English

Noncommutative Valiant's Classes: Structure and Complete Problems

Computational Complexity 2015-08-04 v1

Abstract

In this paper we explore the noncommutative analogues, VPnc\mathrm{VP}_{nc} and VNPnc\mathrm{VNP}_{nc}, of Valiant's algebraic complexity classes and show some striking connections to classical formal language theory. Our main results are the following: (1) We show that Dyck polynomials (defined from the Dyck languages of formal language theory) are complete for the class VPnc\mathrm{VP}_{nc} under abp\le_{abp} reductions. Likewise, it turns out that PAL\mathrm{PAL} (Palindrome polynomials defined from palindromes) are complete for the class VSKEWnc\mathrm{VSKEW}_{nc} (defined by polynomial-size skew circuits) under abp\le_{abp} reductions. The proof of these results is by suitably adapting the classical Chomsky-Sch\"{u}tzenberger theorem showing that Dyck languages are the hardest CFLs. (2) Next, we consider the class VNPnc\mathrm{VNP}_{nc}. It is known~\cite{HWY10a} that, assuming the sum-of-squares conjecture, the noncommutative polynomial w{x0,x1}nww\sum_{w\in\{x_0,x_1\}^n}ww requires exponential size circuits. We unconditionally show that w{x0,x1}nww\sum_{w\in\{x_0,x_1\}^n}ww is not VNPnc\mathrm{VNP}_{nc}-complete under the projection reducibility. As a consequence, assuming the sum-of-squares conjecture, we exhibit a strictly infinite hierarchy of p-families under projections inside VNPnc\mathrm{VNP}_{nc} (analogous to Ladner's theorem~\cite{Ladner75}). In the final section we discuss some new VNPnc\mathrm{VNP}_{nc}-complete problems under abp\le_{abp}-reductions. (3) Inside VPnc\mathrm{VP}_{nc} too we show there is a strict hierarchy of p-families (based on the nesting depth of Dyck polynomials) under the abp\le_{abp} reducibility.

Keywords

Cite

@article{arxiv.1508.00395,
  title  = {Noncommutative Valiant's Classes: Structure and Complete Problems},
  author = {V. Arvind and Pushkar S Joglekar and S. Raja},
  journal= {arXiv preprint arXiv:1508.00395},
  year   = {2015}
}
R2 v1 2026-06-22T10:24:55.729Z