| Metadata-Version: 2.1 | |
| Name: lws | |
| Version: 1.2.8 | |
| Summary: Fast spectrogram phase reconstruction using Local Weighted Sums | |
| Home-page: https://github.com/Jonathan-LeRoux/lws | |
| Download-URL: https://github.com/Jonathan-LeRoux/lws/archive/1.2.8.tar.gz | |
| Author: Jonathan Le Roux | |
| Author-email: leroux@merl.com | |
| License: Apache 2.0 | |
| Keywords: phase,reconstruction,stft,short-term Fourier Transform,spectrogram | |
| Classifier: Programming Language :: Python | |
| Classifier: Intended Audience :: Developers | |
| Classifier: Topic :: Multimedia :: Sound/Audio :: Analysis | |
| Classifier: Programming Language :: Python :: 2 | |
| Classifier: Programming Language :: Python :: 2.7 | |
| Classifier: Programming Language :: Python :: 3 | |
| Classifier: Programming Language :: Python :: 3.5 | |
| Classifier: Programming Language :: Python :: 3.6 | |
| Classifier: Programming Language :: Python :: 3.7 | |
| Classifier: Programming Language :: Python :: 3.8 | |
| Classifier: Programming Language :: Python :: 3.9 | |
| Classifier: Programming Language :: Python :: 3.10 | |
| Classifier: Programming Language :: Python :: 3.11 | |
| Classifier: Programming Language :: Python :: 3.12 | |
| Classifier: Programming Language :: Python :: 3.13 | |
| Description-Content-Type: text/markdown | |
| Requires-Dist: numpy | |
| LWS | |
| === | |
| ### Fast spectrogram phase recovery using Local Weighted Sums ### | |
| Author: Jonathan Le Roux -- 2008-2023 | |
| [](https://badge.fury.io/py/lws) | |
| LWS is a C/C++ library for which this package is a Python wrapper. | |
| A Matlab/Mex wrapper is also available. | |
| License | |
| ------- | |
| Copyright (C) 2008-2023 Jonathan Le Roux | |
| Apache 2.0 (http://www.apache.org/licenses/LICENSE-2.0) | |
| Citing this code | |
| ---------------- | |
| If you use this code, please cite the following papers: | |
| ### Batch LWS ### | |
| Jonathan Le Roux, Hirokazu Kameoka, Nobutaka Ono, Shigeki Sagayama, | |
| "Fast Signal Reconstruction from Magnitude STFT Spectrogram Based on Spectrogram Consistency," | |
| in Proc. International Conference on Digital Audio Effects (DAFx), pp. 397--403, Sep. 2010. | |
| @InProceedings{LeRoux2010DAFx09, | |
| author = {Jonathan {Le Roux} and Hirokazu Kameoka and Nobutaka Ono and Shigeki Sagayama}, | |
| title = {Fast Signal Reconstruction from Magnitude {STFT} Spectrogram Based on Spectrogram Consistency}, | |
| booktitle = {Proc. International Conference on Digital Audio Effects (DAFx)}, | |
| year = 2010, | |
| pages = {397--403}, | |
| month = sep | |
| } | |
| ### Online LWS, "No future" LWS ### | |
| Jonathan Le Roux, Hirokazu Kameoka, Nobutaka Ono, Shigeki Sagayama, | |
| "Phase initialization schemes for faster spectrogram-consistency-based signal reconstruction," | |
| in Proc. of ASJ Autumn Meeting, 3-10-3, Sep. 2010. | |
| @InProceedings{LeRoux2010ASJ09, | |
| author = {Jonathan {Le Roux} and Hirokazu Kameoka and Nobutaka Ono and Shigeki Sagayama}, | |
| title = {Phase Initialization Schemes for Faster Spectrogram-Consistency-Based Signal Reconstruction}, | |
| year = 2010, | |
| booktitle = {Proc. Acoustical Society of Japan Autumn Meeting (ASJ)}, | |
| number = {3-10-3}, | |
| month = mar | |
| } | |
| Installation: | |
| ------------- | |
| 1) The easiest way to install `lws` is via `pip`: | |
| ```sh | |
| pip install lws | |
| ``` | |
| 2) To compile from source using cython (required if one modifies the code): | |
| ```sh | |
| cd python | |
| LWS_USE_CYTHON=1 make | |
| ``` | |
| 3) To compile from source using the pre-generated c source file (which was obtained with cython): | |
| ```sh | |
| cd python | |
| make | |
| ``` | |
| 4) Alternatively, one can first use cython to create a tarball, which can then be installed with pip: | |
| ```sh | |
| cd python | |
| make sdist | |
| pip install dist/lws-1.2.7.tar.gz | |
| ``` | |
