This repository contains the NNabla implementation of Open-Unmix, a deep neural network reference implementation for music source separation, applicable for researchers, audio engineers and artists. Open-Unmix provides ready-to-use models that allow users to separate pop music into four stems: vocals, drums, bass and the remaining other instruments.
umx
or umx-hq
in your work, use the pytorch version for now. See the current implementation status here
Related Projects: open-unmix-pytorch | open-unmix-nnabla | musdb | museval | norbert
Open-Unmix is based on a three-layer bidirectional deep LSTM. The model learns to predict the magnitude spectrogram of a target, like vocals, from the magnitude spectrogram of a mixture input. Internally, the prediction is obtained by applying a mask on the input. The model is optimized in the magnitude domain using mean squared error and the actual separation is done in a post-processing step involving a multichannel wiener filter implemented using norbert. To perform separation into multiple sources, multiple models are trained for each particular target. While this makes the training less comfortable, it allows great flexibility to customize the training data for each target source.
Open-Unmix operates in the time-frequency domain to perform its prediction. The input of the model is either:
- A time domain signal tensor of shape
(nb_samples, nb_channels, nb_timesteps)
, wherenb_samples
are the samples in a batch,nb_channels
is 1 or 2 for mono or stereo audio, respectively, andnb_timesteps
is the number of audio samples in the recording.
In that case, the model computes spectrograms with nnabla STFT
on the fly.
- Alternatively open-unmix also takes magnitude spectrograms directly (e.g. when pre-computed and loaded from disk).
In that case, the input is of shape (nb_frames, nb_samples, nb_channels, nb_bins)
, where nb_frames
and nb_bins
are the time and frequency-dimensions of a Short-Time-Fourier-Transform.
The input spectrogram is standardized using the global mean and standard deviation for every frequency bin across all frames. Furthermore, we apply batch normalization in multiple stages of the model to make the training more robust against gain variation.
The LSTM is not operating on the original input spectrogram resolution. Instead, in the first step after the normalization, the network learns to compresses the frequency and channel axis of the model to reduce redundancy and make the model converge faster.
The core of open-unmix is a three layer bidirectional LSTM network. Due to its recurrent nature, the model can be trained and evaluated on arbitrary length of audio signals. Since the model takes information from past and future simultaneously, the model cannot be used in an online/real-time manner. An uni-directional model can easily be trained as described here.
After applying the LSTM, the signal is decoded back to its original input dimensionality. In the last steps the output is multiplied with the input magnitude spectrogram, so that the models is asked to learn a mask.
Inference is not supported right now and will be added later.
For installation we recommend to use the Anaconda python distribution. To create a conda environment for open-unmix, simply run:
conda env create -f environment-X.yml
where X
is either [cpu
, gpu
], depending on your system.
- we favored simplicity over performance to promote clearness of the code. The rationale is to have open-unmix serve as a baseline for future research while performance still meets current state-of-the-art (See Evaluation). The results are comparable/better to those of
UHL1
/UHL2
which obtained the best performance over all systems trained on MUSDB18 in the SiSEC 2018 Evaluation campaign. - We designed the code to allow researchers to reproduce existing results, quickly develop new architectures and add own user data for training and testing. We favored framework specifics implementations instead of having a monolithic repository.
- open-unmix is a community focused project, we therefore encourage the community to submit bug-fixes and comments and improve the computational performance. However, we are not looking for changes that only focused on improving the performance.
Fabian-Robert Stöter, Antoine Liutkus, Inria and LIRMM, Montpellier, France
If you use open-unmix for your research – Cite Open-Unmix
@article{stoter19,
author={F.-R. St\\"oter and S. Uhlich and A. Liutkus and Y. Mitsufuji},
title={Open-unmix: a reference implementation for source separation},
journal={Journal of Open Source Software},
year=2019,
note={submitted}}
}
If you use the MUSDB dataset for your research - Cite the MUSDB18 Dataset
@misc{MUSDB18,
author = {Rafii, Zafar and
Liutkus, Antoine and
Fabian-Robert St{\"o}ter and
Mimilakis, Stylianos Ioannis and
Bittner, Rachel},
title = {The {MUSDB18} corpus for music separation},
month = dec,
year = 2017,
doi = {10.5281/zenodo.1117372},
url = {https://doi.org/10.5281/zenodo.1117372}
}
If compare your results with SiSEC 2018 Participants - Cite the SiSEC 2018 LVA/ICA Paper
@inproceedings{SiSEC18,
author="St{\"o}ter, Fabian-Robert and Liutkus, Antoine and Ito, Nobutaka",
title="The 2018 Signal Separation Evaluation Campaign",
booktitle="Latent Variable Analysis and Signal Separation:
14th International Conference, LVA/ICA 2018, Surrey, UK",
year="2018",
pages="293--305"
}
MIT