Bounds are obtained for the maximum average connectivity over orientations and the ratio to undirected average connectivity for graphs in specified classes, extending prior tree results with sharpness demonstrations where possible.
Average connectivity of minimally 2-connected graphs and average edge-connectivity of minimally 2-edge-connected graphs
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
Let $G$ be a (multi)graph of order $n$ and let $u,v$ be vertices of $G$. The maximum number of internally disjoint $u$-$v$ paths in $G$ is denoted by $\kappa_G(u,v)$, and the maximum number of edge-disjoint $u$-$v$ paths in $G$ is denoted by $\lambda_G (u,v)$. The average connectivity of $G$ is defined by $\overline{\kappa}(G)=\sum_{\{u,v\}\subseteq V(G)} \kappa_G(u,v)/\tbinom{n}{2},$ and the average edge-connectivity of $G$ is defined by $\overline{\lambda}(G)=\sum_{\{u,v\}\subseteq V(G)} \lambda_G(u,v)/\tbinom{n}{2}$. A graph $G$ is called ideally connected if $\kappa_G(u,v)=\min\{\mathrm{deg}(u),\mathrm{deg}(v)\}$ for all pairs of vertices $\{u,v\}$ of $G$. We prove that every minimally $2$-connected graph of order $n$ with largest average connectivity is bipartite, with the set of vertices of degree $2$ and the set of vertices of degree at least $3$ being the partite sets. We use this structure to prove that $\overline{\kappa}(G)<\tfrac{9}{4}$ for any minimally $2$-connected graph $G$. This bound is asymptotically tight, and we prove that every extremal graph of order $n$ is obtained from some ideally connected nearly regular graph on roughly $n/4$ vertices and $3n/4$ edges by subdividing every edge. We also prove that $\overline{\lambda}(G)<\tfrac{9}{4}$ for any minimally $2$-edge-connected graph $G$, and provide a similar characterization of the extremal graphs.
fields
math.CO 1years
2019 1verdicts
UNVERDICTED 1representative citing papers
citing papers explorer
-
The maximum average connectivity among all orientations of a graph
Bounds are obtained for the maximum average connectivity over orientations and the ratio to undirected average connectivity for graphs in specified classes, extending prior tree results with sharpness demonstrations where possible.