Near-Optimal Bootstrapping of Hitting Sets for Algebraic Models

Abstract

∈paren[1]( #1 ) [2]∈paren12 [1] #1 F The Polynomial Identity Lemma (also called the "Schwartz--Zippel lemma") states that any nonzero polynomial f(x1,…, xn) of degree at most s will evaluate to a nonzero value at some point on any grid Sn ⊂eq n with |S| > s. Thus, there is an explicit hitting set for all n-variate degree-s, size-s algebraic circuits of size (s+1)n. In this paper, we prove the following results: Let ε > 0 be a constant. For a sufficiently large constant n, and all s > n, if we have an explicit hitting set of size (s+1)n-ε for the class of n-variate degree-s polynomials that are computable by algebraic circuits of size s, then for all large s, we have an explicit hitting set of size s( (O( s))) for s-variate circuits of degree s and size s. That is, if we can obtain a barely non-trivial exponent (a factor-s(1) improvement) compared to the trivial (s+1)n-size hitting set even for constant-variate circuits, we can get an almost complete derandomization of PIT. The above result holds when "circuits" are replaced by "formulas" or "algebraic branching programs." This extends a recent surprising result of Agrawal, Ghosh and Saxena (STOC 2018, PNAS 2019) who proved the same conclusion for the class of algebraic circuits, if the hypothesis provided a hitting set of size at most ∈parensn0.5 - δ (where δ> 0 is any constant). Hence, our work significantly weakens the hypothesis of Agrawal, Ghosh and Saxena to only require a slightly non-trivial saving over the trivial hitting set, and also presents the first such result for algebraic formulas.