Ejemplo n.º 1
0
def test_multipolar_bases():
    """Test multipolar moment basis calculation using sensor information"""
    from scipy.io import loadmat
    # Test our basis calculations
    info = read_info(raw_fname)
    coils = _prep_meg_channels(info, accurate=True, elekta_defs=True)[0]
    # Check against a known benchmark
    sss_data = loadmat(bases_fname)
    for origin in ((0, 0, 0.04), (0, 0.02, 0.02)):
        o_str = ''.join('%d' % (1000 * n) for n in origin)

        S_tot = _sss_basis_basic(origin,
                                 coils,
                                 int_order,
                                 ext_order,
                                 method='alternative')
        # Test our real<->complex conversion functions
        S_tot_complex = _bases_real_to_complex(S_tot, int_order, ext_order)
        S_tot_round = _bases_complex_to_real(S_tot_complex, int_order,
                                             ext_order)
        assert_allclose(S_tot, S_tot_round, atol=1e-7)

        S_tot_mat = np.concatenate(
            [sss_data['Sin' + o_str], sss_data['Sout' + o_str]], axis=1)
        S_tot_mat_real = _bases_complex_to_real(S_tot_mat, int_order,
                                                ext_order)
        S_tot_mat_round = _bases_real_to_complex(S_tot_mat_real, int_order,
                                                 ext_order)
        assert_allclose(S_tot_mat, S_tot_mat_round, atol=1e-7)
        assert_allclose(S_tot_complex, S_tot_mat, rtol=1e-4, atol=1e-8)
        assert_allclose(S_tot, S_tot_mat_real, rtol=1e-4, atol=1e-8)

        # Now normalize our columns
        S_tot /= np.sqrt(np.sum(S_tot * S_tot, axis=0))[np.newaxis]
        S_tot_complex /= np.sqrt(
            np.sum((S_tot_complex * S_tot_complex.conj()).real,
                   axis=0))[np.newaxis]
        # Check against a known benchmark
        S_tot_mat = np.concatenate(
            [sss_data['SNin' + o_str], sss_data['SNout' + o_str]], axis=1)
        # Check this roundtrip
        S_tot_mat_real = _bases_complex_to_real(S_tot_mat, int_order,
                                                ext_order)
        S_tot_mat_round = _bases_real_to_complex(S_tot_mat_real, int_order,
                                                 ext_order)
        assert_allclose(S_tot_mat, S_tot_mat_round, atol=1e-7)
        assert_allclose(S_tot_complex, S_tot_mat, rtol=1e-4, atol=1e-8)

        # Now test our optimized version
        S_tot = _sss_basis_basic(origin, coils, int_order, ext_order)
        S_tot_fast = _sss_basis(origin, coils, int_order, ext_order)
        S_tot_fast *= _get_coil_scale(coils)
        # there are some sign differences for columns (order/degrees)
        # in here, likely due to Condon-Shortley. Here we use a
        # Magnetometer channel to figure out the flips because the
        # gradiometer channels have effectively zero values for first three
        # external components (i.e., S_tot[grad_picks, 80:83])
        flips = (np.sign(S_tot_fast[2]) != np.sign(S_tot[2]))
        flips = 1 - 2 * flips
        assert_allclose(S_tot, S_tot_fast * flips, atol=1e-16)
Ejemplo n.º 2
0
def test_multipolar_bases():
    """Test multipolar moment basis calculation using sensor information."""
    from scipy.io import loadmat
    # Test our basis calculations
    info = read_info(raw_fname)
    with use_coil_def(elekta_def_fname):
        coils = _prep_meg_channels(info, accurate=True, do_es=True)[0]
    # Check against a known benchmark
    sss_data = loadmat(bases_fname)
    exp = dict(int_order=int_order, ext_order=ext_order)
    for origin in ((0, 0, 0.04), (0, 0.02, 0.02)):
        o_str = ''.join('%d' % (1000 * n) for n in origin)
        exp.update(origin=origin)
        S_tot = _sss_basis_basic(exp, coils, method='alternative')
        # Test our real<->complex conversion functions
        S_tot_complex = _bases_real_to_complex(S_tot, int_order, ext_order)
        S_tot_round = _bases_complex_to_real(S_tot_complex,
                                             int_order, ext_order)
        assert_allclose(S_tot, S_tot_round, atol=1e-7)

        S_tot_mat = np.concatenate([sss_data['Sin' + o_str],
                                    sss_data['Sout' + o_str]], axis=1)
        S_tot_mat_real = _bases_complex_to_real(S_tot_mat,
                                                int_order, ext_order)
        S_tot_mat_round = _bases_real_to_complex(S_tot_mat_real,
                                                 int_order, ext_order)
        assert_allclose(S_tot_mat, S_tot_mat_round, atol=1e-7)
        assert_allclose(S_tot_complex, S_tot_mat, rtol=1e-4, atol=1e-8)
        assert_allclose(S_tot, S_tot_mat_real, rtol=1e-4, atol=1e-8)

