Caution
You're reading the documentation for a development version. For the latest released version, please have a look at 0.10.2.
librosa.filters.wavelet
- librosa.filters.wavelet(*, freqs, sr=22050, window='hann', filter_scale=1, pad_fft=True, norm=1, dtype=<class 'numpy.complex64'>, gamma=0, alpha=None, **kwargs)[source]
Construct a wavelet basis using windowed complex sinusoids.
This function constructs a wavelet filterbank at a specified set of center frequencies.
- Parameters:
- freqsnp.ndarray (positive)
Center frequencies of the filters (in Hz). Must be in ascending order.
- srnumber > 0 [scalar]
Audio sampling rate
- windowstring, tuple, number, or function
Windowing function to apply to filters.
- filter_scalefloat > 0 [scalar]
Scale of filter windows. Small values (<1) use shorter windows for higher temporal resolution.
- pad_fftboolean
Center-pad all filters up to the nearest integral power of 2.
By default, padding is done with zeros, but this can be overridden by setting the
mode=
field in kwargs.- norm{inf, -inf, 0, float > 0}
Type of norm to use for basis function normalization. See librosa.util.normalize
- gammanumber >= 0
Bandwidth offset for variable-Q transforms.
- dtypenp.dtype
The data type of the output basis. By default, uses 64-bit (single precision) complex floating point.
- alphanumber > 0 [optional]
Optional pre-computed relative bandwidth parameter. Note that this must be provided if
len(freqs)==1
because bandwidth cannot be inferred from a single frequency. Otherwise, if left unspecified, it will be automatically derived by the rules specified above.- **kwargsadditional keyword arguments
Arguments to np.pad() when
pad==True
.
- Returns:
- filtersnp.ndarray,
len(filters) == n_bins
each
filters[i]
is a (complex) time-domain filter- lengthsnp.ndarray,
len(lengths) == n_bins
The (fractional) length of each filter in samples
- filtersnp.ndarray,
Notes
This function caches at level 10.
Examples
Create a constant-Q basis
>>> freqs = librosa.cqt_frequencies(n_bins=84, fmin=librosa.note_to_hz('C1')) >>> basis, lengths = librosa.filters.wavelet(freqs=freqs, sr=22050)
Plot one octave of filters in time and frequency
>>> import matplotlib.pyplot as plt >>> basis, lengths = librosa.filters.wavelet(freqs=freqs, sr=22050) >>> fig, ax = plt.subplots(nrows=2, figsize=(10, 6)) >>> notes = librosa.midi_to_note(np.arange(24, 24 + len(basis))) >>> for i, (f, n) in enumerate(zip(basis, notes[:12])): ... f_scale = librosa.util.normalize(f) / 2 ... ax[0].plot(i + f_scale.real) ... ax[0].plot(i + f_scale.imag, linestyle=':') >>> ax[0].set(yticks=np.arange(len(notes[:12])), yticklabels=notes[:12], ... ylabel='CQ filters', ... title='CQ filters (one octave, time domain)', ... xlabel='Time (samples at 22050 Hz)') >>> ax[0].legend(['Real', 'Imaginary']) >>> F = np.abs(np.fft.fftn(basis, axes=[-1])) >>> # Keep only the positive frequencies >>> F = F[:, :(1 + F.shape[1] // 2)] >>> librosa.display.specshow(F, x_axis='linear', y_axis='cqt_note', ax=ax[1]) >>> ax[1].set(ylabel='CQ filters', title='CQ filter magnitudes (frequency domain)')