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Source code for librosa.core.spectrum

#!/usr/bin/env python
# -*- coding: utf-8 -*-
"""Utilities for spectral processing"""
import warnings

import numpy as np
import scipy
import scipy.ndimage
import scipy.signal
import scipy.interpolate

from numba import jit

from . import convert
from .fft import get_fftlib
from .audio import resample
from .._cache import cache
from .. import util
from ..util.exceptions import ParameterError
from ..filters import get_window, semitone_filterbank
from ..filters import window_sumsquare
from ..util.decorators import deprecate_positional_args

__all__ = [
    "stft",
    "istft",
    "magphase",
    "iirt",
    "reassigned_spectrogram",
    "phase_vocoder",
    "perceptual_weighting",
    "power_to_db",
    "db_to_power",
    "amplitude_to_db",
    "db_to_amplitude",
    "fmt",
    "pcen",
    "griffinlim",
]


[docs]@deprecate_positional_args @cache(level=20) def stft( y, *, n_fft=2048, hop_length=None, win_length=None, window="hann", center=True, dtype=None, pad_mode="constant", ): """Short-time Fourier transform (STFT). The STFT represents a signal in the time-frequency domain by computing discrete Fourier transforms (DFT) over short overlapping windows. This function returns a complex-valued matrix D such that - ``np.abs(D[..., f, t])`` is the magnitude of frequency bin ``f`` at frame ``t``, and - ``np.angle(D[..., f, t])`` is the phase of frequency bin ``f`` at frame ``t``. The integers ``t`` and ``f`` can be converted to physical units by means of the utility functions `frames_to_samples` and `fft_frequencies`. Parameters ---------- y : np.ndarray [shape=(..., n)], real-valued input signal. Multi-channel is supported. n_fft : int > 0 [scalar] length of the windowed signal after padding with zeros. The number of rows in the STFT matrix ``D`` is ``(1 + n_fft/2)``. The default value, ``n_fft=2048`` samples, corresponds to a physical duration of 93 milliseconds at a sample rate of 22050 Hz, i.e. the default sample rate in librosa. This value is well adapted for music signals. However, in speech processing, the recommended value is 512, corresponding to 23 milliseconds at a sample rate of 22050 Hz. In any case, we recommend setting ``n_fft`` to a power of two for optimizing the speed of the fast Fourier transform (FFT) algorithm. hop_length : int > 0 [scalar] number of audio samples between adjacent STFT columns. Smaller values increase the number of columns in ``D`` without affecting the frequency resolution of the STFT. If unspecified, defaults to ``win_length // 4`` (see below). win_length : int <= n_fft [scalar] Each frame of audio is windowed by ``window`` of length ``win_length`` and then padded with zeros to match ``n_fft``. Smaller values improve the temporal resolution of the STFT (i.e. the ability to discriminate impulses that are closely spaced in time) at the expense of frequency resolution (i.e. the ability to discriminate pure tones that are closely spaced in frequency). This effect is known as the time-frequency localization trade-off and needs to be adjusted according to the properties of the input signal ``y``. If unspecified, defaults to ``win_length = n_fft``. window : string, tuple, number, function, or np.ndarray [shape=(n_fft,)] Either: - a window specification (string, tuple, or number); see `scipy.signal.get_window` - a window function, such as `scipy.signal.windows.hann` - a vector or array of length ``n_fft`` Defaults to a raised cosine window (`'hann'`), which is adequate for most applications in audio signal processing. .. see also:: `filters.get_window` center : boolean If ``True``, the signal ``y`` is padded so that frame ``D[:, t]`` is centered at ``y[t * hop_length]``. If ``False``, then ``D[:, t]`` begins at ``y[t * hop_length]``. Defaults to ``True``, which simplifies the alignment of ``D`` onto a time grid by means of `librosa.frames_to_samples`. Note, however, that ``center`` must be set to `False` when analyzing signals with `librosa.stream`. .. see also:: `librosa.stream` dtype : np.dtype, optional Complex numeric type for ``D``. Default is inferred to match the precision of the input signal. pad_mode : string or function If ``center=True``, this argument is passed to `np.pad` for padding the edges of the signal ``y``. By default (``pad_mode="constant"``), ``y`` is padded on both sides with zeros. If ``center=False``, this argument is ignored. .. see also:: `numpy.pad` Returns ------- D : np.ndarray [shape=(..., 1 + n_fft/2, n_frames), dtype=dtype] Complex-valued matrix of short-term Fourier transform coefficients. See Also -------- istft : Inverse STFT reassigned_spectrogram : Time-frequency reassigned spectrogram Notes ----- This function caches at level 20. Examples -------- >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> S = np.abs(librosa.stft(y)) >>> S array([[5.395e-03, 3.332e-03, ..., 9.862e-07, 1.201e-05], [3.244e-03, 2.690e-03, ..., 9.536e-07, 1.201e-05], ..., [7.523e-05, 3.722e-05, ..., 1.188e-04, 1.031e-03], [7.640e-05, 3.944e-05, ..., 5.180e-04, 1.346e-03]], dtype=float32) Use left-aligned frames, instead of centered frames >>> S_left = librosa.stft(y, center=False) Use a shorter hop length >>> D_short = librosa.stft(y, hop_length=64) Display a spectrogram >>> import matplotlib.pyplot as plt >>> fig, ax = plt.subplots() >>> img = librosa.display.specshow(librosa.amplitude_to_db(S, ... ref=np.max), ... y_axis='log', x_axis='time', ax=ax) >>> ax.set_title('Power spectrogram') >>> fig.colorbar(img, ax=ax, format="%+2.0f dB") """ # By default, use the entire frame if win_length is None: win_length = n_fft # Set the default hop, if it's not already specified if hop_length is None: hop_length = int(win_length // 4) # Check audio is valid util.valid_audio(y, mono=False) fft_window = get_window(window, win_length, fftbins=True) # Pad the window out to n_fft size fft_window = util.pad_center(fft_window, size=n_fft) # Reshape so that the window can be broadcast fft_window = util.expand_to(fft_window, ndim=1 + y.ndim, axes=-2) # Pad the time series so that frames are centered if center: if n_fft > y.shape[-1]: warnings.warn( "n_fft={} is too small for input signal of length={}".format( n_fft, y.shape[-1] ), stacklevel=2, ) padding = [(0, 0) for _ in range(y.ndim)] padding[-1] = (int(n_fft // 2), int(n_fft // 2)) y = np.pad(y, padding, mode=pad_mode) elif n_fft > y.shape[-1]: raise ParameterError( "n_fft={} is too large for input signal of length={}".format( n_fft, y.shape[-1] ) ) # Window the time series. y_frames = util.frame(y, frame_length=n_fft, hop_length=hop_length) fft = get_fftlib() if dtype is None: dtype = util.dtype_r2c(y.dtype) # Pre-allocate the STFT matrix shape = list(y_frames.shape) shape[-2] = 1 + n_fft // 2 stft_matrix = np.empty(shape, dtype=dtype, order="F") n_columns = util.MAX_MEM_BLOCK // ( np.prod(stft_matrix.shape[:-1]) * stft_matrix.itemsize ) n_columns = max(n_columns, 1) for bl_s in range(0, stft_matrix.shape[-1], n_columns): bl_t = min(bl_s + n_columns, stft_matrix.shape[-1]) stft_matrix[..., bl_s:bl_t] = fft.rfft( fft_window * y_frames[..., bl_s:bl_t], axis=-2 ) return stft_matrix
[docs]@deprecate_positional_args @cache(level=30) def istft( stft_matrix, *, hop_length=None, win_length=None, n_fft=None, window="hann", center=True, dtype=None, length=None, ): """ Inverse short-time Fourier transform (ISTFT). Converts a complex-valued spectrogram ``stft_matrix`` to time-series ``y`` by minimizing the mean squared error between ``stft_matrix`` and STFT of ``y`` as described in [#]_ up to Section 2 (reconstruction from MSTFT). In general, window function, hop length and other parameters should be same as in stft, which mostly leads to perfect reconstruction of a signal from unmodified ``stft_matrix``. .. [#] D. W. Griffin and J. S. Lim, "Signal estimation from modified short-time Fourier transform," IEEE Trans. ASSP, vol.32, no.2, pp.236–243, Apr. 1984. Parameters ---------- stft_matrix : np.ndarray [shape=(..., 1 + n_fft//2, t)] STFT matrix from ``stft`` hop_length : int > 0 [scalar] Number of frames between STFT columns. If unspecified, defaults to ``win_length // 4``. win_length : int <= n_fft = 2 * (stft_matrix.shape[0] - 1) When reconstructing the time series, each frame is windowed and each sample is normalized by the sum of squared window according to the ``window`` function (see below). If unspecified, defaults to ``n_fft``. n_fft : int > 0 or None The number of samples per frame in the input spectrogram. By default, this will be inferred from the shape of ``stft_matrix``. However, if an odd frame length was used, you can specify the correct length by setting ``n_fft``. window : string, tuple, number, function, np.ndarray [shape=(n_fft,)] - a window specification (string, tuple, or number); see `scipy.signal.get_window` - a window function, such as `scipy.signal.windows.hann` - a user-specified window vector of length ``n_fft`` .. see also:: `filters.get_window` center : boolean - If ``True``, ``D`` is assumed to have centered frames. - If ``False``, ``D`` is assumed to have left-aligned