Adversarially Robust Learning: A Generic Minimax Optimal Learner and Characterization
Abstract
We present a minimax optimal learner for the problem of learning predictors robust to adversarial examples at test-time. Interestingly, we find that this requires new algorithmic ideas and approaches to adversarially robust learning. In particular, we show, in a strong negative sense, the suboptimality of the robust learner proposed by Montasser, Hanneke, and Srebro (2019) and a broader family of learners we identify as local learners. Our results are enabled by adopting a global perspective, specifically, through a key technical contribution: the global one-inclusion graph, which may be of independent interest, that generalizes the classical one-inclusion graph due to Haussler, Littlestone, and Warmuth (1994). Finally, as a byproduct, we identify a dimension characterizing qualitatively and quantitatively what classes of predictors are robustly learnable. This resolves an open problem due to Montasser et al. (2019), and closes a (potentially) infinite gap between the established upper and lower bounds on the sample complexity of adversarially robust learning.
Cite
@article{arxiv.2209.07369,
title = {Adversarially Robust Learning: A Generic Minimax Optimal Learner and Characterization},
author = {Omar Montasser and Steve Hanneke and Nathan Srebro},
journal= {arXiv preprint arXiv:2209.07369},
year = {2022}
}
Comments
To appear in NeurIPS 2022