Deterministic Approximate Counting for Degree-$2$ Polynomial Threshold Functions
Abstract
We give a {\em deterministic} algorithm for approximately computing the fraction of Boolean assignments that satisfy a degree- polynomial threshold function. Given a degree-2 input polynomial and a parameter , the algorithm approximates to within an additive in time . Note that it is NP-hard to determine whether the above probability is nonzero, so any sort of multiplicative approximation is almost certainly impossible even for efficient randomized algorithms. This is the first deterministic algorithm for this counting problem in which the running time is polynomial in for . For "regular" polynomials (those in which no individual variable's influence is large compared to the sum of all variable influences) our algorithm runs in time. The algorithm also runs in time to approximate to within an additive , for any degree-2 polynomial . As an application of our counting result, we give a deterministic FPT multiplicative -approximation algorithm to approximate the -th absolute moment of a degree-2 polynomial. The algorithm's running time is of the form .
Cite
@article{arxiv.1311.7105,
title = {Deterministic Approximate Counting for Degree-$2$ Polynomial Threshold Functions},
author = {Anindya De and Ilias Diakonikolas and Rocco A. Servedio},
journal= {arXiv preprint arXiv:1311.7105},
year = {2013}
}