A fully-convolution GAN-based model to generate mel-spectrogram of audio samples.

The mel-spectrogram is in a (1, mel filter, time frame) format and can be converted back to audio waveform using mel-spectrogram inverter like HiFi-GAN, Wavenet etc. The model architecture is inspired by DCGAN [1] and is conditioned by discrete variables. It is trained as a Wasserstein GAN with gradient penalty [2]. Some hints and tricks were adopted from a NIPS 2016 workshop [3]. As a nomenclature, this model is called CWGAN-GP.

Refer to requirements.txt

Frechet Audio Distance is used in Evaluate.py, and the link to the github repository for this metric (including setup) is available in the same script.

Just in case, python>=3.9 is desired to support Python's multiprocessing libraries.

The training parameters and mel-spectrogram configurations are within a .yaml file. The yaml file can be customized by editing the parameters in it and load it using argparser.

To train the model:

python train_CWGANGP.py --config <.yaml configuration file>

To train the model from a checkpoint:

python train_CWGANGP.py --config <.yaml configuration file> --checkpoint <checkpoint file> --load_from_checkpoint

To generate mel-spectrogram samples with drill force 1 and drill angle 0 with CUDA:

python CWGANGP_generate.py --config <.yaml configuration file> --model <trained model file> --num_gen <number of generation> --drill_force 1 --drill_angle 0 --use_cuda

For this repository, the Griffin-Lim algorithm is used to invert the mel-spectrogram back to the audio waveform. The drill_force and drill_angle can be replaced with other conditions to suit one's application.

To score the mel-spectrogram generator w.r.t. real samples using Frechet Inception Distance (FID) and Frechet Audio Distance (FAD):

python Evaluate.py --FID_real <dir of real mel-spec images> --FID_fake <dir of fake mel-spec images> --FAD_real <dir of real audio samples> --FAD_fake <dir of fake audio samples>

This is an experimental model consisting of 8 lightweight CWGAN-GP generating 8 separate strips (1, mel filter, time frame / 8) constituting the whole mel-spectrogram. When run sequentially, each network generates mel-spectrogram about 10 times faster than a single deep CWGAN-GP. The goal is to run this network in parallel during inferencing under a single CPU/GPU. However, when using Python's multiprocessing module, particularly ThreadPoolExecutor and the map function, it performed slower than the original CWGAN-GP, due to the use of a single core. Using multiple processes did not fare much better because each network needs to be copied into each process.

[1] Radford et al., Unsupervised Representation Learning with Deep Convolutional Generative Adversarial Networks, paper
[2] Gulrajani et al., Improved Training of Wasserstein GANs, paper
[3] Soumith et al., How to train a GAN?, link