English

Approximating real-rooted and stable polynomials, with combinatorial applications

Combinatorics 2018-06-21 v1 Data Structures and Algorithms Classical Analysis and ODEs

Abstract

Let p(x)=a0+a1x++anxnp(x)=a_0 + a_1 x + \ldots + a_n x^n be a polynomial with all roots real and satisfying xδx \leq -\delta for some 0<δ<10<\delta <1. We show that for any 0<ϵ<10 < \epsilon <1, the value of p(1)p(1) is determined within relative error ϵ\epsilon by the coefficients aka_k with kcδlnnϵδk \leq {c \over \sqrt{\delta}} \ln {n \over \epsilon \sqrt{ \delta}} for some absolute constant c>0c > 0. Consequently, if mk(G)m_k(G) is the number of matchings with kk edges in a graph GG, then for any 0<ϵ<10 < \epsilon < 1, the total number M(G)=m0(G)+m1(G)+M(G)=m_0(G)+m_1(G) + \ldots of matchings is determined within relative error ϵ\epsilon by the numbers mk(G)m_k(G) with kcΔln(v/ϵ)k \leq c \sqrt{\Delta} \ln (v /\epsilon), where Δ\Delta is the largest degree of a vertex, vv is the number of vertices of GG and c>0c >0 is an absolute constant. We prove a similar result for polynomials with complex roots satisfying zδ\Re\thinspace z \leq -\delta and apply it to estimate the number of unbranched subgraphs of GG.

Keywords

Cite

@article{arxiv.1806.07404,
  title  = {Approximating real-rooted and stable polynomials, with combinatorial applications},
  author = {Alexander Barvinok},
  journal= {arXiv preprint arXiv:1806.07404},
  year   = {2018}
}

Comments

12 pages

R2 v1 2026-06-23T02:35:09.002Z