Ideals, Macaulay Bases, and PCPs

TL;DR

This paper introduces a novel PCP construction that reduces the number of composition steps to one by developing a new algebraic protocol using Macaulay bases, enabling efficient verification of polynomial evaluations over complex sets.

Contribution

The work presents the first PCP with a single composition step, utilizing a new class of sum-check alternatives based on Macaulay bases to verify polynomial evaluations efficiently.

Findings

Developed a PCP of size $2^{n^psilon}$ with $O_psilon(1)$ queries.

Extended sum-check protocols to broader set classes, reducing queries to a constant.

Highlighted the potential of algebraic notions like Macaulay bases in complexity theory.

Abstract

All known proofs of the PCP theorem rely on multiple "composition" steps, where PCPs over large alphabets are turned into PCPs over much smaller alphabets at a (relatively) small price in the soundness error of the PCP. Algebraic proofs, starting with the work of Arora, Lund, Motwani, Sudan, and Szegedy use at least 2 such composition steps, whereas the "Gap amplification" proof of Dinur uses $\Theta(\log n)$ such composition steps. In this work, we present the first PCP construction using just one composition step. The key ingredient, missing in previous work and finally supplied in this paper, is a basic PCP (of Proximity) of size $2^{n^\epsilon}$, for any $\epsilon > 0$, that makes $O_\epsilon(1)$ queries. At the core of our new construction is a new class of alternatives to "sum-check" protocols. As used in past PCPs, these provide a method by which to verify that an $m$-variate degree $d$ polynomial $P$ evaluates to zero at every point of some set $S \subseteq \mathbb{F}_q^m$. Previous works had shown how to check this condition for sets of the form $S = H^m$ using $O(m)$ queries with alphabet $\mathbb{F}_q^d$ assuming $d \geq |H|$. Our work improves this basic protocol in two ways: First we extend it to broader classes of sets $S$ (ones closer to Hamming balls rather than cubes). Second, it reduces the number of queries from $O(m)$ to an absolute constant for the settings of $S$ we consider. Specifically when $S = (\{0,1\}^{m/c}_{\leq 1})^c$, we give such an alternate to the sum-check protocol with $O(1)$ queries with alphabet $\mathbb{F}_q^{O(c+d)}$, using proofs of size $q^{O(m^2/c)}$. Our new protocols use the notion of Macaulay bases to extend previously known protocols to these new settings with surprising ease. In doing so, they highlight why these notions from algebra may be of further use in complexity theory.