The k-metric dimension of graphs: a general approach

Abstract

Let (X,d) be a metric space. A set S⊂eq X is said to be a k-metric generator for X if and only if for any pair of different points u,v∈ X, there exist at least k points w1,w2, … wk∈ S such that d(u,wi) d(v,wi),\; for all\; i∈ \1, … k\. Let Rk(X) be the set of metric generators for X. The k-metric dimension k(X) of (X,d) is defined as k(X)=∈f\|S|:\, S∈ Rk(X)\. Here, we discuss the k-metric dimension of (V,dt), where V is the set of vertices of a simple graph G and the metric dt:V× V→ N \0\ is defined by dt(x,y)=\d(x,y),t\ from the geodesic distance d in G and a positive integer t. The case t D(G), where D(G) denotes the diameter of G, corresponds to the original theory of k-metric dimension and the case t=2 corresponds to the theory of k-adjacency dimension. Furthermore, this approach allows us to extend the theory of k-metric dimension to the general case of non-necessarily connected graphs.