Exemple #1
0
def test_ADM_no_rotate():
    np.random.seed(2)
    coil_dipole_pos = np.array(
        np.meshgrid(np.linspace(-.5, .5, 5), np.linspace(-.5, .5, 5),
                    np.linspace(-.2, .2, 3))).reshape(3, -1).T
    coil_dipole_weights = np.zeros_like(coil_dipole_pos)
    coil_dipole_weights[:, 2] = 1

    current_elm_positions = np.random.rand(1000, 3) + 10
    currents = np.random.rand(len(current_elm_positions), 3)

    observation_pos = np.random.rand(10, 3)

    coildir = np.array([[0, 1, 0]])

    coil_matrices = np.repeat(np.eye(4)[..., None],
                              len(observation_pos),
                              axis=2)
    coil_matrices[:3, 3, :] = observation_pos.T

    E_adm = ADMlib.ADM(current_elm_positions.T, currents.T, coil_dipole_pos.T,
                       coil_dipole_weights.T, coil_matrices, coildir.T)

    # Total H field in the coil
    for i, p in enumerate(observation_pos):
        H = calculate_Hprim(current_elm_positions, currents,
                            coil_dipole_pos + p)
        E = -np.sum(H * coil_dipole_weights)
        assert np.allclose(E_adm[0, i], E)
Exemple #2
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def test_ADM_rotate():
    np.random.seed(2)
    coil_dipole_pos = np.array(
        np.meshgrid(np.linspace(-.5, .5, 5), np.linspace(-.5, .5, 5),
                    np.linspace(-.2, .2, 3))).reshape(3, -1).T
    coil_dipole_weights = np.zeros_like(coil_dipole_pos)
    coil_dipole_weights[:, 2] = 1

    current_elm_positions = np.random.rand(1000, 3) + 10
    currents = np.random.rand(len(current_elm_positions), 3)

    observation_pos = np.random.rand(10, 3)

    coil_dir = []
    for angle in np.linspace(np.pi / 2, np.pi, 7):
        coil_dir.append([-np.sin(angle), np.cos(angle), 0])
    coil_dir = np.array(coil_dir)

    coil_matrices = np.repeat(np.eye(4)[..., None],
                              len(observation_pos),
                              axis=2)
    coil_matrices[:3, 3, :] = observation_pos.T

    E_adm = ADMlib.ADM(current_elm_positions.T, currents.T, coil_dipole_pos.T,
                       coil_dipole_weights.T, coil_matrices, coil_dir.T)

    # Total H field in the coil
    z = np.array([0, 0, 1])
    for i, p in enumerate(observation_pos):
        for j, cd in enumerate(coil_dir):
            rotation_matrix = np.array([np.cross(cd, z), cd, z]).T
            coil_dipole_pos_moved = rotation_matrix.dot(
                coil_dipole_pos.T).T + p
            coil_dipole_weights_rot = rotation_matrix.dot(
                coil_dipole_weights.T).T
            H = calculate_Hprim(current_elm_positions, currents,
                                coil_dipole_pos_moved)
            E = -np.sum(H * coil_dipole_weights_rot)
            assert np.allclose(E_adm[j, i], E)