English

Flow polynomials of a signed graph

Combinatorics 2018-06-26 v2

Abstract

In contrast to ordinary graphs, the number of the nowhere-zero group-flows in a signed graph may vary with different groups, even if the groups have the same order. In fact, for a signed graph GG and non-negative integer dd, it was shown that there exists a polynomial Fd(G,x)F_d(G,x) such that the number of the nowhere-zero Γ\Gamma-flows in GG equals Fd(G,x)F_d(G,x) evaluated at kk for every Abelian group Γ\Gamma of order kk with ϵ(Γ)=d\epsilon(\Gamma)=d, where ϵ(Γ)\epsilon(\Gamma) is the largest integer dd for which Γ\Gamma has a subgroup isomorphic to Z2d\mathbb{Z}^d_2. We focus on the combinatorial structure of Γ\Gamma-flows in a signed graph and the coefficients in Fd(G,x)F_d(G,x). We first define the fundamental directed circuits for a signed graph GG and show that all Γ\Gamma-flows (not necessarily nowhere-zero) in GG can be generated by these circuits. It turns out that all Γ\Gamma-flows in GG can be evenly classified into 2ϵ(Γ)2^{\epsilon(\Gamma)}-classes specified by the elements of order 2 in Γ\Gamma, each class of which consists of the same number of flows depending only on the order of the group. This gives an explanation for why the number of Γ\Gamma-flows in a signed graph varies with different ϵ(Γ)\epsilon(\Gamma), and also gives an answer to a problem posed by Beck and Zaslavsky. Secondly, using an extension of Whitney's broken circuit theory we give a combinatorial interpretation of the coefficients in Fd(G,x)F_d(G,x) for d=0d=0, in terms of the broken bonds. As an example, we give an analytic expression of F0(G,x)F_0(G,x) for a class of the signed graphs that contain no balanced circuit. Finally, we show that the sets of edges in a signed graph that contain no broken bond form a homogeneous simplicial complex.

Keywords

Cite

@article{arxiv.1805.07878,
  title  = {Flow polynomials of a signed graph},
  author = {Jianguo Qian},
  journal= {arXiv preprint arXiv:1805.07878},
  year   = {2018}
}

Comments

The original version consists of 17 pages and 1 figure. The current version: 18 pages and 1 figure; a reference and a proof for Corollary 6.1 added; minor text modification made

R2 v1 2026-06-23T02:02:12.595Z