The second largest eigenvalue and vertex-connectivity of regular multigraphs Article Swipe

PDF

Related Concepts

Combinatorics Multigraph Vertex (graph theory) Mathematics Graph Simple graph Connectivity Regular graph Eigenvalues and eigenvectors Discrete mathematics Physics Line graph Graph power Quantum mechanics

O Suil ·

YOU? · · 2016 · Open Access · · DOI: https://doi.org/10.48550/arxiv.1603.03960 · OA: W2530385338

Let $μ_2(G)$ be the second smallest Laplacian eigenvalue of a graph $G$. The vertex connectivity of $G$, written $κ(G)$, is the minimum size of a vertex set $S$ such that $G-S$ is disconnected. Fiedler proved that $μ_2(G) \le κ(G)$ for a non-complete simple graph $G$; for this reason $μ_2(G)$ is called the "algebraic connectivity" of $G$. We extend his result to multigraphs. For a pair of vertices $u$ and $v$, let $m(u,v)$ be the number of edges with endpoints $u$ and $v$. For a vertex $v$, let $m(v)=\max_{u \in N(v)} m(v,u)$, where $N(v)$ is the set of neighbors of $v$, and let $m(G)=\max_{v \in V(G)} m(v)$. We prove that for any multigraph $G$ whose underlying graph is not a complete graph, $μ_2(G) \le κ(G) m(G)$. We also prove that for any $d$-regular multigraph $G$ whose underlying graph is not the complete graph with 2 vertices, if $μ_2(G) > \frac d4$, then $G$ is 2-connected. For $t\ge2$ and infinitely many $d$, we construct $d$-regular multigraphs $H$ with $μ_2(H)=d$, $κ(H)=t$, and $m(H)=\frac dt$. These graphs show that the inequality $μ_2(G) \le κ(G) m(G)$ is sharp. In addition, we prove that if $G$ is a $d$-regular multigraph whose underlying graph is not a complete graph, then $μ_2(G) \le d$; equality holds for the graphs in the construction.