Approximate Newton-based statistical inference using only stochastic gradients
Abstract
We present a novel statistical inference framework for convex empirical risk minimization, using approximate stochastic Newton steps. The proposed algorithm is based on the notion of finite differences and allows the approximation of a Hessian-vector product from first-order information. In theory, our method efficiently computes the statistical error covariance in -estimation, both for unregularized convex learning problems and high-dimensional LASSO regression, without using exact second order information, or resampling the entire data set. We also present a stochastic gradient sampling scheme for statistical inference in non-i.i.d. time series analysis, where we sample contiguous blocks of indices. In practice, we demonstrate the effectiveness of our framework on large-scale machine learning problems, that go even beyond convexity: as a highlight, our work can be used to detect certain adversarial attacks on neural networks.
Cite
@article{arxiv.1805.08920,
title = {Approximate Newton-based statistical inference using only stochastic gradients},
author = {Tianyang Li and Anastasios Kyrillidis and Liu Liu and Constantine Caramanis},
journal= {arXiv preprint arXiv:1805.08920},
year = {2019}
}