Exemplo n.º 1
0
def test_find_probe_loc_from_frontwall_real(theta_deg):
    """Test move_probe_on_Oxy() with a 10 element linear points1"""
    standoff = -10.0

    numelements = 10

    # Setup: a 2-element points1
    probe = Probe.make_matrix_probe(numelements, 0.1, 1, 0.0, 1e6)

    locations_pcs = probe.locations

    # The point O(0., 0., 0.) is the 'centre' of the points1 (geometrical centre)
    assert np.allclose(np.mean(locations_pcs, axis=0), 0.0)

    # rotate and shift points1:
    locations_gcs = locations_pcs @ g.rotation_matrix_y(
        np.deg2rad(theta_deg)).T
    locations_gcs[:, 2] += standoff

    # empty fmc data
    tx, rx = arim.ut.fmc(numelements)
    time = Time(0.0, 1.0, 50)
    scanlines = np.zeros((len(tx), len(time)))
    frame = Frame(scanlines, time, tx, rx, probe,
                  ExaminationObject(Material(1.0)))

    # Distance to surface: orthogonal projection on Oxy
    distance_to_surface = np.full(len(tx), np.nan)
    distance_to_surface[tx == rx] = -locations_gcs[tx[tx == rx], 2]

    frame = reg.move_probe_over_flat_surface(frame, distance_to_surface)
    out_locations = frame.probe.locations

    assert np.allclose(out_locations, locations_gcs)
Exemplo n.º 2
0
def test_find_probe_loc_from_frontwall_ideal(A, B, dA, dB):
    """Test move_probe_over_flat_surface() with 2 elements"""
    A = np.asarray(A, dtype=np.float)
    B = np.asarray(B, dtype=np.float)

    # Setup: a 2-element points1
    locations = g.Points(np.array([A, B]))  # locations in PCS
    probe = Probe(locations, 1e6)  # NB: assume PCS=GCS at this point

    tx = np.array([0, 0, 1])
    rx = np.array([0, 1, 1])

    distance_to_surface = np.array([dA, np.nan, dB])

    time = Time(0.0, 1.0, 50)
    scanlines = np.zeros((len(tx), len(time)))

    frame = Frame(scanlines, time, tx, rx, probe,
                  ExaminationObject(Material(1.0)))

    frame, iso = reg.move_probe_over_flat_surface(frame,
                                                  distance_to_surface,
                                                  full_output=True)
    new_locations = frame.probe.locations

    # Are the locations in PCS unchanged?
    assert np.allclose(frame.probe.locations_pcs, locations)

    # Right distance to the plane Oxy (NB: z<0):
    assert np.isclose(new_locations.z[0], -dA)
    assert np.isclose(new_locations.z[1], -dB)

    # Elements are in plane y=0
    assert np.isclose(new_locations.y[0], 0.0)
    assert np.isclose(new_locations.y[1], 0.0)

    # Is element A(0., 0., 0.) now in (0., 0., z)?
    assert np.allclose(new_locations[0], (0.0, 0.0, iso.z_o))

    # the elements are still in the right distance
    dAB = g.norm2(*(locations[0] - locations[1]))
    dApBp = g.norm2(*(new_locations[0] - new_locations[1]))
    assert np.isclose(dAB, dApBp)

    # Is the returned theta right?
    # Remark: (dB-dB)/(xB-xA) has the sign of theta, then
    # (zA-zB)/(xB-xA) has the sign of -theta because zA=-dA and zB=-dB
    theta = -np.arctan((new_locations.z[1] - new_locations.z[0]) /
                       (new_locations.x[1] - new_locations.x[0]))
    assert np.isclose(theta, iso.theta)
Exemplo n.º 3
0
def test_detect_surface_from_extrema():
    probe = Probe.make_matrix_probe(3, 1.0, 1.0, 0.0, 1e6)

    time = Time(10.0, 1.0, 50)

    tx = np.array([0, 0, 1, 1, 2, 2])
    rx = np.array([0, 1, 1, 0, 2, 0])

    scanlines = np.random.uniform(high=10.0, size=(len(tx), len(time)))

    times_to_surface_expected = np.array([25.0, 26.0, 27.0, 28.0, 29.0, 30.0])

    for (i, t) in enumerate(times_to_surface_expected):
        scanlines[i, time.closest_index(t)] = t

    frame = Frame(scanlines, time, tx, rx, probe,
                  ExaminationObject(Material(1.0)))

    times_to_surface = reg.detect_surface_from_extrema(frame)

    assert np.allclose(times_to_surface, times_to_surface_expected)
Exemplo n.º 4
0
def make_delay_and_sum_case_random(dtype_float,
                                   dtype_data,
                                   amplitudes="random"):
    locations = g.Points(
        np.array([(0, 0, 0), (1.0, 0, 0), (2.0, 0.0, 0.0)], dtype=np.float))
    numelements = len(locations)
    frequency = 1e6
    probe = Probe(locations, frequency)

    # examination object:
    vel = 10.0
    material = Material(vel)
    examination_object = ExaminationObject(material)

    # timetraces
    # time = Time(start=0.35, step=0.001, num=100)
    time = Time(start=0.0, step=0.001, num=100)

    tx = np.array([0, 0, 1, 1, 2, 2], dtype=np.int)
    rx = np.array([0, 1, 0, 1, 0, 1], dtype=np.int)
    numtimetraces = len(tx)

    numpoints = 10

    start_lookup = time.start / 2
    stop_lookup = (time.end - time.step) / 2

    np.random.seed(31031596)
    timetraces = _random_uniform(dtype_data,
                                 100.0,
                                 101.0,
                                 size=(numtimetraces, len(time)))
    amplitudes_tx = _random_uniform(dtype_data,
                                    1.0,
                                    1.1,
                                    size=(numpoints, numelements))
    amplitudes_rx = _random_uniform(dtype_data,
                                    -1.0,
                                    -1.1,
                                    size=(numpoints, numelements))
    timetrace_weights = _random_uniform(dtype_data, size=(numtimetraces))
    lookup_times_tx = _random_uniform(dtype_float, start_lookup, stop_lookup,
                                      (numpoints, numelements))
    lookup_times_rx = _random_uniform(dtype_float, start_lookup, stop_lookup,
                                      (numpoints, numelements))
    if amplitudes == "random":
        amplitudes = arim.im.tfm.TxRxAmplitudes(amplitudes_tx, amplitudes_rx)
    elif amplitudes == "uniform":
        amplitudes = arim.im.tfm.TxRxAmplitudes(
            np.ones((numpoints, numelements), dtype_data),
            np.ones((numpoints, numelements), dtype_data),
        )
    elif amplitudes == "none":
        amplitudes = None
    else:
        raise ValueError

    # Mess a bit lookup times to get out of bounds values:
    # lookup_times_tx[0, 0] = time.start / 2.
    # lookup_times_rx[1, 1] = time.end * 2.

    focal_law = arim.im.tfm.FocalLaw(lookup_times_tx, lookup_times_rx,
                                     amplitudes, timetrace_weights)

    frame = Frame(timetraces, time, tx, rx, probe, examination_object)

    return frame, focal_law