        # Now normalize our columns
        S_tot /= np.sqrt(np.sum(S_tot * S_tot, axis=0))[np.newaxis]
        S_tot_complex /= np.sqrt(np.sum(
            (S_tot_complex * S_tot_complex.conj()).real, axis=0))[np.newaxis]
        # Check against a known benchmark
        S_tot_mat = np.concatenate([sss_data['SNin' + o_str],
                                    sss_data['SNout' + o_str]], axis=1)
        # Check this roundtrip
        S_tot_mat_real = _bases_complex_to_real(S_tot_mat,
                                                int_order, ext_order)
        S_tot_mat_round = _bases_real_to_complex(S_tot_mat_real,
                                                 int_order, ext_order)
        assert_allclose(S_tot_mat, S_tot_mat_round, atol=1e-7)
        assert_allclose(S_tot_complex, S_tot_mat, rtol=1e-4, atol=1e-8)

        # Now test our optimized version
        S_tot = _sss_basis_basic(exp, coils)
        with use_coil_def(elekta_def_fname):
            S_tot_fast = _trans_sss_basis(
                exp, all_coils=_prep_mf_coils(info), trans=info['dev_head_t'])
        # there are some sign differences for columns (order/degrees)
        # in here, likely due to Condon-Shortley. Here we use a
        # Magnetometer channel to figure out the flips because the
        # gradiometer channels have effectively zero values for first three
        # external components (i.e., S_tot[grad_picks, 80:83])
        flips = (np.sign(S_tot_fast[2]) != np.sign(S_tot[2]))
        flips = 1 - 2 * flips
        assert_allclose(S_tot, S_tot_fast * flips, atol=1e-16)
Ejemplo n.º 3
0
def test_multipolar_bases():
    """Test multipolar moment basis calculation using sensor information"""
    from scipy.io import loadmat
    # Test our basis calculations
    info = read_info(raw_fname)
    coils = _prep_meg_channels(info, accurate=True, elekta_defs=True,
                               verbose=False)[0]
    # Check against a known benchmark
    sss_data = loadmat(bases_fname)
    for origin in ((0, 0, 0.04), (0, 0.02, 0.02)):
        o_str = ''.join('%d' % (1000 * n) for n in origin)

        S_tot = _sss_basis(origin, coils, int_order, ext_order,
                           method='alternative')
        # Test our real<->complex conversion functions
        S_tot_complex = _bases_real_to_complex(S_tot, int_order, ext_order)
        S_tot_round = _bases_complex_to_real(S_tot_complex,
                                             int_order, ext_order)
        assert_allclose(S_tot, S_tot_round, atol=1e-7)

        S_tot_mat = np.concatenate([sss_data['Sin' + o_str],
                                    sss_data['Sout' + o_str]], axis=1)
        mu0 = 4e-7 * np.pi  # Permeability of vacuum
        S_tot_mat /= mu0  # divide out the magnetic permeability
        S_tot_mat_real = _bases_complex_to_real(S_tot_mat,
                                                int_order, ext_order)
        S_tot_mat_round = _bases_real_to_complex(S_tot_mat_real,
                                                 int_order, ext_order)
        assert_allclose(S_tot_mat, S_tot_mat_round, atol=1e-7)
        assert_allclose(S_tot_complex, S_tot_mat, rtol=1e-4, atol=1e-8)
        assert_allclose(S_tot, S_tot_mat_real, rtol=1e-4, atol=1e-8)

        # Now normalize our columns
        S_tot /= np.sqrt(np.sum(S_tot * S_tot, axis=0))[np.newaxis]
        S_tot_complex /= np.sqrt(np.sum(
            (S_tot_complex * S_tot_complex.conj()).real, axis=0))[np.newaxis]
        # Check against a known benchmark
        S_tot_mat = np.concatenate([sss_data['SNin' + o_str],
                                    sss_data['SNout' + o_str]], axis=1)
        # Check this roundtrip
        S_tot_mat_real = _bases_complex_to_real(S_tot_mat,
                                                int_order, ext_order)
        S_tot_mat_round = _bases_real_to_complex(S_tot_mat_real,
                                                 int_order, ext_order)
        assert_allclose(S_tot_mat, S_tot_mat_round, atol=1e-7)
        assert_allclose(S_tot_complex, S_tot_mat, rtol=1e-4, atol=1e-8)