Here we provide the inference repository. The training code is at the following github repo
Check the biodenoising web page for demos and more info.
The proposed model is based on the Demucs architecture, originally proposed for music source-separation and real-time speech enhancement.
We publish the pre-print on arXiv.
If you want to play with the pretrained model inside colab for instance, start from this Colab Example for Biodenoising.
First, install Python >= 3.8 (recommended with miniconda).
Just run
pip install biodenoising_inference
Clone this repository and install the dependencies. We recommend using a fresh virtualenv or Conda environment.
git clone https://github.com/earthspecies/biodenoising-inference-internal
cd biodenoising-inference-internal
pip install -r requirements.txt
If you want to use biodenoising
live, you will
need a specific loopback audio interface.
On Mac OS X, this is provided by [Soundflower][soundflower]. First install Soundflower, and then you can just run
python -m biodenoising.denoiser.live
In your favorite video conference call application, just select "Soundflower (2ch)" as input to enjoy your denoised speech.
Watch our live demo presentation in the following link: [Demo][demo].
You can use the pacmd
command and the pavucontrol
tool:
- run the following commands:
pacmd load-module module-null-sink sink_name=denoiser
pacmd update-sink-proplist denoiser device.description=denoiser
This will add a Monitor of Null Output
to the list of microphones to use. Select it as input in your software.
- Launch the
pavucontrol
tool. In the Playback tab, after launchingpython -m biodenoising.denoiser.live --out INDEX_OR_NAME_OF_LOOPBACK_IFACE
and the software you want to denoise for (here an in-browser call), you should see both applications. For denoiser interface as Playback destination which will output the processed audio stream on the sink we previously created.
At the moment, we do not provide official support for other OSes. However, if you
have a a soundcard that supports loopback (for instance Steinberg products), you can try
to make it work. You can list the available audio interfaces with python -m sounddevice
.
Then once you have spotted your loopback interface, just run
python -m biodenoising.denoiser.live --out INDEX_OR_NAME_OF_LOOPBACK_IFACE
By default, biodenoising
will use the default audio input. You can change that with the --in
flag.
Note that on Windows you will need to replace python
by python.exe
.
This is from the original denoiser implementation:
denoiser
can introduce distortions for very high level of noises.
Audio can become crunchy if your computer is not fast enough to process audio in real time.
In that case, you will see an error message in your terminal warning you that denoiser
is not processing audio fast enough. You can try exiting all non required applications.
denoiser
was tested on a Mac Book Pro with an 2GHz quadcore Intel i5 with DDR4 memory.
You might experience issues with DDR3 memory. In that case you can trade overall latency for speed by processing multiple frames at once. To do so, run
python -m biodenoising.denoiser.live -f 2
You can increase to -f 3
or more if needed, but each increase will add 16ms of extra latency.
You can also denoise received speech, but you won't be able to both denoise your own speech and the received speech (unless you have a really beefy computer and enough loopback audio interfaces). This can be achieved by selecting the loopback interface as the audio output of your VC software and then running
python -m biodenoising.denoiser.live --in "Soundflower (2ch)" --out "NAME OF OUT IFACE"
The way experiments are automatically named, as explained hereafter.
Generating the denoised files can be done by:
python -m biodenoising.denoiser.denoise --input=<path to the dir with the noisy files> --output=<path to store enhanced files>
Notice, you can either provide noisy_dir
or noisy_json
for the test data.
Note that the path given to --model_path
should be obtained from one of the best.th
file, not checkpoint.th
.
It is also possible to use pre-trained model, using --dns48
.
For more details regarding possible arguments, please see:
usage: biodenoising.denoiser.denoise [-h] [-m MODEL_PATH | --dns48 ]
[--device DEVICE] [--dry DRY]
[--num_workers NUM_WORKERS] [--streaming]
[--output OUT_DIR] [--batch_size BATCH_SIZE] [-v]
[--input NOISY_DIR]
Speech enhancement using biodenoising - Generate enhanced files
optional arguments:
-h, --help show this help message and exit
-m MODEL_PATH, --model_path MODEL_PATH
Path to local trained model.
--dns48 Use pre-trained real time H=48 model trained on biodenoising-datasets.
--device DEVICE
--dry DRY dry/wet knob coefficient. 0 is only input signal, 1
only denoised.
--num_workers NUM_WORKERS
--streaming true streaming evaluation for biodenoising
--output OUT_DIR directory putting enhanced wav files
--batch_size BATCH_SIZE
batch size
-v, --verbose more loggging
--input NOISY_DIR
directory including noisy wav files
This is from the original denoiser implementation:
Our online implementation is based on pure python code with some optimization of the streaming convolutions and transposed convolutions. We benchmark this implementation on a quad-core Intel i5 CPU at 2 GHz. The Real-Time Factor (RTF) of the proposed models are:
Model | Threads | RTF |
---|---|---|
H=48 | 1 | 0.8 |
H=48 | 4 | 0.6 |
In order to compute the RTF on your own CPU launch the following command:
python -m biodenoising.denoiser.demucs --hidden=48 --num_threads=1
The output should be something like this:
total lag: 41.3ms, stride: 16.0ms, time per frame: 12.2ms, delta: 0.21%, RTF: 0.8
Feel free to explore different settings, i.e. bigger models and more CPU-cores.
If you use the code in your research, then please cite it as:
@misc{miron2024biodenoisinganimalvocalizationdenoising,
title={Biodenoising: animal vocalization denoising without access to clean data},
author={Marius Miron and Sara Keen and Jen-Yu Liu and Benjamin Hoffman and Masato Hagiwara and Olivier Pietquin and Felix Effenberger and Maddie Cusimano},
year={2024},
eprint={2410.03427},
archivePrefix={arXiv},
primaryClass={cs.SD},
url={https://arxiv.org/abs/2410.03427},
}
This model is released under the CC-BY-NC 4.0. license as found in the LICENSE file.