Near-Linear Sample Complexity for $L_p$ Polynomial Regression
Abstract
We study polynomial regression. Given query access to a function , the goal is to find a degree polynomial such that, for a given parameter , Here is the norm, . We show that querying at points randomly drawn from the Chebyshev measure on is a near-optimal strategy for polynomial regression in all norms. In particular, to find , it suffices to sample points from with probabilities proportional to this measure. While the optimal sample complexity for polynomial regression was well understood for and , our result is the first that achieves sample complexity linear in and error for other values of without any assumptions. Our result requires two main technical contributions. The first concerns , for which we provide explicit bounds on the Lewis weight function of the infinite linear operator underlying polynomial regression. Using tools from the orthogonal polynomial literature, we show that this function is bounded by the Chebyshev density. Our second key contribution is to take advantage of the structure of polynomials to reduce the case to the case. By doing so, we obtain a better sample complexity than what is possible for general -norm linear regression problems, for which samples are required.
Cite
@article{arxiv.2211.06790,
title = {Near-Linear Sample Complexity for $L_p$ Polynomial Regression},
author = {Raphael A. Meyer and Cameron Musco and Christopher Musco and David P. Woodruff and Samson Zhou},
journal= {arXiv preprint arXiv:2211.06790},
year = {2022}
}
Comments
68 pages, to be presented at SODA 2023