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import os.path as op
import numpy as np
from numpy.testing import assert_allclose, assert_array_equal
import pytest
from itertools import compress
from mne import io, pick_types, pick_channels, read_events, Epochs
from mne.channels.interpolation import _make_interpolation_matrix
from mne.datasets import testing
from mne.preprocessing.nirs import (optical_density, scalp_coupling_index,
beer_lambert_law)
from mne.io import read_raw_nirx
from mne.io.proj import _has_eeg_average_ref_proj
from mne.utils import _record_warnings, requires_version
base_dir = op.join(op.dirname(__file__), '..', '..', 'io', 'tests', 'data')
raw_fname = op.join(base_dir, 'test_raw.fif')
event_name = op.join(base_dir, 'test-eve.fif')
raw_fname_ctf = op.join(base_dir, 'test_ctf_raw.fif')
testing_path = testing.data_path(download=False)
event_id, tmin, tmax = 1, -0.2, 0.5
event_id_2 = 2
def _load_data(kind):
"""Load data."""
# It is more memory efficient to load data in a separate
# function so it's loaded on-demand
raw = io.read_raw_fif(raw_fname)
events = read_events(event_name)
# subselect channels for speed
if kind == 'eeg':
picks = pick_types(raw.info, meg=False, eeg=True, exclude=[])[:15]
epochs = Epochs(raw, events, event_id, tmin, tmax, picks=picks,
preload=True, reject=dict(eeg=80e-6))
else:
picks = pick_types(raw.info, meg=True, eeg=False, exclude=[])[1:200:2]
assert kind == 'meg'
with pytest.warns(RuntimeWarning, match='projection'):
epochs = Epochs(raw, events, event_id, tmin, tmax, picks=picks,
preload=True,
reject=dict(grad=1000e-12, mag=4e-12))
return raw, epochs
@pytest.mark.parametrize('offset', (0., 0.1))
@pytest.mark.parametrize('avg_proj, ctol', [
(True, (0.86, 0.93)),
(False, (0.97, 0.99)),
])
@pytest.mark.parametrize('method, atol', [
pytest.param(None, 3e-6, marks=pytest.mark.slowtest), # slow on Azure
(dict(eeg='MNE'), 4e-6),
])
@pytest.mark.filterwarnings('ignore:.*than 20 mm from head frame origin.*')
def test_interpolation_eeg(offset, avg_proj, ctol, atol, method):
"""Test interpolation of EEG channels."""
raw, epochs_eeg = _load_data('eeg')
epochs_eeg = epochs_eeg.copy()
assert not _has_eeg_average_ref_proj(epochs_eeg.info)
# Offsetting the coordinate frame should have no effect on the output
for inst in (raw, epochs_eeg):
for ch in inst.info['chs']:
if ch['kind'] == io.constants.FIFF.FIFFV_EEG_CH:
ch['loc'][:3] += offset
ch['loc'][3:6] += offset
for d in inst.info['dig']:
d['r'] += offset
# check that interpolation does nothing if no bads are marked
epochs_eeg.info['bads'] = []
evoked_eeg = epochs_eeg.average()
kw = dict(method=method)
with pytest.warns(RuntimeWarning, match='Doing nothing'):
evoked_eeg.interpolate_bads(**kw)
# create good and bad channels for EEG
epochs_eeg.info['bads'] = []
goods_idx = np.ones(len(epochs_eeg.ch_names), dtype=bool)
goods_idx[epochs_eeg.ch_names.index('EEG 012')] = False
bads_idx = ~goods_idx
pos = epochs_eeg._get_channel_positions()
evoked_eeg = epochs_eeg.average()
if avg_proj:
evoked_eeg.set_eeg_reference(projection=True).apply_proj()
assert_allclose(evoked_eeg.data.mean(0), 0., atol=1e-20)
ave_before = evoked_eeg.data[bads_idx]
# interpolate bad channels for EEG
epochs_eeg.info['bads'] = ['EEG 012']
evoked_eeg = epochs_eeg.average()
