mne.preprocessing.create_ecg_epochs#

mne.preprocessing.create_ecg_epochs(raw, ch_name=None, event_id=999, picks=None, tmin=- 0.5, tmax=0.5, l_freq=8, h_freq=16, reject=None, flat=None, baseline=None, preload=True, keep_ecg=False, reject_by_annotation=True, decim=1, verbose=None)[source]#

Conveniently generate epochs around ECG artifact events.

This function will:

  1. Filter the ECG data channel.

  2. Find ECG R wave peaks using mne.preprocessing.find_ecg_events().

  3. Create Epochs around the R wave peaks, capturing the heartbeats.

Note

Filtering is only applied to the ECG channel while finding events. The resulting ecg_epochs will have no filtering applied (i.e., have the same filter properties as the input raw instance).

Parameters
rawinstance of Raw

The raw data.

ch_nameNone | str

The name of the channel to use for ECG peak detection. If None (default), ECG channel is used if present. If None and no ECG channel is present, a synthetic ECG channel is created from the cross-channel average. This synthetic channel can only be created from MEG channels.

event_idint

The index to assign to found ECG events.

picksstr | list | slice | None

Channels to include. Slices and lists of integers will be interpreted as channel indices. In lists, channel type strings (e.g., ['meg', 'eeg']) will pick channels of those types, channel name strings (e.g., ['MEG0111', 'MEG2623'] will pick the given channels. Can also be the string values “all” to pick all channels, or “data” to pick data channels. None (default) will pick all channels. Note that channels in info['bads'] will be included if their names or indices are explicitly provided.

tminfloat

Start time before event.

tmaxfloat

End time after event.

l_freqfloat

Low pass frequency to apply to the ECG channel while finding events.

h_freqfloat

High pass frequency to apply to the ECG channel while finding events.

rejectdict | None

Reject epochs based on maximum peak-to-peak signal amplitude (PTP), i.e. the absolute difference between the lowest and the highest signal value. In each individual epoch, the PTP is calculated for every channel. If the PTP of any one channel exceeds the rejection threshold, the respective epoch will be dropped.

The dictionary keys correspond to the different channel types; valid keys can be any channel type present in the object.

Example:

reject = dict(grad=4000e-13,  # unit: T / m (gradiometers)
              mag=4e-12,      # unit: T (magnetometers)
              eeg=40e-6,      # unit: V (EEG channels)
              eog=250e-6      # unit: V (EOG channels)
              )

Note

Since rejection is based on a signal difference calculated for each channel separately, applying baseline correction does not affect the rejection procedure, as the difference will be preserved.

Note

To constrain the time period used for estimation of signal quality, pass the reject_tmin and reject_tmax parameters.

If reject is None (default), no rejection is performed.

flatdict | None

Reject epochs based on minimum peak-to-peak signal amplitude (PTP). Valid keys can be any channel type present in the object. The values are floats that set the minimum acceptable PTP. If the PTP is smaller than this threshold, the epoch will be dropped. If None then no rejection is performed based on flatness of the signal.

Note

To constrain the time period used for estimation of signal quality, pass the reject_tmin and reject_tmax parameters.

baselineNone | tuple of length 2

The time interval to consider as “baseline” when applying baseline correction. If None, do not apply baseline correction. If a tuple (a, b), the interval is between a and b (in seconds), including the endpoints. If a is None, the beginning of the data is used; and if b is None, it is set to the end of the interval. If (None, None), the entire time interval is used.

Note

The baseline (a, b) includes both endpoints, i.e. all timepoints t such that a <= t <= b.

Correction is applied to each epoch and channel individually in the following way:

  1. Calculate the mean signal of the baseline period.

  2. Subtract this mean from the entire epoch.

preloadbool

Preload epochs or not (default True). Must be True if keep_ecg is True.

keep_ecgbool

When ECG is synthetically created (after picking), should it be added to the epochs? Must be False when synthetic channel is not used. Defaults to False.

reject_by_annotationbool

Whether to reject based on annotations. If True (default), epochs overlapping with segments whose description begins with 'bad' are rejected. If False, no rejection based on annotations is performed.

New in version 0.14.0.

decimint

Factor by which to subsample the data.

Warning

Low-pass filtering is not performed, this simply selects every Nth sample (where N is the value passed to decim), i.e., it compresses the signal (see Notes). If the data are not properly filtered, aliasing artifacts may occur.

New in version 0.21.0.

verbosebool | str | int | None

Control verbosity of the logging output. If None, use the default verbosity level. See the logging documentation and mne.verbose() for details. Should only be passed as a keyword argument.

Returns
ecg_epochsinstance of Epochs

Data epoched around ECG R wave peaks.

Notes

If you already have a list of R-peak times, or want to compute R-peaks outside MNE-Python using a different algorithm, the recommended approach is to call the Epochs constructor directly, with your R-peaks formatted as an events array (here we also demonstrate the relevant default values):

mne.Epochs(raw, r_peak_events_array, tmin=-0.5, tmax=0.5,
           baseline=None, preload=True, proj=False)  # doctest: +SKIP

Examples using mne.preprocessing.create_ecg_epochs#

Overview of artifact detection

Overview of artifact detection

Overview of artifact detection
Rejecting bad data spans and breaks

Rejecting bad data spans and breaks

Rejecting bad data spans and breaks
Repairing artifacts with ICA

Repairing artifacts with ICA

Repairing artifacts with ICA
Repairing artifacts with SSP

Repairing artifacts with SSP

Repairing artifacts with SSP