Loss Landscapes of Regularized Linear Autoencoders

Daniel Kunin, Jonathan Bloom, Aleksandrina Goeva, Cotton Seed

ICML 2019 pp. 3560-3569

/icml/2019/kunin2019icml-loss/

Abstract

Autoencoders are a deep learning model for representation learning. When trained to minimize the distance between the data and its reconstruction, linear autoencoders (LAEs) learn the subspace spanned by the top principal directions but cannot learn the principal directions themselves. In this paper, we prove that $L_2$-regularized LAEs are symmetric at all critical points and learn the principal directions as the left singular vectors of the decoder. We smoothly parameterize the critical manifold and relate the minima to the MAP estimate of probabilistic PCA. We illustrate these results empirically and consider implications for PCA algorithms, computational neuroscience, and the algebraic topology of learning.

PDF ICML Semantic Scholar

Cite

Text

Kunin et al. "Loss Landscapes of Regularized Linear Autoencoders." International Conference on Machine Learning, 2019.

Markdown

[Kunin et al. "Loss Landscapes of Regularized Linear Autoencoders." International Conference on Machine Learning, 2019.](https://mlanthology.org/icml/2019/kunin2019icml-loss/)

BibTeX

@inproceedings{kunin2019icml-loss,
  title     = {{Loss Landscapes of Regularized Linear Autoencoders}},
  author    = {Kunin, Daniel and Bloom, Jonathan and Goeva, Aleksandrina and Seed, Cotton},
  booktitle = {International Conference on Machine Learning},
  year      = {2019},
  pages     = {3560-3569},
  volume    = {97},
  url       = {https://mlanthology.org/icml/2019/kunin2019icml-loss/}
}