frames. dtype : numeric type Real numeric type for ``y``. Default is to match the numerical precision of the input spectrogram. length : int > 0, optional If provided, the output ``y`` is zero-padded or clipped to exactly ``length`` samples. Returns ------- y : np.ndarray [shape=(..., n)] time domain signal reconstructed from ``stft_matrix``. If ``stft_matrix`` contains more than two axes (e.g., from a stereo input signal), then ``y`` will match shape on the leading dimensions. See Also -------- stft : Short-time Fourier Transform Notes ----- This function caches at level 30. Examples -------- >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> D = librosa.stft(y) >>> y_hat = librosa.istft(D) >>> y_hat array([-1.407e-03, -4.461e-04, ..., 5.131e-06, -1.417e-05], dtype=float32) Exactly preserving length of the input signal requires explicit padding. Otherwise, a partial frame at the end of ``y`` will not be represented. >>> n = len(y) >>> n_fft = 2048 >>> y_pad = librosa.util.fix_length(y, size=n + n_fft // 2) >>> D = librosa.stft(y_pad, n_fft=n_fft) >>> y_out = librosa.istft(D, length=n) >>> np.max(np.abs(y - y_out)) 8.940697e-08 """ if n_fft is None: n_fft = 2 * (stft_matrix.shape[-2] - 1) # By default, use the entire frame if win_length is None: win_length = n_fft # Set the default hop, if it's not already specified if hop_length is None: hop_length = int(win_length // 4) ifft_window = get_window(window, win_length, fftbins=True) # Pad out to match n_fft, and add broadcasting axes ifft_window = util.pad_center(ifft_window, size=n_fft) ifft_window = util.expand_to(ifft_window, ndim=stft_matrix.ndim, axes=-2) # For efficiency, trim STFT frames according to signal length if available if length: if center: padded_length = length + int(n_fft) else: padded_length = length n_frames = min(stft_matrix.shape[-1], int(np.ceil(padded_length / hop_length))) else: n_frames = stft_matrix.shape[-1] if dtype is None: dtype = util.dtype_c2r(stft_matrix.dtype) shape = list(stft_matrix.shape[:-2]) expected_signal_len = n_fft + hop_length * (n_frames - 1) shape.append(expected_signal_len) y = np.zeros(shape, dtype=dtype) n_columns = util.MAX_MEM_BLOCK // ( np.prod(stft_matrix.shape[:-1]) * stft_matrix.itemsize ) n_columns = max(n_columns, 1) fft = get_fftlib() frame = 0 for bl_s in range(0, n_frames, n_columns): bl_t = min(bl_s + n_columns, n_frames) # invert the block and apply the window function ytmp = ifft_window * fft.irfft(stft_matrix[..., bl_s:bl_t], n=n_fft, axis=-2) # Overlap-add the istft block starting at the i'th frame __overlap_add(y[..., frame * hop_length :], ytmp, hop_length) frame += bl_t - bl_s # Normalize by sum of squared window ifft_window_sum = window_sumsquare( window=window, n_frames=n_frames, win_length=win_length, n_fft=n_fft, hop_length=hop_length, dtype=dtype, ) approx_nonzero_indices = ifft_window_sum > util.tiny(ifft_window_sum) y[..., approx_nonzero_indices] /= ifft_window_sum[approx_nonzero_indices] if length is None: # If we don't need to control length, just do the usual center trimming # to eliminate padded data if center: y = y[..., int(n_fft // 2) : -int(n_fft // 2)] else: if center: # If we're centering, crop off the first n_fft//2 samples # and then trim/pad to the target length. # We don't trim the end here, so that if the signal is zero-padded # to a longer duration, the decay is smooth by windowing start = int(n_fft // 2) else: # If we're not centering, start at 0 and trim/pad as necessary start = 0 y = util.fix_length(y[..., start:], size=length) return y
@jit(nopython=True, cache=True) def __overlap_add(y, ytmp, hop_length): # numba-accelerated overlap add for inverse stft # y is the pre-allocated output buffer # ytmp is the windowed inverse-stft frames # hop_length is the hop-length of the STFT analysis n_fft = ytmp.shape[-2] for frame in range(ytmp.shape[-1]): sample = frame * hop_length y[..., sample : (sample + n_fft)] += ytmp[..., frame] def __reassign_frequencies( y, sr=22050, S=None, n_fft=2048, hop_length=None, win_length=None, window="hann", center=True, dtype=None, pad_mode="constant", ): """Instantaneous frequencies based on a spectrogram representation. The reassignment vector is calculated using equation 5.20 in Flandrin, Auger, & Chassande-Mottin 2002:: omega_reassigned = omega - np.imag(S_dh/S_h) where ``S_h`` is the complex STFT calculated using the original window, and ``S_dh`` is the complex STFT calculated using the derivative of the original window. See `reassigned_spectrogram` for references. It is recommended to use ``pad_mode="wrap"`` or else ``center=False``, rather than the defaults. Frequency reassignment assumes that the energy in each FFT bin is associated with exactly one signal component. Reflection padding at the edges of the signal may invalidate the reassigned estimates in the boundary frames. Parameters ---------- y : np.ndarray [shape=(..., n,)], real-valued audio time series. Multi-channel is supported. sr : number > 0 [scalar] sampling rate of ``y`` S : np.ndarray [shape=(..., d, t)] or None (optional) complex STFT calculated using the other arguments provided to `__reassign_frequencies` n_fft : int > 0 [scalar] FFT window size. Defaults to 2048. hop_length : int > 0 [scalar] hop length, number samples between subsequent frames. If not supplied, defaults to ``win_length // 4``. win_length : int > 0, <= n_fft Window length. Defaults to ``n_fft``. See ``stft`` for details. window : string, tuple, number, function, or np.ndarray [shape=(n_fft,)] - a window specification (string, tuple, number); see `scipy.signal.get_window` - a window function, such as `scipy.signal.windows.hann` - a user-specified window vector of length ``n_fft`` See `stft` for details. .. see also:: `filters.get_window` center : boolean - If ``True``, the signal ``y`` is padded so that frame ``S[:, t]`` is centered at ``y[t * hop_length]``. - If ``False``, then ``S[:, t]`` begins at ``y[t * hop_length]``. dtype : numeric type Complex numeric type for ``S``. Default is inferred to match the numerical precision of the input signal. pad_mode : string If ``center=True``, the padding mode to use at the edges of the signal. By default, STFT uses zero padding. Returns ------- freqs : np.ndarray [shape=(..., 1 + n_fft/2, t), dtype=real] Instantaneous frequencies: ``freqs[f, t]`` is the frequency for bin ``f``, frame ``t``. S : np.ndarray [shape=(..., 1 + n_fft/2, t), dtype=complex] Short-time Fourier transform Warns ----- RuntimeWarning Frequencies with zero support will produce a divide-by-zero warning and will be returned as `np.nan`. See Also -------- stft : Short-time Fourier Transform reassigned_spectrogram : Time-frequency reassigned spectrogram Examples -------- >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> frequencies, S = librosa.core.spectrum.__reassign_frequencies(y, sr=sr) >>> frequencies array([[0.000e+00, 0.000e+00, ..., 0.000e+00, 0.000e+00], [3.628e+00, 4.698e+00, ..., 1.239e+01, 1.072e+01], ..., [1.101e+04, 1.102e+04, ..., 1.105e+04, 1.102e+04], [1.102e+04, 1.102e+04, ..., 1.102e+04, 1.102e+04]]) """ # retrieve window samples if needed so that the window derivative can be # calculated if win_length is None: win_length = n_fft window = get_window(window, win_length, fftbins=True) window = util.pad_center(window, size=n_fft) if S is None: if dtype is None: dtype = util.dtype_r2c(y.dtype) S_h = stft( y=y, n_fft=n_fft, hop_length=hop_length, window=window, center=center, dtype=dtype, pad_mode=pad_mode, ) else: if dtype is None: dtype = S.dtype S_h = S # cyclic gradient to correctly handle edges of a periodic window window_derivative = util.cyclic_gradient(window) S_dh = stft( y=y, n_fft=n_fft, hop_length=hop_length, window=window_derivative, center=center, dtype=dtype, pad_mode=pad_mode, ) # equation 5.20 of Flandrin, Auger, & Chassande-Mottin 2002 # the sign of the correction is reversed in some papers - see Plante, # Meyer, & Ainsworth 1998 pp. 283-284 correction = -np.imag(S_dh / S_h) freqs = convert.fft_frequencies(sr=sr, n_fft=n_fft) freqs = util.expand_to(freqs, ndim=correction.ndim, axes=-2) + correction * ( 0.5 * sr / np.pi ) return freqs, S_h def __reassign_times( y, sr=22050, S=None, n_fft=2048, hop_length=None, win_length=None, window="hann", center=True, dtype=None, pad_mode="constant", ): """Time reassignments based on a spectrogram representation. The reassignment vector is calculated using equation 5.23 in Flandrin, Auger, & Chassande-Mottin 2002:: t_reassigned = t + np.real(S_th/S_h) where ``S_h`` is the complex STFT calculated using the original window, and ``S_th`` is the complex STFT calculated using the original window multiplied by the time offset from the window center. See `reassigned_spectrogram` for references. It is recommended to use ``pad_mode="constant"`` (zero padding) or else ``center=False``, rather than the defaults. Time reassignment assumes that the energy in each FFT bin is associated with exactly one impulse event. Reflection padding at the edges of the signal may invalidate the reassigned estimates in the boundary frames. Parameters ---------- y : np.ndarray [shape=(..., n,)], real-valued