Models for the k-metric dimension

Abstract

For an undirected graph G=(V,E), a vertex x ∈ V separates vertices u and v (where u,v ∈ V, u ≠ v) if their distances to x are not equal. Given an integer parameter k ≥ 1, a set of vertices L ⊂eq V is a feasible solution if for every pair of distinct vertices, u,v, there are at least k distinct vertices x1,x2,...,xk ∈ L each separating u and v. Such a feasible solution is called a "landmark set", and the k-metric dimension of a graph is the minimal cardinality of a landmark set for the parameter k. The case k=1 is a classic problem, where in its weighted version, each vertex v has a non-negative weight, and the goal is to find a landmark set with minimal total weight. We generalize the problem for k ≥ 2, introducing two models, and we seek for solutions to both the weighted version and the unweighted version of this more general problem. In the model of all-pairs (AP), k separations are needed for every pair of distinct vertices of V, while in the non-landmarks model (NL), such separations are required only for pairs of distinct vertices in V L. We study the weighted and unweighted versions for both models (AP and NL), for path graphs, complete graphs, complete bipartite graphs, and complete wheel graphs, for all values of k ≥ 2. We present algorithms for these cases, thus demonstrating the difference between the two new models, and the differences between the cases k=1 and k ≥ 2.