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Principal Bit Analysis: Autoencoding with Schur-Concave Loss

Information Theory 2021-06-09 v2 Computer Vision and Pattern Recognition Machine Learning math.IT

Abstract

We consider a linear autoencoder in which the latent variables are quantized, or corrupted by noise, and the constraint is Schur-concave in the set of latent variances. Although finding the optimal encoder/decoder pair for this setup is a nonconvex optimization problem, we show that decomposing the source into its principal components is optimal. If the constraint is strictly Schur-concave and the empirical covariance matrix has only simple eigenvalues, then any optimal encoder/decoder must decompose the source in this way. As one application, we consider a strictly Schur-concave constraint that estimates the number of bits needed to represent the latent variables under fixed-rate encoding, a setup that we call \emph{Principal Bit Analysis (PBA)}. This yields a practical, general-purpose, fixed-rate compressor that outperforms existing algorithms. As a second application, we show that a prototypical autoencoder-based variable-rate compressor is guaranteed to decompose the source into its principal components.

Keywords

Cite

@article{arxiv.2106.02796,
  title  = {Principal Bit Analysis: Autoencoding with Schur-Concave Loss},
  author = {Sourbh Bhadane and Aaron B. Wagner and Jayadev Acharya},
  journal= {arXiv preprint arXiv:2106.02796},
  year   = {2021}
}

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ICML 2021

R2 v1 2026-06-24T02:51:42.284Z