audio time series. Multi-channel is supported. sr : number > 0 [scalar] sampling rate of ``y`` S : np.ndarray [shape=(..., d, t)] or None (optional) complex STFT calculated using the other arguments provided to `__reassign_times` n_fft : int > 0 [scalar] FFT window size. Defaults to 2048. hop_length : int > 0 [scalar] hop length, number samples between subsequent frames. If not supplied, defaults to ``win_length // 4``. win_length : int > 0, <= n_fft Window length. Defaults to ``n_fft``. See `stft` for details. window : string, tuple, number, function, or np.ndarray [shape=(n_fft,)] - a window specification (string, tuple, number); see `scipy.signal.get_window` - a window function, such as `scipy.signal.windows.hann` - a user-specified window vector of length ``n_fft`` See `stft` for details. .. see also:: `filters.get_window` center : boolean - If ``True``, the signal ``y`` is padded so that frame ``S[:, t]`` is centered at ``y[t * hop_length]``. - If ``False``, then ``S[:, t]`` begins at ``y[t * hop_length]``. dtype : numeric type Complex numeric type for ``S``. Default is inferred to match the precision of the input signal. pad_mode : string If ``center=True``, the padding mode to use at the edges of the signal. By default, STFT uses zero padding. Returns ------- times : np.ndarray [shape=(..., 1 + n_fft/2, t), dtype=real] Reassigned times: ``times[f, t]`` is the time for bin ``f``, frame ``t``. S : np.ndarray [shape=(..., 1 + n_fft/2, t), dtype=complex] Short-time Fourier transform Warns ----- RuntimeWarning Time estimates with zero support will produce a divide-by-zero warning and will be returned as `np.nan`. See Also -------- stft : Short-time Fourier Transform reassigned_spectrogram : Time-frequency reassigned spectrogram Examples -------- >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> times, S = librosa.core.spectrum.__reassign_times(y, sr=sr) >>> times array([[ 2.268e-05, 1.144e-02, ..., 5.332e+00, 5.333e+00], [ 2.268e-05, 1.451e-02, ..., 5.334e+00, 5.333e+00], ..., [ 2.268e-05, -6.177e-04, ..., 5.368e+00, 5.327e+00], [ 2.268e-05, 1.420e-03, ..., 5.307e+00, 5.328e+00]]) """ # retrieve window samples if needed so that the time-weighted window can be # calculated if win_length is None: win_length = n_fft window = get_window(window, win_length, fftbins=True) window = util.pad_center(window, size=n_fft) # retrieve hop length if needed so that the frame times can be calculated if hop_length is None: hop_length = int(win_length // 4) if S is None: if dtype is None: dtype = util.dtype_r2c(y.dtype) S_h = stft( y=y, n_fft=n_fft, hop_length=hop_length, window=window, center=center, dtype=dtype, pad_mode=pad_mode, ) else: if dtype is None: dtype = S.dtype S_h = S # calculate window weighted by time half_width = n_fft // 2 if n_fft % 2: window_times = np.arange(-half_width, half_width + 1) else: window_times = np.arange(0.5 - half_width, half_width) window_time_weighted = window * window_times S_th = stft( y=y, n_fft=n_fft, hop_length=hop_length, window=window_time_weighted, center=center, dtype=dtype, pad_mode=pad_mode, ) # equation 5.23 of Flandrin, Auger, & Chassande-Mottin 2002 # the sign of the correction is reversed in some papers - see Plante, # Meyer, & Ainsworth 1998 pp. 283-284 correction = np.real(S_th / S_h) if center: pad_length = None else: pad_length = n_fft times = convert.frames_to_time( np.arange(S_h.shape[-1]), sr=sr, hop_length=hop_length, n_fft=pad_length ) times = util.expand_to(times, ndim=correction.ndim, axes=-1) + correction / sr return times, S_h
[docs]@deprecate_positional_args def reassigned_spectrogram( y, *, sr=22050, S=None, n_fft=2048, hop_length=None, win_length=None, window="hann", center=True, reassign_frequencies=True, reassign_times=True, ref_power=1e-6, fill_nan=False, clip=True, dtype=None, pad_mode="constant", ): r"""Time-frequency reassigned spectrogram. The reassignment vectors are calculated using equations 5.20 and 5.23 in [#]_:: t_reassigned = t + np.real(S_th/S_h) omega_reassigned = omega - np.imag(S_dh/S_h) where ``S_h`` is the complex STFT calculated using the original window, ``S_dh`` is the complex STFT calculated using the derivative of the original window, and ``S_th`` is the complex STFT calculated using the original window multiplied by the time offset from the window center. See [#]_ for additional algorithms, and [#]_ and [#]_ for history and discussion of the method. .. [#] Flandrin, P., Auger, F., & Chassande-Mottin, E. (2002). Time-Frequency reassignment: From principles to algorithms. In Applications in Time-Frequency Signal Processing (Vol. 10, pp. 179-204). CRC Press. .. [#] Fulop, S. A., & Fitz, K. (2006). Algorithms for computing the time-corrected instantaneous frequency (reassigned) spectrogram, with applications. The Journal of the Acoustical Society of America, 119(1), 360. doi:10.1121/1.2133000 .. [#] Auger, F., Flandrin, P., Lin, Y.-T., McLaughlin, S., Meignen, S., Oberlin, T., & Wu, H.-T. (2013). Time-Frequency Reassignment and Synchrosqueezing: An Overview. IEEE Signal Processing Magazine, 30(6), 32-41. doi:10.1109/MSP.2013.2265316 .. [#] Hainsworth, S., Macleod, M. (2003). Time-frequency reassignment: a review and analysis. Tech. Rep. CUED/FINFENG/TR.459, Cambridge University Engineering Department Parameters ---------- y : np.ndarray [shape=(..., n)], real-valued audio time series. Multi-channel is supported. sr : number > 0 [scalar] sampling rate of ``y`` S : np.ndarray [shape=(..., d, t)] or None (optional) complex STFT calculated using the other arguments provided to ``reassigned_spectrogram`` n_fft : int > 0 [scalar] FFT window size. Defaults to 2048. hop_length : int > 0 [scalar] hop length, number samples between subsequent frames. If not supplied, defaults to ``win_length // 4``. win_length : int > 0, <= n_fft Window length. Defaults to ``n_fft``. See `stft` for details. window : string, tuple, number, function, or np.ndarray [shape=(n_fft,)] - a window specification (string, tuple, number); see `scipy.signal.get_window` - a window function, such as `scipy.signal.windows.hann` - a user-specified window vector of length ``n_fft`` See `stft` for details. .. see also:: `filters.get_window` center : boolean - If ``True`` (default), the signal ``y`` is padded so that frame ``S[:, t]`` is centered at ``y[t * hop_length]``. See `Notes` for recommended usage in this function. - If ``False``, then ``S[:, t]`` begins at ``y[t * hop_length]``. reassign_frequencies : boolean - If ``True`` (default), the returned frequencies will be instantaneous frequency estimates. - If ``False``, the returned frequencies will be a read-only view of the STFT bin frequencies for all frames. reassign_times : boolean - If ``True`` (default), the returned times will be corrected (reassigned) time estimates for each bin. - If ``False``, the returned times will be a read-only view of the STFT frame times for all bins. ref_power : float >= 0 or callable Minimum power threshold for estimating time-frequency reassignments. Any bin with ``np.abs(S[f, t])**2 < ref_power`` will be returned as `np.nan` in both frequency and time, unless ``fill_nan`` is ``True``. If 0 is provided, then only bins with zero power will be returned as `np.nan` (unless ``fill_nan=True``). fill_nan : boolean - If ``False`` (default), the frequency and time reassignments for bins below the power threshold provided in ``ref_power`` will be returned as `np.nan`. - If ``True``, the frequency and time reassignments for these bins will be returned as the bin center frequencies and frame times. clip : boolean - If ``True`` (default), estimated frequencies outside the range `[0, 0.5 * sr]` or times outside the range `[0, len(y) / sr]` will be clipped to those ranges. - If ``False``, estimated frequencies and times beyond the bounds of the spectrogram may be returned. dtype : numeric type Complex numeric type for STFT calculation. Default is inferred to match the precision of the input signal. pad_mode : string If ``center=True``, the padding mode to use at the edges of the signal. By default, STFT uses zero padding. Returns ------- freqs, times, mags : np.ndarray [shape=(..., 1 + n_fft/2, t), dtype=real] Instantaneous frequencies: ``freqs[..., f, t]`` is the frequency for bin ``f``, frame ``t``. If ``reassign_frequencies=False``, this will instead be a read-only array of the same shape containing the bin center frequencies for all frames. Reassigned times: ``times[..., f, t]`` is the time for bin ``f``, frame ``t``. If ``reassign_times=False``, this will instead be a read-only array of the same shape containing the frame times for all bins. Magnitudes from short-time Fourier transform: ``mags[..., f, t]`` is the magnitude for bin ``f``, frame ``t``. Warns ----- RuntimeWarning Frequency or time estimates with zero support will produce a divide-by-zero warning, and will be returned as `np.nan` unless ``fill_nan=True``. See Also -------- stft : Short-time Fourier Transform Notes ----- It is recommended to use ``center=False`` with this function rather than the librosa default ``True``. Unlike ``stft``, reassigned times are not aligned to the left or center of each frame, so padding the signal does not affect the meaning of the reassigned times. However, reassignment assumes that the energy in each FFT bin is associated with exactly one signal component and impulse event. If ``reassign_times`` is ``False``, the frame times that are returned will be aligned to the left or center of the frame, depending on the value of ``center``. In this case, if ``center`` is ``True``, then ``pad_mode="wrap"`` is recommended for valid estimation of the instantaneous frequencies in the boundary frames. Examples -------- >>> import matplotlib.pyplot as plt >>> amin = 1e-10 >>> n_fft = 64 >>> sr = 4000 >>> y = 1e-3 * librosa.clicks(times=[0.3], sr=sr, click_duration=1.0, ... click_freq=1200.0, length=8000) +\ ... 