English

On bipartite graphs having minimal fourth adjacency coefficient

Combinatorics 2020-02-11 v1

Abstract

Let GG be a simple graph with order nn and adjacency matrix A(G)\mathbf{A}(G). Let ϕ(G;λ)=det(λIA(G))=i=0nai(G)λni\phi(G; \lambda)=\det(\lambda I-\mathbf{A}(G))=\sum_{i=0}^n\mathbf{a}_i(G)\lambda^{n-i} be the characteristic polynomial of GG, where ai(G)\mathbf{a}_i(G) is called the ii-th adjacency coefficient of GG. Denote by Bn,m\mathfrak{B}_{n,m} the set of all connected graphs having nn vertices and mm edges. A bipartite graph GG is referred as bipartite optimal if a4(G)=min{a4(H)HBn,m}.\mathbf{a}_4(G)=min\{\mathbf{a}_4(H)|H\in \mathfrak{B}_{n,m}\}. The value min{a4(H)HBn,m}min\{\mathbf{a}_4(H)|H\in \mathfrak{B}_{n,m}\} is called the minimal 44-Sachs number in Bn,m\mathfrak{B}_{n,m}, denoted by aˉ4(Bn,m)\bar{\mathbf{a}}_4(\mathfrak{B}_{n,m}). \vspace{2mm} For any given integer pair (n,m)(n,m), we in this paper investigate the bipartite optimal graphs. Firstly, we show that each bipartite optimal graph is a difference graph (see Theorem 10). Then we deduce some structural properties on bipartite optimal graphs. As applications of those properties, we determine all bipartite optimal (n,m)(n,m)-graphs together with the corresponding minimal 44-Sachs number for n5n\ge 5 and n1m3(n3)n-1\le m\le 3(n-3). Finally, we express the problem of computing the minimal 44-Sachs number as a class of combinatorial optimization problem, which relates to the partitions of positive integers.

Keywords

Cite

@article{arxiv.2002.03829,
  title  = {On bipartite graphs having minimal fourth adjacency coefficient},
  author = {Shi Cai Gong and Shao Wei Sun},
  journal= {arXiv preprint arXiv:2002.03829},
  year   = {2020}
}

Comments

21 pages

R2 v1 2026-06-23T13:36:54.475Z