Constructing Internally Disjoint Pendant Steiner Trees in Cartesian Product Networks

Abstract

The concept of pedant tree-connectivity was introduced by Hager in 1985. For a graph G=(V,E) and a set S⊂eq V(G) of at least two vertices, an S-Steiner tree or a Steiner tree connecting S (or simply, an S-tree) is a such subgraph T=(V',E') of G that is a tree with S⊂eq V'. For an S-Steiner tree, if the degree of each vertex in S is equal to one, then this tree is called a pedant S-Steiner tree. Two pedant S-Steiner trees T and T' are said to be internally disjoint if E(T) E(T')= and V(T) V(T')=S. For S⊂eq V(G) and |S|≥ 2, the local pedant tree-connectivity τG(S) is the maximum number of internally disjoint pedant S-Steiner trees in G. For an integer k with 2≤ k≤ n, pedant tree k-connectivity is defined as τk(G)=\τG(S)\,|\,S⊂eq V(G),|S|=k\. In this paper, we prove that for any two connected graphs G and H, τ3(G H)≥ \3τ3(G)2,3τ3(H)2\. Moreover, the bound is sharp.