English

Deterministic polynomial-time approximation algorithms for partition functions and graph polynomials

Combinatorics 2018-01-11 v3 Computational Complexity Discrete Mathematics Data Structures and Algorithms

Abstract

In this paper we show a new way of constructing deterministic polynomial-time approximation algorithms for computing complex-valued evaluations of a large class of graph polynomials on bounded degree graphs. In particular, our approach works for the Tutte polynomial and independence polynomial, as well as partition functions of complex-valued spin and edge-coloring models. More specifically, we define a large class of graph polynomials C\mathcal C and show that if pCp\in \cal C and there is a disk DD centered at zero in the complex plane such that p(G)p(G) does not vanish on DD for all bounded degree graphs GG, then for each zz in the interior of DD there exists a deterministic polynomial-time approximation algorithm for evaluating p(G)p(G) at zz. This gives an explicit connection between absence of zeros of graph polynomials and the existence of efficient approximation algorithms, allowing us to show new relationships between well-known conjectures. Our work builds on a recent line of work initiated by. Barvinok, which provides a new algorithmic approach besides the existing Markov chain Monte Carlo method and the correlation decay method for these types of problems.

Keywords

Cite

@article{arxiv.1607.01167,
  title  = {Deterministic polynomial-time approximation algorithms for partition functions and graph polynomials},
  author = {Viresh Patel and Guus Regts},
  journal= {arXiv preprint arXiv:1607.01167},
  year   = {2018}
}

Comments

27 pages; some changes have been made based on referee comments. In particular a tiny error in Proposition 4.4 has been fixed. The introduction and concluding remarks have also been rewritten to incorporate the most recent developments. Accepted for publication in SIAM Journal on Computation

R2 v1 2026-06-22T14:43:14.216Z