The Steiner k-radius and Steiner k-diameter of connected graphs for k≥ 4

Abstract

Given a connected graph G=(V,E) and a vertex set S⊂ V, the Steiner distance d(S) of S is the size of a minimum spanning tree of S in G. For a connected graph G of order n and an integer k with 2≤ k ≤ n, the k-eccentricity of a vertex v in G is the maximum value of d(S) over all S⊂ V with |S|=k and v∈ S. The minimum k-eccentricity, sradk(G), is called the k-radius of G while the maximum k-eccentricity, sdiamk(G), is called the k-diameter of G. In 1990, Henning, Oellermann, and Swart [Ars Combinatoria 12 13-19, (1990)] showed that there exists a graph Hk such that sdiamk(Hk) = 2(k+1)2k-1sradk(Hk). The authors also conjectured that for any k≥ 2 and connected graph G sdiamk(G) ≤ 2(k+1)2k-1sradk(G). The authors provided proofs of the conjecture for k=3 and 4. Their proof for k=4, however, was incomplete. In this note, we disprove the conjecture for k≥ 5 by proving that the bound sdiamk(G)≤ k+3k+1sradk(G) is tight for k≥ 5. We then provide a complete proof for k=4 and identify the error in the previous proof of this case.