1e-3 * librosa.clicks(times=[1.5], sr=sr, click_duration=0.5, ... click_freq=400.0, length=8000) +\ ... 1e-3 * librosa.chirp(fmin=200, fmax=1600, sr=sr, duration=2.0) +\ ... 1e-6 * np.random.randn(2*sr) >>> freqs, times, mags = librosa.reassigned_spectrogram(y=y, sr=sr, ... n_fft=n_fft) >>> mags_db = librosa.amplitude_to_db(mags, ref=np.max) >>> fig, ax = plt.subplots(nrows=2, sharex=True, sharey=True) >>> img = librosa.display.specshow(mags_db, x_axis="s", y_axis="linear", sr=sr, ... hop_length=n_fft//4, ax=ax[0]) >>> ax[0].set(title="Spectrogram", xlabel=None) >>> ax[0].label_outer() >>> ax[1].scatter(times, freqs, c=mags_db, cmap="magma", alpha=0.1, s=5) >>> ax[1].set_title("Reassigned spectrogram") >>> fig.colorbar(img, ax=ax, format="%+2.f dB") """ if not callable(ref_power) and ref_power < 0: raise ParameterError("ref_power must be non-negative or callable.") if not reassign_frequencies and not reassign_times: raise ParameterError("reassign_frequencies or reassign_times must be True.") if win_length is None: win_length = n_fft if hop_length is None: hop_length = int(win_length // 4) # frequency and time reassignment if requested if reassign_frequencies: freqs, S = __reassign_frequencies( y=y, sr=sr, S=S, n_fft=n_fft, hop_length=hop_length, win_length=win_length, window=window, center=center, dtype=dtype, pad_mode=pad_mode, ) if reassign_times: times, S = __reassign_times( y=y, sr=sr, S=S, n_fft=n_fft, hop_length=hop_length, win_length=win_length, window=window, center=center, dtype=dtype, pad_mode=pad_mode, ) mags = np.abs(S) # clean up reassignment issues: divide-by-zero, bins with near-zero power, # and estimates outside the spectrogram bounds # retrieve bin frequencies and frame times to replace missing estimates if fill_nan or not reassign_frequencies or not reassign_times: if center: pad_length = None else: pad_length = n_fft bin_freqs = convert.fft_frequencies(sr=sr, n_fft=n_fft) frame_times = convert.frames_to_time( frames=np.arange(S.shape[-1]), sr=sr, hop_length=hop_length, n_fft=pad_length, ) # find bins below the power threshold # reassigned bins with zero power will already be NaN if callable(ref_power): ref_power = ref_power(mags ** 2) mags_low = np.less(mags, ref_power ** 0.5, where=~np.isnan(mags)) # for reassigned estimates, optionally set thresholded bins to NaN, return # bin frequencies and frame times in place of NaN generated by # divide-by-zero and power threshold, and clip to spectrogram bounds if reassign_frequencies: if ref_power > 0: freqs[mags_low] = np.nan if fill_nan: freqs = np.where(np.isnan(freqs), bin_freqs[:, np.newaxis], freqs) if clip: np.clip(freqs, 0, sr / 2.0, out=freqs) # or if reassignment was not requested, return bin frequencies and frame # times for every cell is the spectrogram else: freqs = np.broadcast_to(bin_freqs[:, np.newaxis], S.shape) if reassign_times: if ref_power > 0: times[mags_low] = np.nan if fill_nan: times = np.where(np.isnan(times), frame_times[np.newaxis, :], times) if clip: np.clip(times, 0, y.shape[-1] / float(sr), out=times) else: times = np.broadcast_to(frame_times[np.newaxis, :], S.shape) return freqs, times, mags
[docs]@deprecate_positional_args def magphase(D, *, power=1): """Separate a complex-valued spectrogram D into its magnitude (S) and phase (P) components, so that ``D = S * P``. Parameters ---------- D : np.ndarray [shape=(..., d, t), dtype=complex] complex-valued spectrogram power : float > 0 Exponent for the magnitude spectrogram, e.g., 1 for energy, 2 for power, etc. Returns ------- D_mag : np.ndarray [shape=(..., d, t), dtype=real] magnitude of ``D``, raised to ``power`` D_phase : np.ndarray [shape=(..., d, t), dtype=complex] ``exp(1.j * phi)`` where ``phi`` is the phase of ``D`` Examples -------- >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> D = librosa.stft(y) >>> magnitude, phase = librosa.magphase(D) >>> magnitude array([[5.395e-03, 3.332e-03, ..., 9.862e-07, 1.201e-05], [3.244e-03, 2.690e-03, ..., 9.536e-07, 1.201e-05], ..., [7.523e-05, 3.722e-05, ..., 1.188e-04, 1.031e-03], [7.640e-05, 3.944e-05, ..., 5.180e-04, 1.346e-03]], dtype=float32) >>> phase array([[ 1. +0.000e+00j, 1. +0.000e+00j, ..., -1. -8.742e-08j, -1. -8.742e-08j], [-1. -8.742e-08j, -0.775-6.317e-01j, ..., -0.885-4.648e-01j, 0.472-8.815e-01j], ..., [ 1. -4.342e-12j, 0.028-9.996e-01j, ..., -0.222-9.751e-01j, -0.75 -6.610e-01j], [-1. -8.742e-08j, -1. -8.742e-08j, ..., 1. +0.000e+00j, 1. +0.000e+00j]], dtype=complex64) Or get the phase angle (in radians) >>> np.angle(phase) array([[ 0.000e+00, 0.000e+00, ..., -3.142e+00, -3.142e+00], [-3.142e+00, -2.458e+00, ..., -2.658e+00, -1.079e+00], ..., [-4.342e-12, -1.543e+00, ..., -1.794e+00, -2.419e+00], [-3.142e+00, -3.142e+00, ..., 0.000e+00, 0.000e+00]], dtype=float32) """ mag = np.abs(D) # Prevent NaNs and return magnitude 0, phase 1+0j for zero zeros_to_ones = mag == 0 mag_nonzero = mag + zeros_to_ones # Compute real and imaginary separately, because complex division can # produce NaNs when denormalized numbers are involved (< ~2e-39 for # complex64, ~5e-309 for complex128) phase = np.empty_like(D, dtype=util.dtype_r2c(D.dtype)) phase.real = D.real / mag_nonzero + zeros_to_ones phase.imag = D.imag / mag_nonzero mag **= power return mag, phase
[docs]@deprecate_positional_args def phase_vocoder(D, *, rate, hop_length=None, n_fft=None): """Phase vocoder. Given an STFT matrix D, speed up by a factor of ``rate`` Based on the implementation provided by [#]_. This is a simplified implementation, intended primarily for reference and pedagogical purposes. It makes no attempt to handle transients, and is likely to produce many audible artifacts. For a higher quality implementation, we recommend the RubberBand library [#]_ and its Python wrapper `pyrubberband`. .. [#] Ellis, D. P. W. "A phase vocoder in Matlab." Columbia University, 2002. http://www.ee.columbia.edu/~dpwe/resources/matlab/pvoc/ .. [#] https://breakfastquay.com/rubberband/ Examples -------- >>> # Play at double speed >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> D = librosa.stft(y, n_fft=2048, hop_length=512) >>> D_fast = librosa.phase_vocoder(D, rate=2.0, hop_length=512) >>> y_fast = librosa.istft(D_fast, hop_length=512) >>> # Or play at 1/3 speed >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> D = librosa.stft(y, n_fft=2048, hop_length=512) >>> D_slow = librosa.phase_vocoder(D, rate=1./3, hop_length=512) >>> y_slow = librosa.istft(D_slow, hop_length=512) Parameters ---------- D : np.ndarray [shape=(..., d, t), dtype=complex] STFT matrix rate : float > 0 [scalar] Speed-up factor: ``rate > 1`` is faster, ``rate < 1`` is slower. hop_length : int > 0 [scalar] or None The number of samples between successive columns of ``D``. If None, defaults to ``n_fft//4 = (D.shape[0]-1)//2`` n_fft : int > 0 or None The number of samples per frame in D. By default (None), this will be inferred from the shape of D. However, if D was constructed using an odd-length window, the correct frame length can be specified here. Returns ------- D_stretched : np.ndarray [shape=(..., d, t / rate), dtype=complex] time-stretched STFT See Also -------- pyrubberband """ if n_fft is None: n_fft = 2 * (D.shape[-2] - 1) if hop_length is None: hop_length = int(n_fft // 4) time_steps = np.arange(0, D.shape[-1], rate, dtype=np.float64) # Create an empty output array shape = list(D.shape) shape[-1] = len(time_steps) d_stretch = np.zeros_like(D, shape=shape) # Expected phase advance in each bin phi_advance = np.linspace(0, np.pi * hop_length, D.shape[-2]) # Phase accumulator; initialize to the first sample phase_acc = np.angle(D[..., 0]) # Pad 0 columns to simplify boundary logic padding = [(0, 0) for _ in D.shape] padding[-1] = (0, 2) D = np.pad(D, padding, mode="constant") for (t, step) in enumerate(time_steps): columns = D[..., int(step) : int(step + 2)] # Weighting for linear magnitude interpolation alpha = np.mod(step, 1.0) mag = (1.0 - alpha) * np.abs(columns[..., 0]) + alpha * np.abs(columns[..., 1]) # Store to output array d_stretch[..., t] = mag * np.exp(1.0j * phase_acc) # Compute phase advance dphase = np.angle(columns[..., 1]) - np.angle(columns[..., 0]) - phi_advance # Wrap to -pi:pi range dphase = dphase - 2.0 * np.pi * np.round(dphase / (2.0 * np.pi)) # Accumulate phase phase_acc += phi_advance + dphase return d_stretch
