On the Steiner k-diameter and Steiner (k,k)-radius of trees
Abstract
Given a connected graph G=(V,E) and a k-set S⊂eq V(G), the Steiner distance dG(S) of S is defined as the size of a minimum tree including S in G. The Steiner k-eccentricity of a vertex v in G is the maximum value of dG(S) over all S⊂eq V(G) with |S|=k and v∈ S. The minimum Steiner k-eccentricity over all vertices, denoted by Srk(G), is called the Steiner k-radius of G and the maximum Steiner k-eccentricity over all vertices, denoted by Sdk(G), is its Steiner k-diameter. The Steiner (k,k)-eccentricity of a k-subset S of V(G), which is an extension of the Steiner k-eccentricity of a vertex v, is defined as the maximum Steiner distance over all k-subsets of V(G) containing S. The minimum Steiner (k,k)-eccentricity among all k-subsets of V(G), denoted by Srk,k(G), is called the Steiner (k,k)-radius of G. In 1989, Chartrand, Oellermann, Tian and Zou showed that for any k≥3, Sdk(T)≤ kk-1Srk(T) for any tree T. In this paper, we generalize this result and show that Sdk(T)≤ kk-kSrk,k(T) for any k≥3, k>k≥1. Furthermore, for k=2 and k=3, we obtain a tight upper bound of the Steiner k-diameter by the Steiner (k,k)-radius for all trees.
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