Revised: August 5, 2021
Published: December 31, 2023
Abstract: [Plain Text Version]
The Polynomial Identity Lemma (also called the “Schwartz--Zippel lemma”) states that any nonzero polynomial $f(x_1,\ldots, x_n)$ of degree at most $s$ will evaluate to a nonzero value at some point on any grid $S^n \subseteq \F^n$ with $\abs{S} > s$. 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 $\epsilon > 0$ be a constant.
For a sufficiently large constant $n$, and all $s > n$, if we have an explicit hitting set of size $(s+1)^{n-\epsilon}$ 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 $s^{\exp(\exp (O(\log^\ast s)))}$ for $s$-variate circuits of degree $s$ and size $s$.
That is, if we can obtain a barely non-trivial exponent (a factor-$s^{\Omega(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.”
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A preliminary version of this paper appeared in the Proceedings of the 30th Annual ACM-SIAM Symposium on Discrete Algorithms (SODA 2019).
Licensed under a Creative Commons Attribution License (CC-BY)