[docs]@deprecate_positional_args @cache(level=20) def iirt( y, *, sr=22050, win_length=2048, hop_length=None, center=True, tuning=0.0, pad_mode="constant", flayout="sos", res_type="kaiser_best", **kwargs, ): r"""Time-frequency representation using IIR filters This function will return a time-frequency representation using a multirate filter bank consisting of IIR filters. [#]_ First, ``y`` is resampled as needed according to the provided ``sample_rates``. Then, a filterbank with with ``n`` band-pass filters is designed. The resampled input signals are processed by the filterbank as a whole. (`scipy.signal.filtfilt` resp. `sosfiltfilt` is used to make the phase linear.) The output of the filterbank is cut into frames. For each band, the short-time mean-square power (STMSP) is calculated by summing ``win_length`` subsequent filtered time samples. When called with the default set of parameters, it will generate the TF-representation (pitch filterbank): * 85 filters with MIDI pitches [24, 108] as ``center_freqs``. * each filter having a bandwidth of one semitone. .. [#] Müller, Meinard. "Information Retrieval for Music and Motion." Springer Verlag. 2007. Parameters ---------- y : np.ndarray [shape=(..., n)] audio time series. Multi-channel is supported. sr : number > 0 [scalar] sampling rate of ``y`` win_length : int > 0, <= n_fft Window length. hop_length : int > 0 [scalar] Hop length, number samples between subsequent frames. If not supplied, defaults to ``win_length // 4``. center : boolean - If ``True``, the signal ``y`` is padded so that frame ``D[..., :, t]`` is centered at ``y[t * hop_length]``. - If ``False``, then `D[..., :, t]`` begins at ``y[t * hop_length]`` tuning : float [scalar] Tuning deviation from A440 in fractions of a bin. pad_mode : string If ``center=True``, the padding mode to use at the edges of the signal. By default, this function uses zero padding. flayout : string - If `sos` (default), a series of second-order filters is used for filtering with `scipy.signal.sosfiltfilt`. Minimizes numerical precision errors for high-order filters, but is slower. - If `ba`, the standard difference equation is used for filtering with `scipy.signal.filtfilt`. Can be unstable for high-order filters. res_type : string The resampling mode. See `librosa.resample` for details. **kwargs : additional keyword arguments Additional arguments for `librosa.filters.semitone_filterbank` (e.g., could be used to provide another set of ``center_freqs`` and ``sample_rates``). Returns ------- bands_power : np.ndarray [shape=(..., n, t), dtype=dtype] Short-time mean-square power for the input signal. Raises ------ ParameterError If ``flayout`` is not None, `ba`, or `sos`. See Also -------- librosa.filters.semitone_filterbank librosa.filters.mr_frequencies librosa.cqt scipy.signal.filtfilt scipy.signal.sosfiltfilt Examples -------- >>> import matplotlib.pyplot as plt >>> y, sr = librosa.load(librosa.ex('trumpet'), duration=3) >>> D = np.abs(librosa.iirt(y)) >>> C = np.abs(librosa.cqt(y=y, sr=sr)) >>> fig, ax = plt.subplots(nrows=2, sharex=True, sharey=True) >>> img = librosa.display.specshow(librosa.amplitude_to_db(C, ref=np.max), ... y_axis='cqt_hz', x_axis='time', ax=ax[0]) >>> ax[0].set(title='Constant-Q transform') >>> ax[0].label_outer() >>> img = librosa.display.specshow(librosa.amplitude_to_db(D, ref=np.max), ... y_axis='cqt_hz', x_axis='time', ax=ax[1]) >>> ax[1].set_title('Semitone spectrogram (iirt)') >>> fig.colorbar(img, ax=ax, format="%+2.0f dB") """ if flayout not in ("ba", "sos"): raise ParameterError("Unsupported flayout={}".format(flayout)) # check audio input util.valid_audio(y, mono=False) # Set the default hop, if it's not already specified if hop_length is None: hop_length = win_length // 4 # Pad the time series so that frames are centered if center: padding = [(0, 0) for _ in y.shape] padding[-1] = (win_length // 2, win_length // 2) y = np.pad(y, padding, mode=pad_mode) # get the semitone filterbank filterbank_ct, sample_rates = semitone_filterbank( tuning=tuning, flayout=flayout, **kwargs ) # create three downsampled versions of the audio signal y_resampled = [] y_srs = np.unique(sample_rates) for cur_sr in y_srs: y_resampled.append(resample(y, orig_sr=sr, target_sr=cur_sr, res_type=res_type)) # Compute the number of frames that will fit. The end may get truncated. n_frames = int(1 + (y.shape[-1] - win_length) // hop_length) # Pre-allocate the output array shape = list(y.shape) # Time dimension reduces to n_frames shape[-1] = n_frames # Insert a new axis at position -2 for filter response shape.insert(-1, len(filterbank_ct)) bands_power = np.empty_like(y, shape=shape) slices = [slice(None) for _ in bands_power.shape] for i, (cur_sr, cur_filter) in enumerate(zip(sample_rates, filterbank_ct)): slices[-2] = i # filter the signal cur_sr_idx = np.flatnonzero(y_srs == cur_sr)[0] if flayout == "ba": cur_filter_output = scipy.signal.filtfilt( cur_filter[0], cur_filter[1], y_resampled[cur_sr_idx], axis=-1 ) elif flayout == "sos": cur_filter_output = scipy.signal.sosfiltfilt( cur_filter, y_resampled[cur_sr_idx], axis=-1 ) factor = sr / cur_sr hop_length_STMSP = hop_length / factor win_length_STMSP_round = int(round(win_length / factor)) # hop_length_STMSP is used here as a floating-point number. # The discretization happens at the end to avoid accumulated rounding errors. start_idx = np.arange( 0, cur_filter_output.shape[-1] - win_length_STMSP_round, hop_length_STMSP ) if len(start_idx) < n_frames: min_length = ( int(np.ceil(n_frames * hop_length_STMSP)) + win_length_STMSP_round ) cur_filter_output = util.fix_length(cur_filter_output, size=min_length) start_idx = np.arange( 0, cur_filter_output.shape[-1] - win_length_STMSP_round, hop_length_STMSP, ) start_idx = np.round(start_idx).astype(int)[:n_frames] idx = np.add.outer(start_idx, np.arange(win_length_STMSP_round)) bands_power[tuple(slices)] = factor * np.sum( cur_filter_output[..., idx] ** 2, axis=-1 ) return bands_power
[docs]@deprecate_positional_args @cache(level=30) def power_to_db(S, *, ref=1.0, amin=1e-10, top_db=80.0): """Convert a power spectrogram (amplitude squared) to decibel (dB) units This computes the scaling ``10 * log10(S / ref)`` in a numerically stable way. Parameters ---------- S : np.ndarray input power ref : scalar or callable If scalar, the amplitude ``abs(S)`` is scaled relative to ``ref``:: 10 * log10(S / ref) Zeros in the output correspond to positions where ``S == ref``. If callable, the reference value is computed as ``ref(S)``. amin : float > 0 [scalar] minimum threshold for ``abs(S)`` and ``ref`` top_db : float >= 0 [scalar] threshold the output at ``top_db`` below the peak: ``max(10 * log10(S/ref)) - top_db`` Returns ------- S_db : np.ndarray ``S_db ~= 10 * log10(S) - 10 * log10(ref)`` See Also -------- perceptual_weighting db_to_power amplitude_to_db db_to_amplitude Notes ----- This function caches at level 30. Examples -------- Get a power spectrogram from a waveform ``y`` >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> S = np.abs(librosa.stft(y)) >>> librosa.power_to_db(S**2) array([[-41.809, -41.809, ..., -41.809, -41.809], [-41.809, -41.809, ..., -41.809, -41.809], ..., [-41.809, -41.809, ..., -41.809, -41.809], [-41.809, -41.809, ..., -41.809, -41.809]], dtype=float32) Compute dB relative to peak power >>> librosa.power_to_db(S**2, ref=np.max) array([[-80., -80., ..., -80., -80.], [-80., -80., ..., -80., -80.], ..., [-80., -80., ..., -80., -80.], [-80., -80., ..., -80., -80.]], dtype=float32) Or compare to median power >>> librosa.power_to_db(S**2, ref=np.median) array([[16.578, 16.578, ..., 16.578, 16.578], [16.578, 16.578, ..., 16.578, 16.578], ..., [16.578, 16.578, ..., 16.578, 16.578], [16.578, 16.578, ..., 16.578, 16.578]], dtype=float32) And plot the results >>> import matplotlib.pyplot as plt >>> fig, ax = plt.subplots(nrows=2, sharex=True, sharey=True) >>> imgpow = librosa.display.specshow(S**2, sr=sr, y_axis='log', x_axis='time', ... ax=ax[0]) >>> ax[0].set(title='Power spectrogram') >>> ax[0].label_outer() >>> imgdb = librosa.display.specshow(librosa.power_to_db(S**2, ref=np.max), ... sr=sr, y_axis='log', x_axis='time', ax=ax[1]) >>> ax[1].set(title='Log-Power spectrogram') >>> fig.colorbar(imgpow, ax=ax[0]) >>> fig.colorbar(imgdb, ax=ax[1], format="%+2.0f dB") """ S = np.asarray(S) if amin <= 0: raise ParameterError("amin must be strictly positive") if np.issubdtype(S.dtype, np.complexfloating): warnings.warn( "power_to_db was called on complex input so phase " "information will be discarded. To suppress this warning, " "call power_to_db(np.abs(D)**2) instead.", stacklevel=2, ) magnitude = np.abs(S) else: magnitude = S if callable(ref): # User supplied a function to calculate reference power ref_value = ref(magnitude) else: ref_value = np.abs(ref) log_spec = 10.0 * np.log10(np.maximum(amin, magnitude)) log_spec -= 10.0 * np.log10(np.maximum(amin, ref_value)) if top_db is not None: if top_db < 0: raise ParameterError("top_db must be non-negative") log_spec = np.maximum(log_spec, log_spec.max() - top_db) return log_spec
