English

Relative stability toward diffeomorphisms indicates performance in deep nets

Machine Learning 2022-12-07 v3 Computer Vision and Pattern Recognition

Abstract

Understanding why deep nets can classify data in large dimensions remains a challenge. It has been proposed that they do so by becoming stable to diffeomorphisms, yet existing empirical measurements support that it is often not the case. We revisit this question by defining a maximum-entropy distribution on diffeomorphisms, that allows to study typical diffeomorphisms of a given norm. We confirm that stability toward diffeomorphisms does not strongly correlate to performance on benchmark data sets of images. By contrast, we find that the stability toward diffeomorphisms relative to that of generic transformations RfR_f correlates remarkably with the test error ϵt\epsilon_t. It is of order unity at initialization but decreases by several decades during training for state-of-the-art architectures. For CIFAR10 and 15 known architectures, we find ϵt0.2Rf\epsilon_t\approx 0.2\sqrt{R_f}, suggesting that obtaining a small RfR_f is important to achieve good performance. We study how RfR_f depends on the size of the training set and compare it to a simple model of invariant learning.

Keywords

Cite

@article{arxiv.2105.02468,
  title  = {Relative stability toward diffeomorphisms indicates performance in deep nets},
  author = {Leonardo Petrini and Alessandro Favero and Mario Geiger and Matthieu Wyart},
  journal= {arXiv preprint arXiv:2105.02468},
  year   = {2022}
}

Comments

NeurIPS 2021 Conference

R2 v1 2026-06-24T01:49:41.350Z