Hitting-sets for ROABP and Sum of Set-Multilinear circuits

TL;DR

This paper presents improved blackbox polynomial identity testing algorithms for ROABP and depth-3 set-multilinear circuits, achieving subexponential time complexities and introducing new techniques like basis isolation.

Contribution

It introduces a faster $n^{O( ext{log } n)}$-time PIT for unknown-order ROABP, matching known order complexities, and provides the first subexponential whitebox PIT for sum of set-multilinear depth-3 circuits.

Findings

Achieved $n^{O( ext{log } n)}$-time blackbox PIT for unknown-order ROABP.

Developed subexponential whitebox PIT for sum of constant-depth set-multilinear circuits.

Designed a polynomial-time hitting-set for invertible-factor ROABP of width $w$.

Abstract

We give a $n^{O(\log n)}$-time ($n$ is the input size) blackbox polynomial identity testing algorithm for unknown-order read-once oblivious algebraic branching programs (ROABP). The best result known for this class was $n^{O(\log^2 n)}$ due to Forbes-Saptharishi-Shpilka (STOC 2014), and that too only for multilinear ROABP. We get rid of their exponential dependence on the individual degree. With this, we match the time-complexity for the unknown order ROABP with the known order ROABP (due to Forbes-Shpilka (FOCS 2013)) and also with the depth-$3$ set-multilinear circuits (due to Agrawal-Saha-Saxena (STOC 2013)). Our proof is simpler and involves a new technique called basis isolation. The depth-$3$ model has recently gained much importance, as it has become a stepping-stone to understanding general arithmetic circuits. Its restriction to multilinearity has known exponential lower bounds but no nontrivial blackbox identity tests. In this paper, we take a step towards designing such hitting-sets. We give the first subexponential whitebox PIT for the sum of constantly many set-multilinear depth-$3$ circuits. To achieve this, we define notions of distance and base sets. Distance, for a multilinear depth-$3$ circuit, measures how far are the partitions from a mere refinement. We design a hitting-set in time $n^{O(d \log n)}$ for $d$-distance. Further, we give an extension of our result to models where the distance is large but it is small when restricted to certain base sets (of variables). We also explore a new model of ROABP where the factor-matrices are invertible (called invertible-factor ROABP). We design a hitting-set in time poly($n^{w^2}$) for width-$w$ invertible-factor ROABP. Further, we could do without the invertibility restriction when $w=2$. Previously, the best result for width-$2$ ROABP was quasi-polynomial time (Forbes-Saptharishi-Shpilka, STOC 2014).