Min-Rank Conjecture for Log-Depth Circuits
Abstract
A completion of an m-by-n matrix A with entries in {0,1,*} is obtained by setting all *-entries to constants 0 or 1. A system of semi-linear equations over GF(2) has the form Mx=f(x), where M is a completion of A and f:{0,1}^n --> {0,1}^m is an operator, the i-th coordinate of which can only depend on variables corresponding to *-entries in the i-th row of A. We conjecture that no such system can have more than 2^{n-c\cdot mr(A)} solutions, where c>0 is an absolute constant and mr(A) is the smallest rank over GF(2) of a completion of A. The conjecture is related to an old problem of proving super-linear lower bounds on the size of log-depth boolean circuits computing linear operators x --> Mx. The conjecture is also a generalization of a classical question about how much larger can non-linear codes be than linear ones. We prove some special cases of the conjecture and establish some structural properties of solution sets.
Cite
@article{arxiv.1005.1009,
title = {Min-Rank Conjecture for Log-Depth Circuits},
author = {S. Jukna and G. Schnitger},
journal= {arXiv preprint arXiv:1005.1009},
year = {2012}
}
Comments
22 pages, to appear in: J. Comput.Syst.Sci.