English

Diagnosing and Fixing Manifold Overfitting in Deep Generative Models

Machine Learning 2022-11-30 v4 Artificial Intelligence Machine Learning Methodology

Abstract

Likelihood-based, or explicit, deep generative models use neural networks to construct flexible high-dimensional densities. This formulation directly contradicts the manifold hypothesis, which states that observed data lies on a low-dimensional manifold embedded in high-dimensional ambient space. In this paper we investigate the pathologies of maximum-likelihood training in the presence of this dimensionality mismatch. We formally prove that degenerate optima are achieved wherein the manifold itself is learned but not the distribution on it, a phenomenon we call manifold overfitting. We propose a class of two-step procedures consisting of a dimensionality reduction step followed by maximum-likelihood density estimation, and prove that they recover the data-generating distribution in the nonparametric regime, thus avoiding manifold overfitting. We also show that these procedures enable density estimation on the manifolds learned by implicit models, such as generative adversarial networks, hence addressing a major shortcoming of these models. Several recently proposed methods are instances of our two-step procedures; we thus unify, extend, and theoretically justify a large class of models.

Keywords

Cite

@article{arxiv.2204.07172,
  title  = {Diagnosing and Fixing Manifold Overfitting in Deep Generative Models},
  author = {Gabriel Loaiza-Ganem and Brendan Leigh Ross and Jesse C. Cresswell and Anthony L. Caterini},
  journal= {arXiv preprint arXiv:2204.07172},
  year   = {2022}
}

Comments

Accepted for publication in TMLR

R2 v1 2026-06-24T10:48:35.587Z