Functional lower bounds for arithmetic circuits and connections to boolean circuit complexity
Abstract
We say that a circuit over a field functionally computes an -variate polynomial if for every we have that . This is in contrast to syntactically computing , when as formal polynomials. In this paper, we study the question of proving lower bounds for homogeneous depth- and depth- arithmetic circuits for functional computation. We prove the following results : 1. Exponential lower bounds homogeneous depth- arithmetic circuits for a polynomial in . 2. Exponential lower bounds for homogeneous depth- arithmetic circuits with bounded individual degree for a polynomial in . Our main motivation for this line of research comes from our observation that strong enough functional lower bounds for even very special depth- arithmetic circuits for the Permanent imply a separation between and . Thus, improving the second result to get rid of the bounded individual degree condition could lead to substantial progress in boolean circuit complexity. Besides, it is known from a recent result of Kumar and Saptharishi [KS15] that over constant sized finite fields, strong enough average case functional lower bounds for homogeneous depth- circuits imply superpolynomial lower bounds for homogeneous depth- circuits. Our proofs are based on a family of new complexity measures called shifted evaluation dimension, and might be of independent interest.
Cite
@article{arxiv.1605.04207,
title = {Functional lower bounds for arithmetic circuits and connections to boolean circuit complexity},
author = {Michael A. Forbes and Mrinal Kumar and Ramprasad Saptharishi},
journal= {arXiv preprint arXiv:1605.04207},
year = {2016}
}