if avg_proj:
evoked_eeg.set_eeg_reference(projection=True).apply_proj()
good_picks = pick_types(evoked_eeg.info, meg=False, eeg=True)
assert_allclose(evoked_eeg.data[good_picks].mean(0), 0., atol=1e-20)
evoked_eeg_bad = evoked_eeg.copy()
bads_picks = pick_channels(
epochs_eeg.ch_names, include=epochs_eeg.info['bads'], ordered=True
)
evoked_eeg_bad.data[bads_picks, :] = 1e10
# Test first the exclude parameter
evoked_eeg_2_bads = evoked_eeg_bad.copy()
evoked_eeg_2_bads.info['bads'] = ['EEG 004', 'EEG 012']
evoked_eeg_2_bads.data[
pick_channels(evoked_eeg_bad.ch_names, ['EEG 004', 'EEG 012'])
] = 1e10
evoked_eeg_interp = evoked_eeg_2_bads.interpolate_bads(
origin=(0., 0., 0.), exclude=['EEG 004'], **kw)
assert evoked_eeg_interp.info['bads'] == ['EEG 004']
assert np.all(evoked_eeg_interp.get_data('EEG 004') == 1e10)
assert np.all(evoked_eeg_interp.get_data('EEG 012') != 1e10)
# Now test without exclude parameter
evoked_eeg_bad.info['bads'] = ['EEG 012']
evoked_eeg_interp = evoked_eeg_bad.copy().interpolate_bads(
origin=(0., 0., 0.), **kw)
if avg_proj:
assert_allclose(evoked_eeg_interp.data.mean(0), 0., atol=1e-6)
interp_zero = evoked_eeg_interp.data[bads_idx]
if method is None: # using
pos_good = pos[goods_idx]
pos_bad = pos[bads_idx]
interpolation = _make_interpolation_matrix(pos_good, pos_bad)
assert interpolation.shape == (1, len(epochs_eeg.ch_names) - 1)
interp_manual = np.dot(interpolation, evoked_eeg_bad.data[goods_idx])
assert_array_equal(interp_manual, interp_zero)
del interp_manual, interpolation, pos, pos_good, pos_bad
assert_allclose(ave_before, interp_zero, atol=atol)
assert ctol[0] < np.corrcoef(ave_before, interp_zero)[0, 1] < ctol[1]
interp_fit = evoked_eeg_bad.copy().interpolate_bads(**kw).data[bads_idx]
assert_allclose(ave_before, interp_fit, atol=2.5e-6)
assert ctol[1] < np.corrcoef(ave_before, interp_fit)[0, 1] # better
# check that interpolation fails when preload is False
epochs_eeg.preload = False
with pytest.raises(RuntimeError, match='requires epochs data to be loade'):
epochs_eeg.interpolate_bads(**kw)
epochs_eeg.preload = True
# check that interpolation changes the data in raw
raw_eeg = io.RawArray(data=epochs_eeg._data[0], info=epochs_eeg.info)
raw_before = raw_eeg._data[bads_idx]
raw_after = raw_eeg.interpolate_bads(**kw)._data[bads_idx]
assert not np.all(raw_before == raw_after)
# check that interpolation fails when preload is False
for inst in [raw, epochs_eeg]:
assert hasattr(inst, 'preload')
inst.preload = False
inst.info['bads'] = [inst.ch_names[1]]
with pytest.raises(RuntimeError, match='requires.*data to be loaded'):
inst.interpolate_bads(**kw)
# check that interpolation works with few channels
raw_few = raw.copy().crop(0, 0.1).load_data()
raw_few.pick_channels(raw_few.ch_names[:1] + raw_few.ch_names[3:4])
assert len(raw_few.ch_names) == 2
raw_few.del_proj()
raw_few.info['bads'] = [raw_few.ch_names[-1]]
orig_data = raw_few[1][0]
with _record_warnings() as w:
raw_few.interpolate_bads(reset_bads=False, **kw)
assert len([ww for ww in w if 'more than' not in str(ww.message)]) == 0
new_data = raw_few[1][0]
assert (new_data == 0).mean() < 0.5
assert np.corrcoef(new_data, orig_data)[0, 1] > 0.2
@pytest.mark.slowtest
def test_interpolation_meg():
"""Test interpolation of MEG channels."""
