mne.time_frequency.tfr_array_morlet¶
- mne.time_frequency.tfr_array_morlet(epoch_data, sfreq, freqs, n_cycles=7.0, zero_mean=False, use_fft=True, decim=1, output='complex', n_jobs=1, verbose=None)[source]¶
Compute Time-Frequency Representation (TFR) using Morlet wavelets.
Same computation as
tfr_morlet
, but operates onNumPy arrays
instead ofEpochs
objects.- Parameters
- epoch_data
array
of shape (n_epochs, n_channels, n_times) The epochs.
- sfreq
float
|int
Sampling frequency of the data.
- freqsarray_like of
float
, shape (n_freqs,) The frequencies.
- n_cycles
float
|array
offloat
, default 7.0 Number of cycles in the Morlet wavelet. Fixed number or one per frequency.
- zero_meanbool |
False
If True, make sure the wavelets have a mean of zero. default False.
- use_fftbool
Use the FFT for convolutions or not. default True.
- decim
int
|slice
To reduce memory usage, decimation factor after time-frequency decomposition. default 1 If
int
, returns tfr[…, ::decim]. Ifslice
, returns tfr[…, decim].Note
Decimation may create aliasing artifacts, yet decimation is done after the convolutions.
- output
str
, default ‘complex’ ‘complex’ : single trial complex.
‘power’ : single trial power.
‘phase’ : single trial phase.
‘avg_power’ : average of single trial power.
‘itc’ : inter-trial coherence.
‘avg_power_itc’ : average of single trial power and inter-trial coherence across trials.
- n_jobs
int
The number of jobs to run in parallel (default
1
). If-1
, it is set to the number of CPU cores. Requires thejoblib
package. The number of epochs to process at the same time. The parallelization is implemented across channels. Default 1.- verbosebool |
str
|int
|None
Control verbosity of the logging output. If
None
, use the default verbosity level. See the logging documentation andmne.verbose()
for details. Should only be passed as a keyword argument.
- epoch_data
- Returns
- out
array
Time frequency transform of epoch_data. If output is in [‘complex’, ‘phase’, ‘power’], then shape of out is (n_epochs, n_chans, n_freqs, n_times), else it is (n_chans, n_freqs, n_times). If output is ‘avg_power_itc’, the real values code for ‘avg_power’ and the imaginary values code for the ‘itc’: out = avg_power + i * itc.
- out
See also
Notes
New in version 0.14.0.