[docs]@deprecate_positional_args @cache(level=30) def db_to_power(S_db, *, ref=1.0): """Convert a dB-scale spectrogram to a power spectrogram. This effectively inverts ``power_to_db``:: db_to_power(S_db) ~= ref * 10.0**(S_db / 10) Parameters ---------- S_db : np.ndarray dB-scaled spectrogram ref : number > 0 Reference power: output will be scaled by this value Returns ------- S : np.ndarray Power spectrogram Notes ----- This function caches at level 30. """ return ref * np.power(10.0, 0.1 * S_db)
[docs]@deprecate_positional_args @cache(level=30) def amplitude_to_db(S, *, ref=1.0, amin=1e-5, top_db=80.0): """Convert an amplitude spectrogram to dB-scaled spectrogram. This is equivalent to ``power_to_db(S**2, ref=ref**2, amin=amin**2, top_db=top_db)``, but is provided for convenience. Parameters ---------- S : np.ndarray input amplitude ref : scalar or callable If scalar, the amplitude ``abs(S)`` is scaled relative to ``ref``: ``20 * log10(S / ref)``. Zeros in the output correspond to positions where ``S == ref``. If callable, the reference value is computed as ``ref(S)``. amin : float > 0 [scalar] minimum threshold for ``S`` and ``ref`` top_db : float >= 0 [scalar] threshold the output at ``top_db`` below the peak: ``max(20 * log10(S/ref)) - top_db`` Returns ------- S_db : np.ndarray ``S`` measured in dB See Also -------- power_to_db, db_to_amplitude Notes ----- This function caches at level 30. """ S = np.asarray(S) if np.issubdtype(S.dtype, np.complexfloating): warnings.warn( "amplitude_to_db was called on complex input so phase " "information will be discarded. To suppress this warning, " "call amplitude_to_db(np.abs(S)) instead.", stacklevel=2, ) magnitude = np.abs(S) if callable(ref): # User supplied a function to calculate reference power ref_value = ref(magnitude) else: ref_value = np.abs(ref) power = np.square(magnitude, out=magnitude) return power_to_db(power, ref=ref_value ** 2, amin=amin ** 2, top_db=top_db)
[docs]@deprecate_positional_args @cache(level=30) def db_to_amplitude(S_db, *, ref=1.0): """Convert a dB-scaled spectrogram to an amplitude spectrogram. This effectively inverts `amplitude_to_db`:: db_to_amplitude(S_db) ~= 10.0**(0.5 * S_db/10 + log10(ref)) Parameters ---------- S_db : np.ndarray dB-scaled spectrogram ref : number > 0 Optional reference power. Returns ------- S : np.ndarray Linear magnitude spectrogram Notes ----- This function caches at level 30. """ return db_to_power(S_db, ref=ref ** 2) ** 0.5
[docs]@deprecate_positional_args @cache(level=30) def perceptual_weighting(S, frequencies, *, kind="A", **kwargs): """Perceptual weighting of a power spectrogram:: S_p[..., f, :] = frequency_weighting(f, 'A') + 10*log(S[..., f, :] / ref) Parameters ---------- S : np.ndarray [shape=(..., d, t)] Power spectrogram frequencies : np.ndarray [shape=(d,)] Center frequency for each row of` `S`` kind : str The frequency weighting curve to use. e.g. `'A'`, `'B'`, `'C'`, `'D'`, `None or 'Z'` **kwargs : additional keyword arguments Additional keyword arguments to `power_to_db`. Returns ------- S_p : np.ndarray [shape=(..., d, t)] perceptually weighted version of ``S`` See Also -------- power_to_db Notes ----- This function caches at level 30. Examples -------- Re-weight a CQT power spectrum, using peak power as reference >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> C = np.abs(librosa.cqt(y, sr=sr, fmin=librosa.note_to_hz('A1'))) >>> freqs = librosa.cqt_frequencies(C.shape[0], ... fmin=librosa.note_to_hz('A1')) >>> perceptual_CQT = librosa.perceptual_weighting(C**2, ... freqs, ... ref=np.max) >>> perceptual_CQT array([[ -96.528, -97.101, ..., -108.561, -108.561], [ -95.88 , -96.479, ..., -107.551, -107.551], ..., [ -65.142, -53.256, ..., -80.098, -80.098], [ -71.542, -53.197, ..., -80.311, -80.311]]) >>> import matplotlib.pyplot as plt >>> fig, ax = plt.subplots(nrows=2, sharex=True, sharey=True) >>> img = librosa.display.specshow(librosa.amplitude_to_db(C, ... ref=np.max), ... fmin=librosa.note_to_hz('A1'), ... y_axis='cqt_hz', x_axis='time', ... ax=ax[0]) >>> ax[0].set(title='Log CQT power') >>> ax[0].label_outer() >>> imgp = librosa.display.specshow(perceptual_CQT, y_axis='cqt_hz', ... fmin=librosa.note_to_hz('A1'), ... x_axis='time', ax=ax[1]) >>> ax[1].set(title='Perceptually weighted log CQT') >>> fig.colorbar(img, ax=ax[0], format="%+2.0f dB") >>> fig.colorbar(imgp, ax=ax[1], format="%+2.0f dB") """ offset = convert.frequency_weighting(frequencies, kind=kind).reshape((-1, 1)) return offset + power_to_db(S, **kwargs)
[docs]@deprecate_positional_args @cache(level=30) def fmt(y, *, t_min=0.5, n_fmt=None, kind="cubic", beta=0.5, over_sample=1, axis=-1): """The fast Mellin transform (FMT) The Mellin of a signal `y` is performed by interpolating `y` on an exponential time axis, applying a polynomial window, and then taking the discrete Fourier transform. When the Mellin parameter (beta) is 1/2, it is also known as the scale transform. [#]_ The scale transform can be useful for audio analysis because its magnitude is invariant to scaling of the domain (e.g., time stretching or compression). This is analogous to the magnitude of the Fourier transform being invariant to shifts in the input domain. .. [#] De Sena, Antonio, and Davide Rocchesso. "A fast Mellin and scale transform." EURASIP Journal on Applied Signal Processing 2007.1 (2007): 75-75. .. [#] Cohen, L. "The scale representation." IEEE Transactions on Signal Processing 41, no. 12 (1993): 3275-3292. Parameters ---------- y : np.ndarray, real-valued The input signal(s). Can be multidimensional. The target axis must contain at least 3 samples. t_min : float > 0 The minimum time spacing (in samples). This value should generally be less than 1 to preserve as much information as possible. n_fmt : int > 2 or None The number of scale transform bins to use. If None, then ``n_bins = over_sample * ceil(n * log((n-1)/t_min))`` is taken, where ``n = y.shape[axis]`` kind : str The type of interpolation to use when re-sampling the input. See `scipy.interpolate.interp1d` for possible values. Note that the default is to use high-precision (cubic) interpolation. This can be slow in practice; if speed is preferred over accuracy, then consider using ``kind='linear'``. beta : float The Mellin parameter. ``beta=0.5`` provides the scale transform. over_sample : float >= 1 Over-sampling factor for exponential resampling. axis : int The axis along which to transform ``y`` Returns ------- x_scale : np.ndarray [dtype=complex] The scale transform of ``y`` along the ``axis`` dimension. Raises ------ ParameterError if ``n_fmt < 2`` or ``t_min <= 0`` or if ``y`` is not finite or if ``y.shape[axis] < 3``. Notes ----- This function caches at level 30. Examples -------- >>> # Generate a signal and time-stretch it (with energy normalization) >>> scale = 1.25 >>> freq = 3.0 >>> x1 = np.linspace(0, 1, num=1024, endpoint=False) >>> x2 = np.linspace(0, 1, num=int(scale * len(x1)), endpoint=False) >>> y1 = np.sin(2 * np.pi * freq * x1) >>> y2 = np.sin(2 * np.pi * freq * x2) / np.sqrt(scale) >>> # Verify that the two signals have the same energy >>> np.sum(np.abs(y1)**2), np.sum(np.abs(y2)**2) (255.99999999999997, 255.99999999999969) >>> scale1 = librosa.fmt(y1, n_fmt=512) >>> scale2 = librosa.fmt(y2, n_fmt=512) >>> # And plot the results >>> import matplotlib.pyplot as plt >>> fig, ax = plt.subplots(nrows=2) >>> ax[0].plot(y1, label='Original') >>> ax[0].plot(y2, linestyle='--', label='Stretched') >>> ax[0].set(xlabel='time (samples)', title='Input signals') >>> ax[0].legend() >>> ax[1].semilogy(np.abs(scale1), label='Original') >>> ax[1].semilogy(np.abs(scale2), linestyle='--', label='Stretched') >>> ax[1].set(xlabel='scale coefficients', title='Scale transform magnitude') >>> ax[1].legend() >>> # Plot the scale transform of an onset strength autocorrelation >>> y, sr = librosa.load(librosa.ex('choice')) >>> odf = librosa.onset.onset_strength(y=y, sr=sr) >>> # Auto-correlate with up to 10 seconds lag >>> odf_ac = librosa.autocorrelate(odf, max_size=10 * sr // 512) >>> # Normalize >>> odf_ac = librosa.util.normalize(odf_ac, norm=np.inf) >>> # Compute the scale transform >>> odf_ac_scale = librosa.fmt(librosa.util.normalize(odf_ac), n_fmt=512) >>> # Plot the results >>> fig, ax = plt.subplots(nrows=3) >>> ax[0].plot(odf, label='Onset strength') >>> ax[0].set(xlabel='Time (frames)', title='Onset strength') >>> ax[1].plot(odf_ac, label='Onset autocorrelation') >>> ax[1].set(xlabel='Lag (frames)', title='Onset autocorrelation') >>> ax[2].semilogy(np.abs(odf_ac_scale), label='Scale transform magnitude') >>> ax[2].set(xlabel='scale coefficients') """ n = y.shape[axis] if n < 3: raise ParameterError("y.shape[{:}]=={:} < 3".format(axis, n)) if t_min <= 0: raise ParameterError("t_min must be a positive number") if n_fmt is None: if over_sample < 1: raise ParameterError("over_sample must be >= 1") # The base is the maximum ratio between adjacent samples # Since the sample spacing is increasing, this is simply the # ratio between the positions of the last two samples: (n-1)/(n-2) log_base = np.log(n - 1) - np.log(n - 2) n_fmt = int(np.ceil(over_sample * (np.log(n - 1) - np.log(t_min)) / log_base)) elif