Your search keyword '"05C21, 05C31"' showing total 2 results

1. On graphs whose flow polynomials have real roots only

Author

Dong, Fengming

Subjects

Mathematics - Combinatorics, 05C21, 05C31

Abstract

Let $G$ be a bridgeless graph. In 2011 Kung and Royle showed that all roots of the flow polynomial $F(G,\lambda)$ of $G$ are integers if and only if $G$ is the dual of a chordal and plane graph. In this article, we study whether a bridgeless graph $G$ for which $F(G,\lambda)$ has real roots only must be the dual of some chordal and plane graph. We conclude that the answer of this problem for $G$ is positive if and only if $F(G,\lambda)$ does not have any real root in the interval $(1,2)$. We also prove that for any non-separable and $3$-edge connected $G$, if $G-e$ is also non-separable for each edge $e$ in $G$ and every $3$-edge-cut of $G$ consists of edges incident with some vertex of $G$, then all roots of $P(G,\lambda)$ are real if and only if either $G\in \{L,Z_3,K_4\}$ or $F(G,\lambda)$ contains at least $9$ real roots in the interval $(1,2)$, where $L$ is the graph with one vertex and one loop and $Z_3$ is the graph with two vertices and three parallel edges joining these two vertices., Comment: 15 pages, 2 figures. To appear in EJC

Published

2018

2. On Graphs whose Flow Polynomials have Real Roots Only

Author

Fengming Dong

Subjects

05C21, 05C31, Polynomial, 0102 computer and information sciences, Lambda, 01 natural sciences, Theoretical Computer Science, Combinatorics, symbols.namesake, Chordal graph, FOS: Mathematics, Mathematics - Combinatorics, Discrete Mathematics and Combinatorics, 0101 mathematics, Mathematics, Real roots, Applied Mathematics, 010102 general mathematics, Graph, Vertex (geometry), Planar graph, Computational Theory and Mathematics, 010201 computation theory & mathematics, symbols, Combinatorics (math.CO), Geometry and Topology, Multiple edges

Abstract

Let $G$ be a bridgeless graph. In 2011 Kung and Royle showed that all roots of the flow polynomial $F(G,\lambda)$ of $G$ are integers if and only if $G$ is the dual of a chordal and plane graph. In this article, we study whether a bridgeless graph $G$ for which $F(G,\lambda)$ has real roots only must be the dual of some chordal and plane graph. We conclude that the answer of this problem for $G$ is positive if and only if $F(G,\lambda)$ does not have any real root in the interval $(1,2)$. We also prove that for any non-separable and $3$-edge connected $G$, if $G-e$ is also non-separable for each edge $e$ in $G$ and every $3$-edge-cut of $G$ consists of edges incident with some vertex of $G$, then all roots of $P(G,\lambda)$ are real if and only if either $G\in \{L,Z_3,K_4\}$ or $F(G,\lambda)$ contains at least $9$ real roots in the interval $(1,2)$, where $L$ is the graph with one vertex and one loop and $Z_3$ is the graph with two vertices and three parallel edges joining these two vertices., Comment: 15 pages, 2 figures. To appear in EJC

Published

2018