On the metric dimension of corona product graphs

Abstract

Given a set of vertices S=\v1,v2,...,vk\ of a connected graph G, the metric representation of a vertex v of G with respect to S is the vector r(v|S)=(d(v,v1),d(v,v2),...,d(v,vk)), where d(v,vi), i∈ \1,...,k\ denotes the distance between v and vi. S is a resolving set for G if for every pair of vertices u,v of G, r(u|S) r(v|S). The metric dimension of G, dim(G), is the minimum cardinality of any resolving set for G. Let G and H be two graphs of order n1 and n2, respectively. The corona product G H is defined as the graph obtained from G and H by taking one copy of G and n1 copies of H and joining by an edge each vertex from the ith-copy of H with the ith-vertex of G. For any integer k 2, we define the graph Gk H recursively from G H as Gk H=(Gk-1 H) H. We give several results on the metric dimension of Gk H. For instance, we show that given two connected graphs G and H of order n1 2 and n2 2, respectively, if the diameter of H is at most two, then dim(Gk H)=n1(n2+1)k-1dim(H). Moreover, if n2 7 and the diameter of H is greater than five or H is a cycle graph, then dim(Gk H)=n1(n2+1)k-1dim(K1 H).