n_fmt < 3: raise ParameterError("n_fmt=={:} < 3".format(n_fmt)) else: log_base = (np.log(n_fmt - 1) - np.log(n_fmt - 2)) / over_sample if not np.all(np.isfinite(y)): raise ParameterError("y must be finite everywhere") base = np.exp(log_base) # original grid: signal covers [0, 1). This range is arbitrary, but convenient. # The final sample is positioned at (n-1)/n, so we omit the endpoint x = np.linspace(0, 1, num=n, endpoint=False) # build the interpolator f_interp = scipy.interpolate.interp1d(x, y, kind=kind, axis=axis) # build the new sampling grid # exponentially spaced between t_min/n and 1 (exclusive) # we'll go one past where we need, and drop the last sample # When over-sampling, the last input sample contributions n_over samples. # To keep the spacing consistent, we over-sample by n_over, and then # trim the final samples. n_over = int(np.ceil(over_sample)) x_exp = np.logspace( (np.log(t_min) - np.log(n)) / log_base, 0, num=n_fmt + n_over, endpoint=False, base=base, )[:-n_over] # Clean up any rounding errors at the boundaries of the interpolation # The interpolator gets angry if we try to extrapolate, so clipping is necessary here. if x_exp[0] < t_min or x_exp[-1] > float(n - 1.0) / n: x_exp = np.clip(x_exp, float(t_min) / n, x[-1]) # Make sure that all sample points are unique # This should never happen! if len(np.unique(x_exp)) != len(x_exp): raise ParameterError("Redundant sample positions in Mellin transform") # Resample the signal y_res = f_interp(x_exp) # Broadcast the window correctly shape = [1] * y_res.ndim shape[axis] = -1 # Apply the window and fft # Normalization is absorbed into the window here for expedience fft = get_fftlib() return fft.rfft( y_res * ((x_exp ** beta).reshape(shape) * np.sqrt(n) / n_fmt), axis=axis )
[docs]@deprecate_positional_args @cache(level=30) def pcen( S, *, sr=22050, hop_length=512, gain=0.98, bias=2, power=0.5, time_constant=0.400, eps=1e-6, b=None, max_size=1, ref=None, axis=-1, max_axis=None, zi=None, return_zf=False, ): """Per-channel energy normalization (PCEN) This function normalizes a time-frequency representation ``S`` by performing automatic gain control, followed by nonlinear compression [#]_ :: P[f, t] = (S / (eps + M[f, t])**gain + bias)**power - bias**power IMPORTANT: the default values of eps, gain, bias, and power match the original publication, in which ``S`` is a 40-band mel-frequency spectrogram with 25 ms windowing, 10 ms frame shift, and raw audio values in the interval [-2**31; 2**31-1[. If you use these default values, we recommend to make sure that the raw audio is properly scaled to this interval, and not to [-1, 1[ as is most often the case. The matrix ``M`` is the result of applying a low-pass, temporal IIR filter to ``S``:: M[f, t] = (1 - b) * M[f, t - 1] + b * S[f, t] If ``b`` is not provided, it is calculated as:: b = (sqrt(1 + 4* T**2) - 1) / (2 * T**2) where ``T = time_constant * sr / hop_length``. [#]_ This normalization is designed to suppress background noise and emphasize foreground signals, and can be used as an alternative to decibel scaling (`amplitude_to_db`). This implementation also supports smoothing across frequency bins by specifying ``max_size > 1``. If this option is used, the filtered spectrogram ``M`` is computed as:: M[f, t] = (1 - b) * M[f, t - 1] + b * R[f, t] where ``R`` has been max-filtered along the frequency axis, similar to the SuperFlux algorithm implemented in `onset.onset_strength`:: R[f, t] = max(S[f - max_size//2: f + max_size//2, t]) This can be used to perform automatic gain control on signals that cross or span multiple frequency bans, which may be desirable for spectrograms with high frequency resolution. .. [#] Wang, Y., Getreuer, P., Hughes, T., Lyon, R. F., & Saurous, R. A. (2017, March). Trainable frontend for robust and far-field keyword spotting. In Acoustics, Speech and Signal Processing (ICASSP), 2017 IEEE International Conference on (pp. 5670-5674). IEEE. .. [#] Lostanlen, V., Salamon, J., McFee, B., Cartwright, M., Farnsworth, A., Kelling, S., and Bello, J. P. Per-Channel Energy Normalization: Why and How. IEEE Signal Processing Letters, 26(1), 39-43. Parameters ---------- S : np.ndarray (non-negative) The input (magnitude) spectrogram sr : number > 0 [scalar] The audio sampling rate hop_length : int > 0 [scalar] The hop length of ``S``, expressed in samples gain : number >= 0 [scalar] The gain factor. Typical values should be slightly less than 1. bias : number >= 0 [scalar] The bias point of the nonlinear compression (default: 2) power : number >= 0 [scalar] The compression exponent. Typical values should be between 0 and 0.5. Smaller values of ``power`` result in stronger compression. At the limit ``power=0``, polynomial compression becomes logarithmic. time_constant : number > 0 [scalar] The time constant for IIR filtering, measured in seconds. eps : number > 0 [scalar] A small constant used to ensure numerical stability of the filter. b : number in [0, 1] [scalar] The filter coefficient for the low-pass filter. If not provided, it will be inferred from ``time_constant``. max_size : int > 0 [scalar] The width of the max filter applied to the frequency axis. If left as `1`, no filtering is performed. ref : None or np.ndarray (shape=S.shape) An optional pre-computed reference spectrum (``R`` in the above). If not provided it will be computed from ``S``. axis : int [scalar] The (time) axis of the input spectrogram. max_axis : None or int [scalar] The frequency axis of the input spectrogram. If `None`, and ``S`` is two-dimensional, it will be inferred as the opposite from ``axis``. If ``S`` is not two-dimensional, and ``max_size > 1``, an error will be raised. zi : np.ndarray The initial filter delay values. This may be the ``zf`` (final delay values) of a previous call to ``pcen``, or computed by `scipy.signal.lfilter_zi`. return_zf : bool If ``True``, return the final filter delay values along with the PCEN output ``P``. This is primarily useful in streaming contexts, where the final state of one block of processing should be used to initialize the next block. If ``False`` (default) only the PCEN values ``P`` are returned. Returns ------- P : np.ndarray, non-negative [shape=(n, m)] The per-channel energy normalized version of ``S``. zf : np.ndarray (optional) The final filter delay values. Only returned if ``return_zf=True``. See Also -------- amplitude_to_db librosa.onset.onset_strength Examples -------- Compare PCEN to log amplitude (dB) scaling on Mel spectra >>> import matplotlib.pyplot as plt >>> y, sr = librosa.load(librosa.ex('robin')) >>> # We recommend scaling y to the range [-2**31, 2**31[ before applying >>> # PCEN's default parameters. Furthermore, we use power=1 to get a >>> # magnitude spectrum instead of a power spectrum. >>> S = librosa.feature.melspectrogram(y=y, sr=sr, power=1) >>> log_S = librosa.amplitude_to_db(S, ref=np.max) >>> pcen_S = librosa.pcen(S * (2**31)) >>> fig, ax = plt.subplots(nrows=2, sharex=True, sharey=True) >>> img = librosa.display.specshow(log_S, x_axis='time', y_axis='mel', ax=ax[0]) >>> ax[0].set(title='log amplitude (dB)', xlabel=None) >>> ax[0].label_outer() >>> imgpcen = librosa.display.specshow(pcen_S, x_axis='time', y_axis='mel', ax=ax[1]) >>> ax[1].set(title='Per-channel energy normalization') >>> fig.colorbar(img, ax=ax[0], format="%+2.0f dB") >>> fig.colorbar(imgpcen, ax=ax[1]) Compare PCEN with and without max-filtering >>> pcen_max = librosa.pcen(S * (2**31), max_size=3) >>> fig, ax = plt.subplots(nrows=2, sharex=True, sharey=True) >>> librosa.display.specshow(pcen_S, x_axis='time', y_axis='mel', ax=ax[0]) >>> ax[0].set(title='Per-channel energy normalization (no max-filter)') >>> ax[0].label_outer() >>> img = librosa.display.specshow(pcen_max, x_axis='time', y_axis='mel', ax=ax[1]) >>> ax[1].set(title='Per-channel energy normalization (max_size=3)') >>> fig.colorbar(img, ax=ax) """ if power < 0: raise ParameterError("power={} must be nonnegative".format(power)) if gain < 0: raise ParameterError("gain={} must be non-negative".format(gain)) if bias < 0: raise ParameterError("bias={} must be non-negative".format(bias)) if eps <= 0: raise ParameterError("eps={} must be strictly positive".format(eps)) if time_constant <= 0: raise ParameterError( "time_constant={} must be strictly positive".format(time_constant) ) if max_size < 1 or not isinstance(max_size, (int, np.integer)): raise ParameterError("max_size={} must be a positive integer".format(max_size)) if b is None: t_frames = time_constant * sr / float(hop_length) # By default, this solves the equation for b: # b**2 + (1 - b) / t_frames - 2 = 0 # which approximates the full-width half-max of the # squared frequency response of the IIR low-pass filter b = (np.sqrt(1 + 4 * t_frames ** 2) - 1) / (2 * t_frames ** 2) if not 0 <= b <= 1: raise ParameterError("b={} must be between 0 and 1".format(b)) if np.issubdtype(S.dtype, np.complexfloating): warnings.warn( "pcen was called on complex input so phase " "information will be discarded. To suppress this warning, " "call pcen(np.abs(D)) instead.", stacklevel=2, ) S = np.abs(S) if ref is None: if max_size == 1: ref = S elif S.ndim == 1: raise ParameterError( "Max-filtering cannot be applied to 1-dimensional input" ) else: if max_axis is None: if S.ndim != 2: raise ParameterError( "Max-filtering a {:d}-dimensional spectrogram " "requires you to specify max_axis".format(S.ndim) ) # if axis = 0, max_axis=1 # if axis = +- 1, max_axis = 0 max_axis = np.mod(1 - axis, 2) ref = scipy.ndimage.maximum_filter1d(S, max_size, axis=max_axis) if zi is None: # Make sure zi matches dimension to input shape = tuple([1] * ref.ndim) zi = np.empty(shape) zi[:] = scipy.signal.lfilter_zi([b], [1, b - 1])[:] # Temporal integration S_smooth, zf = scipy.signal.lfilter([b], [1, b - 1], ref, zi=zi, axis=axis) # Adaptive gain control # Working in log-space gives us some stability, and a slight speedup smooth = np.exp(-gain * (np.log(eps) + np.log1p(S_smooth / eps))) # Dynamic range compression if power == 0: S_out = np.log1p(S * smooth) elif bias == 0: S_out = np.exp(power * (np.log(S) + np.log(smooth))) else: S_out = (bias ** power) * np.expm1(power * np.log1p(S * smooth / bias)) if return_zf: return S_out, zf else: return S_out
