An Improved Line-Point Low-Degree Test
Abstract
We prove that the most natural low-degree test for polynomials over finite fields is ``robust'' in the high-error regime for linear-sized fields. Specifically we consider the ``local'' agreement of a function f: Fqm Fq from the space of degree-d polynomials, i.e., the expected agreement of the function from univariate degree-d polynomials over a randomly chosen line in Fqm, and prove that if this local agreement is ε ≥ ((dq)τ)) for some fixed τ > 0, then there is a global degree-d polynomial Q: Fqm Fq with agreement nearly ε with f. This settles a long-standing open question in the area of low-degree testing, yielding an O(d)-query robust test in the ``high-error'' regime (i.e., when ε < 12). The previous results in this space either required ε > 12 (Polishchuk \& Spielman, STOC 1994), or q = (d4) (Arora \& Sudan, Combinatorica 2003), or needed to measure local distance on 2-dimensional ``planes'' rather than one-dimensional lines leading to (d2)-query complexity (Raz \& Safra, STOC 1997). Our analysis follows the spirit of most previous analyses in first analyzing the low-variable case (m = O(1)) and then ``bootstrapping'' to general multivariate settings. Our main technical novelty is a new analysis in the bivariate setting that exploits a previously known connection between multivariate factorization and finding (or testing) low-degree polynomials, in a non ``black-box'' manner. A second contribution is a bootstrapping analysis which manages to lift analyses for m=2 directly to analyses for general m, where previous works needed to work with m = 3 or m = 4 -- arguably this bootstrapping is significantly simpler than those in prior works.
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