pyautoencoder 1.1.5

A Python package offering implementations of state-of-the-art autoencoder architectures in PyTorch.

PyAutoencoder

A clean, modular PyTorch-based library for building and training autoencoders.

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Highlights

PyAutoencoder is designed to offer simple and easy access to autoencoder frameworks. Here's what it offers:

• Minimal, composable API
  You don't have to inherit from complicated base classes or learn a new training loop. Simply provide your own PyTorch nn.Module encoder and decoder, and plug them into the ready‑to‑use autoencoder wrappers. This makes it easy to experiment with different architectures (e.g. MLPs, CNNs) while reusing the same training pipeline.

• Ready‑to‑use autoencoders The library ships with working implementations of autoencoders, each paired with their respective loss functions. You can start training in a few lines, without re‑implementing reconstruction likelihoods, KL divergence, or other boilerplate.

• PyTorch compatibility
  The library is fully compatible with the PyTorch ecosystem, so models integrate naturally with modules, tensors, optimizers, and schedulers.

• Lightweight, research‑oriented
  The library is intentionally minimal: no training loop frameworks, no heavy abstractions. This makes it well suited for research prototypes where you want control and transparency.

Status: The project is in an early but usable stage. Contributions, issues, and feedback are highly encouraged!

Currently implemented:

• Autoencoder (AE)
• Variational Autoencoder (VAE)
• Adaptive Group Variational Autoencoder (Ada-GVAE)

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Documentation

Full documentation (installation, tutorials, API reference, and examples) is available at:

👉 https://pyautoencoder.readthedocs.io/en/latest/

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Installation

pip install pyautoencoder

Or install from source for development:

git clone https://github.com/andrea-pollastro/pyautoencoder.git
cd pyautoencoder
pip install -e .

Quick start

import torch
import torch.nn as nn
from pyautoencoder.variational import VAE

# Define encoder/decoder
latent_dim = 32
encoder = nn.Sequential(
    nn.Linear(784, 512), 
    nn.ReLU(),
)

decoder = nn.Sequential(
    nn.Linear(latent_dim, 512), 
    nn.ReLU(),
    nn.Linear(512, 784)
)

# Model
vae = VAE(encoder=encoder, decoder=decoder, latent_dim=latent_dim)

optimizer = torch.optim.Adam(vae.parameters())
for x in dataloader:
    optimizer.zero_grad()
    out = vae(x)
    loss_results = vae.compute_loss(x, out, beta=1, likelihood='bernoulli')
    loss_results.objective.backward() # negative ELBO
    optimizer.step()
    # optional: log components
    log_likelihood = loss_results.diagnostics["log_likelihood"]
    kl_divergence = loss_results.diagnostics["kl_divergence"]

Examples

The examples/ directory contains runnable scripts, including:

• mnist_ae.py – standard Autoencoder on MNIST
• mnist_vae_kingma2013.py – reproduction of the MNIST VAE experiment from Kingma & Welling (2013), Fig. 2

These examples are also documented and explained in the online documentation.

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License

This project is released under the MIT License. See LICENSE.

Citation

If you use this package in academic work, please cite:

@article{pollastro2025sincvae,
  title={SincVAE: A new semi-supervised approach to improve anomaly detection on EEG data using SincNet and variational autoencoder},
  author={Pollastro, Andrea and Isgr{\`o}, Francesco and Prevete, Roberto},
  journal={Computer Methods and Programs in Biomedicine Update},
  pages={100213},
  year={2025},
  publisher={Elsevier}
}

Acknowledgments

This work was funded by the PNRR MUR project PE0000013-FAIR (CUP: E63C25000630006).