Sharp bounds for the generalized connectivity $\kappa_3(G)$

TL;DR

This paper establishes sharp bounds for the 3-connectivity of graphs, explores its relation to standard connectivity, and provides polynomial-time solutions for certain planar graph cases.

Contribution

It derives bounds for $rac{3}{G}$, relates it to $rac{G}$ in planar graphs, and shows polynomial-time solvability for the equality problem.

Findings

Sharp upper and lower bounds for $rac{3}{G}$ in general graphs.

In planar graphs, $rac{G}-1 \u007leq rac{3}{G} \u007leq rac{G}$.

Polynomial-time algorithm to decide if $rac{G}=rac{3}{G}$ in planar graphs.

Abstract

Let $G$ be a nontrivial connected graph of order $n$ and let $k$ be an integer with $2\leq k\leq n$. For a set $S$ of $k$ vertices of $G$, let $\kappa (S)$ denote the maximum number $\ell$ of edge-disjoint trees $T_1,T_2,...,T_\ell$ in $G$ such that $V(T_i)\cap V(T_j)=S$ for every pair $i,j$ of distinct integers with $1\leq i,j\leq \ell$. A collection $\{T_1,T_2,...,T_\ell\}$ of trees in $G$ with this property is called an internally disjoint set of trees connecting $S$. Chartrand et al. generalized the concept of connectivity as follows: The $k$-$connectivity$, denoted by $\kappa_k(G)$, of $G$ is defined by $\kappa_k(G)=$min$\{\kappa(S)\}$, where the minimum is taken over all $k$-subsets $S$ of $V(G)$. Thus $\kappa_2(G)=\kappa(G)$, where $\kappa(G)$ is the connectivity of $G$. In general, the investigation of $\kappa_k(G)$ is very difficult. We therefore focus on the investigation on $\kappa_3(G)$ in this paper. We study the relation between the connectivity and the 3-connectivity of a graph. First we give sharp upper and lower bounds of $\kappa_3(G)$ for general graphs $G$, and construct two kinds of graphs which attain the upper and lower bound, respectively. We then show that if $G$ is a connected planar graph, then $\kappa(G)-1 \leq \kappa_3(G)\leq \kappa(G)$, and give some classes of graphs which attain the bounds. In the end we show that the problem whether $\kappa(G)=\kappa_3(G)$ for a planar graph $G$ can be solved in polynomial time.