Hilbert Functions and Low-Degree Randomness Extractors
Abstract
For , consider the linear space of restrictions of degree- polynomials to . The Hilbert function of , denoted , is the dimension of this space. We obtain a tight lower bound on the smallest value of the Hilbert function of subsets of arbitrary finite grids in with a fixed size . We achieve this by proving that this value coincides with a combinatorial quantity, namely the smallest number of low Hamming weight points in a down-closed set of size . Understanding the smallest values of Hilbert functions is closely related to the study of degree- closure of sets, a notion introduced by Nie and Wang (Journal of Combinatorial Theory, Series A, 2015). We use bounds on the Hilbert function to obtain a tight bound on the size of degree- closures of subsets of , which answers a question posed by Doron, Ta-Shma, and Tell (Computational Complexity, 2022). We use the bounds on the Hilbert function and degree- closure of sets to prove that a random low-degree polynomial is an extractor for samplable randomness sources. Most notably, we prove the existence of low-degree extractors and dispersers for sources generated by constant-degree polynomials and polynomial-size circuits. Until recently, even the existence of arbitrary deterministic extractors for such sources was not known.
Cite
@article{arxiv.2405.10277,
title = {Hilbert Functions and Low-Degree Randomness Extractors},
author = {Alexander Golovnev and Zeyu Guo and Pooya Hatami and Satyajeet Nagargoje and Chao Yan},
journal= {arXiv preprint arXiv:2405.10277},
year = {2024}
}