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librosa.interp_harmonics¶
- librosa.interp_harmonics(x, *, freqs, harmonics, kind='linear', fill_value=0, axis=- 2)[source]¶
Compute the energy at harmonics of time-frequency representation.
Given a frequency-based energy representation such as a spectrogram or tempogram, this function computes the energy at the chosen harmonics of the frequency axis. (See examples below.) The resulting harmonic array can then be used as input to a salience computation.
- Parameters
- xnp.ndarray
The input energy
- freqsnp.ndarray, shape=(X.shape[axis])
The frequency values corresponding to X’s elements along the chosen axis.
- harmonicslist-like, non-negative
Harmonics to compute as
harmonics[i] * freqs
. The first harmonic (1) corresponds tofreqs
. Values less than one (e.g., 1/2) correspond to sub-harmonics.- kindstr
Interpolation type. See
scipy.interpolate.interp1d
.- fill_valuefloat
The value to fill when extrapolating beyond the observed frequency range.
- axisint
The axis along which to compute harmonics
- Returns
- x_harmnp.ndarray
x_harm[i]
will have the same shape asx
, and measure the energy at theharmonics[i]
harmonic of each frequency. A new dimension indexing harmonics will be inserted immediately beforeaxis
.
See also
Examples
Estimate the harmonics of a time-averaged tempogram
>>> y, sr = librosa.load(librosa.ex('sweetwaltz')) >>> # Compute the time-varying tempogram and average over time >>> tempi = np.mean(librosa.feature.tempogram(y=y, sr=sr), axis=1) >>> # We'll measure the first five harmonics >>> harmonics = [1, 2, 3, 4, 5] >>> f_tempo = librosa.tempo_frequencies(len(tempi), sr=sr) >>> # Build the harmonic tensor; we only have one axis here (tempo) >>> t_harmonics = librosa.interp_harmonics(tempi, freqs=f_tempo, harmonics=harmonics, axis=0) >>> print(t_harmonics.shape) (5, 384)
>>> # And plot the results >>> import matplotlib.pyplot as plt >>> fig, ax = plt.subplots() >>> librosa.display.specshow(t_harmonics, x_axis='tempo', sr=sr, ax=ax) >>> ax.set(yticks=np.arange(len(harmonics)), ... yticklabels=['{:.3g}'.format(_) for _ in harmonics], ... ylabel='Harmonic', xlabel='Tempo (BPM)')
We can also compute frequency harmonics for spectrograms. To calculate sub-harmonic energy, use values < 1.
>>> y, sr = librosa.load(librosa.ex('trumpet'), duration=3) >>> harmonics = [1./3, 1./2, 1, 2, 3, 4] >>> S = np.abs(librosa.stft(y)) >>> fft_freqs = librosa.fft_frequencies(sr=sr) >>> S_harm = librosa.interp_harmonics(S, freqs=fft_freqs, harmonics=harmonics, axis=0) >>> print(S_harm.shape) (6, 1025, 646)
>>> fig, ax = plt.subplots(nrows=3, ncols=2, sharex=True, sharey=True) >>> for i, _sh in enumerate(S_harm): ... img = librosa.display.specshow(librosa.amplitude_to_db(_sh, ... ref=S.max()), ... sr=sr, y_axis='log', x_axis='time', ... ax=ax.flat[i]) ... ax.flat[i].set(title='h={:.3g}'.format(harmonics[i])) ... ax.flat[i].label_outer() >>> fig.colorbar(img, ax=ax, format="%+2.f dB")