| **Note:** On Windows, the Microsoft Visual C++ Compiler for your version of Python needs to be installed. See [this page](https://wiki.python.org/moin/WindowsCompilers) for more details. | |
| Usage | |
| ----- | |
| ```python | |
| import lws | |
| import numpy as np | |
| lws_processor=lws.lws(512,128, mode="speech") # 512: window length; 128: window shift | |
| X = lws_processor.stft(x) # where x is a single-channel waveform | |
| X0 = np.abs(X) # Magnitude spectrogram | |
| print('{:6}: {:5.2f} dB'.format('Abs(X)', lws_processor.get_consistency(X0))) | |
| X1 = lws_processor.run_lws(X0) # reconstruction from magnitude (in general, one can reconstruct from an initial complex spectrogram) | |
| print('{:6}: {:5.2f} dB'.format('LWS', lws_processor.get_consistency(X1))) | |
| ``` | |
| Options | |
| ------- | |
| ```python | |
| lws_processor=lws.lws(awin_or_fsize, fshift, L = 5, swin = None, look_ahead = 3, | |
| nofuture_iterations = 0, nofuture_alpha = 1, nofuture_beta = 0.1, nofuture_gamma = 1, | |
| online_iterations = 0, online_alpha = 1, online_beta = 0.1, online_gamma = 1, | |
| batch_iterations = 100, batch_alpha = 100, batch_beta = 0.1, batch_gamma = 1, | |
| symmetric_win = True, mode= None, fftsize=None, perfectrec=True) | |
| ``` | |
| * `awin_or_fsize`: either the analysis window, or a window length (in which case the sqrt(hann) window is used); the analysis window should be symmetric for the computations to be correct. | |
| * `fshift`: window shift | |
| * `L`: approximation order in the phase reconstruction algorithm, 5 should be good. | |
| * `swin`: synthesis window (if None, it gets computed from the analysis window for perfect reconstruction) | |
| * `look_ahead`: number of look-ahead frames in RTISI-LA-like algorithm, 3 should be good. | |
| * `xxx_iterations`, `xxx_alpha`, `xxx_beta`, `xxx_gamma`: number of iterations of algorithm xxx (where xxx is one of `nofuture`, `online`, or `batch`), and parameters alpha/beta/gamma of the decreasing sparsity curve that is used to determine which bins get updated at each iteration. Any bin with magnitude larger than a given threshold is updated, others are ignored (`thresholds = alpha * np.exp(- beta * np.arange(iterations)**gamma)`) | |
| * `symmetric_win`: determines whether to use a symmetric hann window or not | |
| * `mode`: `None`, `'speech'`, or `'music'`. This sets default numbers of iterations of each algorithm that seem to be good for speech and music signals. Disclaimer: your mileage may vary. | |
| * `fftsize`: can be set longer than frame size to do 0-padding in the FFT. Note that 0-padding will be done symmetrically on the left and right of the window to enforce symmetry in the analysis window. | |
| * `perfectrec`: whether to pad with zeros on each side to ensure perfect reconstruction at the boundaries too. | |
| Three steps are implemented, and they can be turned on/off independently by appropriately setting the corresponding number of iterations: | |
| * "no future" LWS: phase initialization using LWS updates that only involve past frames | |
| * online LWS: phase estimation using online LWS updates, corresponding to a fast time-frequency domain version of RTISI-LA | |
| * LWS: phase estimation using batch LWS updates on the whole spectrogram | |
| Remarks | |
| ------- | |
| 1) The .cpp files are actually C code with some C99 style comments, but the .cpp extension is needed on Windows for mex to acknowledge the c99 flag (with .c, it is discarded, and -ansi used instead, leading to compilation errors) | |
| 2) Because the module is a C extension, it cannot be reloaded (see <http://bugs.python.org/issue1144263>). In Jupyter Notebooks, in particular, autoreload will not work, and the kernel has to be restarted. | |
| Acknowledgements | |
| ---------------- | |
| The recipe to wrap the LWS C code as a python module was largely inspired by Martin Sosic's post: http://martinsosic.com/development/2016/02/08/wrapping-c-library-as-python-module.html | |