[docs]@deprecate_positional_args def griffinlim( S, *, n_iter=32, hop_length=None, win_length=None, n_fft=None, window="hann", center=True, dtype=None, length=None, pad_mode="constant", momentum=0.99, init="random", random_state=None, ): """Approximate magnitude spectrogram inversion using the "fast" Griffin-Lim algorithm. Given a short-time Fourier transform magnitude matrix (``S``), the algorithm randomly initializes phase estimates, and then alternates forward- and inverse-STFT operations. [#]_ Note that this assumes reconstruction of a real-valued time-domain signal, and that ``S`` contains only the non-negative frequencies (as computed by `stft`). The "fast" GL method [#]_ uses a momentum parameter to accelerate convergence. .. [#] D. W. Griffin and J. S. Lim, "Signal estimation from modified short-time Fourier transform," IEEE Trans. ASSP, vol.32, no.2, pp.236–243, Apr. 1984. .. [#] Perraudin, N., Balazs, P., & Søndergaard, P. L. "A fast Griffin-Lim algorithm," IEEE Workshop on Applications of Signal Processing to Audio and Acoustics (pp. 1-4), Oct. 2013. Parameters ---------- S : np.ndarray [shape=(..., n_fft // 2 + 1, t), non-negative] An array of short-time Fourier transform magnitudes as produced by `stft`. n_iter : int > 0 The number of iterations to run hop_length : None or int > 0 The hop length of the STFT. If not provided, it will default to ``n_fft // 4`` win_length : None or int > 0 The window length of the STFT. By default, it will equal ``n_fft`` n_fft : None or int > 0 The number of samples per frame. By default, this will be inferred from the shape of ``S`` as an even number. However, if an odd frame length was used, you can explicitly set ``n_fft``. window : string, tuple, number, function, or np.ndarray [shape=(n_fft,)] A window specification as supported by `stft` or `istft` center : boolean If ``True``, the STFT is assumed to use centered frames. If ``False``, the STFT is assumed to use left-aligned frames. dtype : np.dtype Real numeric type for the time-domain signal. Default is inferred to match the precision of the input spectrogram. length : None or int > 0 If provided, the output ``y`` is zero-padded or clipped to exactly ``length`` samples. pad_mode : string If ``center=True``, the padding mode to use at the edges of the signal. By default, STFT uses zero padding. momentum : number >= 0 The momentum parameter for fast Griffin-Lim. Setting this to 0 recovers the original Griffin-Lim method [1]_. Values near 1 can lead to faster convergence, but above 1 may not converge. init : None or 'random' [default] If 'random' (the default), then phase values are initialized randomly according to ``random_state``. This is recommended when the input ``S`` is a magnitude spectrogram with no initial phase estimates. If `None`, then the phase is initialized from ``S``. This is useful when an initial guess for phase can be provided, or when you want to resume Griffin-Lim from a previous output. random_state : None, int, or np.random.RandomState If int, random_state is the seed used by the random number generator for phase initialization. If `np.random.RandomState` instance, the random number generator itself. If `None`, defaults to the current `np.random` object. Returns ------- y : np.ndarray [shape=(..., n)] time-domain signal reconstructed from ``S`` See Also -------- stft istft magphase filters.get_window Examples -------- A basic STFT inverse example >>> y, sr = librosa.load(librosa.ex('trumpet')) >>> # Get the magnitude spectrogram >>> S = np.abs(librosa.stft(y)) >>> # Invert using Griffin-Lim >>> y_inv = librosa.griffinlim(S) >>> # Invert without estimating phase >>> y_istft = librosa.istft(S) Wave-plot the results >>> import matplotlib.pyplot as plt >>> fig, ax = plt.subplots(nrows=3, sharex=True, sharey=True) >>> librosa.display.waveshow(y, sr=sr, color='b', ax=ax[0]) >>> ax[0].set(title='Original', xlabel=None) >>> ax[0].label_outer() >>> librosa.display.waveshow(y_inv, sr=sr, color='g', ax=ax[1]) >>> ax[1].set(title='Griffin-Lim reconstruction', xlabel=None) >>> ax[1].label_outer() >>> librosa.display.waveshow(y_istft, sr=sr, color='r', ax=ax[2]) >>> ax[2].set_title('Magnitude-only istft reconstruction') """ if random_state is None: rng = np.random elif isinstance(random_state, int): rng = np.random.RandomState(seed=random_state) elif isinstance(random_state, np.random.RandomState): rng = random_state if momentum > 1: warnings.warn( "Griffin-Lim with momentum={} > 1 can be unstable. " "Proceed with caution!".format(momentum), stacklevel=2, ) elif momentum < 0: raise ParameterError( "griffinlim() called with momentum={} < 0".format(momentum) ) # Infer n_fft from the spectrogram shape if n_fft is None: n_fft = 2 * (S.shape[-2] - 1) # using complex64 will keep the result to minimal necessary precision angles = np.empty(S.shape, dtype=np.complex64) eps = util.tiny(angles) if init == "random": # randomly initialize the phase angles[:] = np.exp(2j * np.pi * rng.rand(*S.shape)) elif init is None: # Initialize an all ones complex matrix angles[:] = 1.0 else: raise ParameterError("init={} must either None or 'random'".format(init)) # And initialize the previous iterate to 0 rebuilt = 0.0 for _ in range(n_iter): # Store the previous iterate tprev = rebuilt # Invert with our current estimate of the phases inverse = istft( S * angles, hop_length=hop_length, win_length=win_length, n_fft=n_fft, window=window, center=center, dtype=dtype, length=length, ) # Rebuild the spectrogram rebuilt = stft( inverse, n_fft=n_fft, hop_length=hop_length, win_length=win_length, window=window, center=center, pad_mode=pad_mode, ) # Update our phase estimates angles[:] = rebuilt - (momentum / (1 + momentum)) * tprev angles[:] /= np.abs(angles) + eps # Return the final phase estimates return istft( S * angles, hop_length=hop_length, win_length=win_length, n_fft=n_fft, window=window, center=center, dtype=dtype, length=length, )
def _spectrogram( *, y=None, S=None, n_fft=2048, hop_length=512, power=1, win_length=None, window="hann", center=True, pad_mode="constant", ): """Helper function to retrieve a magnitude spectrogram. This is primarily used in feature extraction functions that can operate on either audio time-series or spectrogram input. Parameters ---------- y : None or np.ndarray If provided, an audio time series S : None or np.ndarray Spectrogram input, optional n_fft : int > 0 STFT window size hop_length : int > 0 STFT hop length power : float > 0 Exponent for the magnitude spectrogram, e.g., 1 for energy, 2 for power, etc. win_length : int <= n_fft [scalar] Each frame of audio is windowed by ``window``. The window will be of length ``win_length`` and then padded with zeros to match ``n_fft``. If unspecified, defaults to ``win_length = n_fft``. window : string, tuple, number, function, or np.ndarray [shape=(n_fft,)] - a window specification (string, tuple, or number); see `scipy.signal.get_window` - a window function, such as `scipy.signal.windows.hann` - a vector or array of length ``n_fft`` .. see also:: `filters.get_window` center : boolean - If ``True``, the signal ``y`` is padded so that frame ``t`` is centered at ``y[t * hop_length]``. - If ``False``, then frame ``t`` begins at ``y[t * hop_length]`` pad_mode : string If ``center=True``, the padding mode to use at the edges of the signal. By default, STFT uses zero padding. Returns ------- S_out : np.ndarray [dtype=np.float] - If ``S`` is provided as input, then ``S_out == S`` - Else, ``S_out = |stft(y, ...)|**power`` n_fft : int > 0 - If ``S`` is provided, then ``n_fft`` is inferred from ``S`` - Else, copied from input """ if S is not None: # Infer n_fft from spectrogram shape, but only if it mismatches if n_fft // 2 + 1 != S.shape[-2]: n_fft = 2 * (S.shape[-2] - 1) else: # Otherwise, compute a magnitude spectrogram from input S = ( np.abs( stft( y, n_fft=n_fft, hop_length=hop_length, win_length=win_length, center=center, window=window, pad_mode=pad_mode, ) ) ** power ) return S, n_fft