How Hard Is Robust Mean Estimation?
Abstract
Robust mean estimation is the problem of estimating the mean of a -dimensional distribution from a list of independent samples, an -fraction of which have been arbitrarily corrupted by a malicious adversary. Recent algorithmic progress has resulted in the first polynomial-time algorithms which achieve \emph{dimension-independent} rates of error: for instance, if has covariance , in polynomial-time one may find with . However, error rates achieved by current polynomial-time algorithms, while dimension-independent, are sub-optimal in many natural settings, such as when is sub-Gaussian, or has bounded -th moments. In this work we give worst-case complexity-theoretic evidence that improving on the error rates of current polynomial-time algorithms for robust mean estimation may be computationally intractable in natural settings. We show that several natural approaches to improving error rates of current polynomial-time robust mean estimation algorithms would imply efficient algorithms for the small-set expansion problem, refuting Raghavendra and Steurer's small-set expansion hypothesis (so long as ). We also give the first direct reduction to the robust mean estimation problem, starting from a plausible but nonstandard variant of the small-set expansion problem.
Cite
@article{arxiv.1903.07870,
title = {How Hard Is Robust Mean Estimation?},
author = {Samuel B. Hopkins and Jerry Li},
journal= {arXiv preprint arXiv:1903.07870},
year = {2019}
}
Comments
Conference on Learning Theory (COLT) 2019