
        x2_est = ut.homog_transform(H, x1)

        assert ut.a_eq(x2, x2_est)

    if 1:
        n = np.array([-0.09576725, -0.02749329, -0.995024])
        d = 12.842613230422947
        X = pylab.randn(3, npts)
        X[2] = (-d - np.sum(X[:2] * n[:2, np.newaxis], axis=0)) / n[2]
        # P1
        K1 = np.array([[184.46153519, 0., 320.5], [0., -184.46153519, 240.5],
                       [0., 0., 1.]])
        P1 = compose_P(K1, np.eye(3), np.zeros(3))
        x1 = ut.homog_transform(P1, X)
        # P2
        K2 = np.array([[184.46153519, 0., 320.5], [0., -184.46153519, 240.5],
                       [0., 0., 1.]])
        R2 = np.array([[0.99540027, -0.00263395, 0.09576725],
                       [0., 0.99962199, 0.02749329],
                       [-0.09580347, -0.02736683, 0.995024]])
        t2 = np.array([-3.42297712, 6.86145016, -1.94439297])
        P2 = compose_P(K2, R2, t2)
        x2 = ut.homog_transform(P2, X)

        H = plane_H(n, d, K1, K2, R2, t2)
        x2_est = ut.homog_transform(H, x1)
        assert ut.a_eq(x2, x2_est)
Esempio n. 4
0
def pixel_ray(P, x, y):
    K, R, t = decompose_P(P)
    return np.dot(
        R.T,
        ut.normalized(
            np.array([(x - K[0, 2]) / K[0, 0], (y - K[1, 2]) / K[1, 1], 1.0])))
def plane_from_3(pts):
  assert pts.shape == (3, 3)
  w = ut.normalized(np.cross(pts[1] - pts[0], pts[2] - pts[0]))
  return np.array(list(w) + [-np.dot(w, pts[0])])