English

Some binary products and integer linear programming for computing $k$-metric dimension of graphs

Combinatorics 2021-02-15 v2

Abstract

Let GG be a connected graph. For an ordered set S={v1,,v}V(G)S=\{v_1,\ldots, v_\ell\}\subseteq V(G), the vector rG(vS)=(dG(v1,v),,dG(v,v))r_G(v|S) = (d_G(v_1,v), \ldots, d_G(v_\ell,v)) is called the metric SS-representation of vv. If for any pair of different vertices u,vV(G)u,v\in V(G), the vectors r(vS)r(v|S) and r(uS)r(u|S) differ in at least kk positions, then SS is a kk-metric generator for GG. A smallest kk-metric generator for GG is a kk-{\em metric basis} for GG, its cardinality being the kk-metric dimension of GG. A sharp upper bound and a closed formulae for the kk-metric dimension of the hierarchical product of graphs is proved. Also, sharp lower bounds for the kk-metric dimension of the splice and link products of graphs are presented. An integer linear programming model for computing the kk-metric dimension and a kk-metric basis of a given graph is proposed. These results are applied to bound or to compute the kk-metric dimension of some classes of graphs that are of interest in mathematical chemistry.

Keywords

Cite

@article{arxiv.2101.10012,
  title  = {Some binary products and integer linear programming for computing $k$-metric dimension of graphs},
  author = {Sandi Klavžar and Freydoon Rahbarnia and Mostafa Tavakoli},
  journal= {arXiv preprint arXiv:2101.10012},
  year   = {2021}
}
R2 v1 2026-06-23T22:29:16.795Z