Hitting-sets for low-distance multilinear depth-3
Abstract
The depth- 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 define a notion of distance for multilinear depth- circuits (say, in variables and product gates) that measures how far are the partitions from a mere refinement. The -distance strictly subsumes the set-multilinear model, while -distance captures general multilinear depth-. We design a hitting-set in time poly() for -distance. Further, we give an extension of our result to models where the distance is large (close to ) but it is small when restricted to certain variables. This implies the first subexponential whitebox PIT for the sum of constantly many set-multilinear depth- circuits. We also explore a new model of read-once algebraic branching programs (ROABP) where the factor-matrices are invertible (called invertible-factor ROABP). We design a hitting-set in time poly() for width- invertible-factor ROABP. Further, we could do without the invertibility restriction when . Previously, the best result for width- ROABP was quasi-polynomial time (Forbes-Saptharishi-Shpilka, arXiv 2013). The common thread in all these results is the phenomenon of low-support `rank concentration'. We exploit the structure of these models to prove rank-concentration after a `small shift' in the variables. Our proof techniques are stronger than the results of Agrawal-Saha-Saxena (STOC 2013) and Forbes-Saptharishi-Shpilka (arXiv 2013); giving us quasi-polynomial-time hitting-sets for models where no subexponential whitebox algorithms were known before.
Cite
@article{arxiv.1312.1826,
title = {Hitting-sets for low-distance multilinear depth-3},
author = {Manindra Agrawal and Rohit Gurjar and Arpita Korwar and Nitin Saxena},
journal= {arXiv preprint arXiv:1312.1826},
year = {2013}
}