# speed accuracy tradeoff: channel subselection is faster but the
# correlation drops
thresh = 0.68
raw, epochs_meg = _load_data('meg')
# check that interpolation works when non M/EEG channels are present
# before MEG channels
raw.crop(0, 0.1).load_data().pick_channels(epochs_meg.ch_names)
raw.info.normalize_proj()
with pytest.warns(RuntimeWarning, match='unit .* changed from .* to .*'):
raw.set_channel_types({raw.ch_names[0]: 'stim'})
raw.info['bads'] = [raw.ch_names[1]]
raw.load_data()
raw.interpolate_bads(mode='fast')
del raw
# check that interpolation works for MEG
epochs_meg.info['bads'] = ['MEG 0141']
evoked = epochs_meg.average()
pick = pick_channels(epochs_meg.info['ch_names'], epochs_meg.info['bads'])
# MEG -- raw
raw_meg = io.RawArray(data=epochs_meg._data[0], info=epochs_meg.info)
raw_meg.info['bads'] = ['MEG 0141']
data1 = raw_meg[pick, :][0][0]
raw_meg.info.normalize_proj()
data2 = raw_meg.interpolate_bads(reset_bads=False,
mode='fast')[pick, :][0][0]
assert np.corrcoef(data1, data2)[0, 1] > thresh
# the same number of bads as before
assert len(raw_meg.info['bads']) == len(raw_meg.info['bads'])
# MEG -- epochs
data1 = epochs_meg.get_data()[:, pick, :].ravel()
epochs_meg.info.normalize_proj()
epochs_meg.interpolate_bads(mode='fast')
data2 = epochs_meg.get_data()[:, pick, :].ravel()
assert np.corrcoef(data1, data2)[0, 1] > thresh
assert len(epochs_meg.info['bads']) == 0
# MEG -- evoked (plus auto origin)
data1 = evoked.data[pick]
evoked.info.normalize_proj()
data2 = evoked.interpolate_bads(origin='auto').data[pick]
assert np.corrcoef(data1, data2)[0, 1] > thresh
# MEG -- with exclude
evoked.info['bads'] = ['MEG 0141', 'MEG 0121']
pick = pick_channels(evoked.ch_names, evoked.info['bads'], ordered=True)
evoked.data[pick[-1]] = 1e10
data1 = evoked.data[pick]
evoked.info.normalize_proj()
data2 = evoked.interpolate_bads(
origin='auto', exclude=['MEG 0121']
).data[pick]
assert np.corrcoef(data1[0], data2[0])[0, 1] > thresh
assert np.all(data2[1] == 1e10)
def _this_interpol(inst, ref_meg=False):
from mne.channels.interpolation import _interpolate_bads_meg
_interpolate_bads_meg(inst, ref_meg=ref_meg, mode='fast')
return inst
@pytest.mark.slowtest
def test_interpolate_meg_ctf():
"""Test interpolation of MEG channels from CTF system."""
thresh = .85
tol = .05 # assert the new interpol correlates at least .05 "better"
bad = 'MLC22-2622' # select a good channel to test the interpolation
raw = io.read_raw_fif(raw_fname_ctf).crop(0, 1.0).load_data() # 3 secs
raw.apply_gradient_compensation(3)
# Show that we have to exclude ref_meg for interpolating CTF MEG-channels
# (fixed in #5965):
raw.info['bads'] = [bad]
pick_bad = pick_channels(raw.info['ch_names'], raw.info['bads'])
data_orig = raw[pick_bad, :][0]
# mimic old behavior (the ref_meg-arg in _interpolate_bads_meg only serves
# this purpose):
data_interp_refmeg = _this_interpol(raw, ref_meg=True)[pick_bad, :][0]
# new:
data_interp_no_refmeg = _this_interpol(raw, ref_meg=False)[pick_bad, :][0]
R = dict()
R['no_refmeg'] = np.corrcoef(data_orig, data_interp_no_refmeg)[0, 1]
R['with_refmeg'] = np.corrcoef(data_orig, data_interp_refmeg)[0, 1]
print('Corrcoef of interpolated with original channel: ', R)
assert R['no_refmeg'] > R['with_refmeg'] + tol
assert R['no_refmeg'] > thresh
@testing.requires_testing_data
def test_interpolation_ctf_comp():
"""Test interpolation with compensated CTF data."""
raw_fname = op.join(testing_path, 'CTF', 'somMDYO-18av.ds')
raw = io.read_raw_ctf(raw_fname, preload=True)
raw.info['bads'] = [raw.ch_names[5], raw.ch_names[-5]]
raw.interpolate_bads(mode='fast', origin=(0., 0., 0.04))
assert raw.info['bads'] == []
@requires_version('pymatreader')
@testing.requires_testing_data
def test_interpolation_nirs():
"""Test interpolating bad nirs channels."""
fname = op.join(testing_path,
'NIRx', 'nirscout', 'nirx_15_2_recording_w_overlap')
raw_intensity = read_raw_nirx(fname, preload=False)
raw_od = optical_density(raw_intensity)
sci = scalp_coupling_index(raw_od)
raw_od.info['bads'] = list(compress(raw_od.ch_names, sci < 0.5))
bad_0 = np.where([name == raw_od.info['bads'][0] for
name in raw_od.ch_names])[0][0]
bad_0_std_pre_interp = np.std(raw_od._data[bad_0])
bads_init = list(raw_od.info['bads'])
raw_od.interpolate_bads(exclude=bads_init[:2])
assert raw_od.info['bads'] == bads_init[:2]
raw_od.interpolate_bads()
assert raw_od.info['bads'] == []
assert bad_0_std_pre_interp > np.std(raw_od._data[bad_0])
raw_haemo = beer_lambert_law(raw_od, ppf=6)
raw_haemo.info['bads'] = raw_haemo.ch_names[2:4]
assert raw_haemo.info['bads'] == ['S1_D2 hbo', 'S1_D2 hbr']
raw_haemo.interpolate_bads()
assert raw_haemo.info['bads'] == []
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