English

The Threshold Dimension and Irreducible Graphs

Combinatorics 2020-02-26 v1 Discrete Mathematics

Abstract

Let GG be a graph, and let uu, vv, and ww be vertices of GG. If the distance between uu and ww does not equal the distance between vv and ww, then ww is said to resolve uu and vv. The metric dimension of GG, denoted β(G)\beta(G), is the cardinality of a smallest set WW of vertices such that every pair of vertices of GG is resolved by some vertex of WW. The threshold dimension of GG, denoted τ(G)\tau(G), is the minimum metric dimension among all graphs HH having GG as a spanning subgraph. In other words, the threshold dimension of GG is the minimum metric dimension among all graphs obtained from GG by adding edges. If β(G)=τ(G)\beta(G) = \tau(G), then GG is said to be irreducible. We give two upper bounds for the threshold dimension of a graph, the first in terms of the diameter, and the second in terms of the chromatic number. As a consequence, we show that every planar graph of order nn has threshold dimension O(log2n)O (\log_2 n). We show that several infinite families of graphs, known to have metric dimension 33, are in fact irreducible. Finally, we show that for any integers nn and bb with 1b<n1 \leq b < n, there is an irreducible graph of order nn and metric dimension bb.

Keywords

Cite

@article{arxiv.2002.11048,
  title  = {The Threshold Dimension and Irreducible Graphs},
  author = {Lucas Mol and Matthew J. H. Murphy and Ortrud R. Oellermann},
  journal= {arXiv preprint arXiv:2002.11048},
  year   = {2020}
}

Comments

15 pages, 2 figures

R2 v1 2026-06-23T13:53:31.602Z