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We developed a Bayesian autoencoder using amortized MCMC for efficient inference. This model enhances dynamic representation learning and generative tasks with flexible priors and improved scalability.

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Area of Science:

  • Machine Learning
  • Artificial Intelligence
  • Computational Statistics

Background:

  • Autoencoders are powerful tools for representation learning but often lack probabilistic rigor.
  • Existing Bayesian autoencoder models can suffer from high inference costs.
  • Integrating Gaussian Processes with autoencoders has shown promise but faces scalability challenges.

Purpose of the Study:

  • To introduce a fully Bayesian autoencoder model with efficient inference.
  • To enable flexible prior specifications and posterior approximations.
  • To enhance scalability and handle complex data structures like missing values.

Main Methods:

  • A fully Bayesian autoencoder treating local latent variables and global parameters probabilistically.
  • Amortized Markov Chain Monte Carlo (MCMC) using implicit stochastic networks for posterior sampling.
  • Incorporation of Sparse Gaussian Process (GP) and Deep Gaussian Process (DGP) priors on the latent space.

Main Results:

  • Demonstrated low inference costs with flexible priors and posterior approximations.
  • Achieved improved scalability through Bayesian treatment of GP inducing points and hyperparameters.
  • Showcased strong performance in dynamic representation learning and generative modeling tasks.

Conclusions:

  • The proposed Bayesian autoencoder offers a robust and scalable framework for representation and generative learning.
  • The model effectively handles complex priors and missing data, outperforming existing GP-autoencoder hybrids.
  • This work advances probabilistic deep learning by integrating advanced Bayesian nonparametrics.