Constructing edge-disjoint Steiner trees in Cartesian product networks (2301.12933v2)

Abstract: Cartesian product networks are always regarded as a tool for ``combining'' two given networks with established properties to obtain a new one that inherits properties from both. For a graph $F=(V,E)$ and a set $S\subseteq V(F)$ of at least two vertices, \emph{an $S$-Steiner tree} or \emph{a Steiner tree connecting $S$} (or simply, \emph{an $S$-tree}) is a subgraph $T=(V',E')$ of $F$ that is a tree with $S\subseteq V'$. For $S\subseteq V(F)$ and $|S|\geq 2$, the {\it generalized local edge-connectivity} $\lambda(S)$ is the maximum number of edge-disjoint Steiner trees connecting $S$ in $F$. For an integer $k$ with $2\leq k\leq n$, the {\it generalized $k$-edge-connectivity} $\lambda_k(F)$ of a graph $F$ is defined as $\lambda_k(F)=\min{\lambda(S)\,|\,S\subseteq V(F) \ and \ |S|=k}$.In this paper, we give sharp upper and lower bounds for $\lambda_k(G\Box H)$, where $\Box$ is the Cartesian product operation, and $G,H$ are two graphs.