English

On the Maximum Hessian Eigenvalue and Generalization

Machine Learning 2023-05-25 v3 Machine Learning

Abstract

The mechanisms by which certain training interventions, such as increasing learning rates and applying batch normalization, improve the generalization of deep networks remains a mystery. Prior works have speculated that "flatter" solutions generalize better than "sharper" solutions to unseen data, motivating several metrics for measuring flatness (particularly λmax\lambda_{max}, the largest eigenvalue of the Hessian of the loss); and algorithms, such as Sharpness-Aware Minimization (SAM) [1], that directly optimize for flatness. Other works question the link between λmax\lambda_{max} and generalization. In this paper, we present findings that call λmax\lambda_{max}'s influence on generalization further into question. We show that: (1) while larger learning rates reduce λmax\lambda_{max} for all batch sizes, generalization benefits sometimes vanish at larger batch sizes; (2) by scaling batch size and learning rate simultaneously, we can change λmax\lambda_{max} without affecting generalization; (3) while SAM produces smaller λmax\lambda_{max} for all batch sizes, generalization benefits (also) vanish with larger batch sizes; (4) for dropout, excessively high dropout probabilities can degrade generalization, even as they promote smaller λmax\lambda_{max}; and (5) while batch-normalization does not consistently produce smaller λmax\lambda_{max}, it nevertheless confers generalization benefits. While our experiments affirm the generalization benefits of large learning rates and SAM for minibatch SGD, the GD-SGD discrepancy demonstrates limits to λmax\lambda_{max}'s ability to explain generalization in neural networks.

Keywords

Cite

@article{arxiv.2206.10654,
  title  = {On the Maximum Hessian Eigenvalue and Generalization},
  author = {Simran Kaur and Jeremy Cohen and Zachary C. Lipton},
  journal= {arXiv preprint arXiv:2206.10654},
  year   = {2023}
}

Comments

Proceedings on "I Can't Believe It's Not Better! - Understanding Deep Learning Through Empirical Falsification" at NeurIPS 2022 Workshops, PMLR 187:51-65, 2023

R2 v1 2026-06-24T11:59:05.211Z