Monitoring the edges of a graph using distances
Abstract
We introduce a new graph-theoretic concept in the area of network monitoring. A set of vertices of a graph is a \emph{distance-edge-monitoring set} if for every edge of , there is a vertex of and a vertex of such that belongs to all shortest paths between and . We denote by the smallest size of such a set in . The vertices of represent distance probes in a network modeled by ; when the edge fails, the distance from to increases, and thus we are able to detect the failure. It turns out that not only we can detect it, but we can even correctly locate the failing edge. In this paper, we initiate the study of this new concept. We show that for a nontrivial connected graph of order , with if and only if is a tree, and if and only if it is a complete graph. We compute the exact value of for grids, hypercubes, and complete bipartite graphs. Then, we relate to other standard graph parameters. We show that is lower-bounded by the arboricity of the graph, and upper-bounded by its vertex cover number. It is also upper-bounded by twice its feedback edge set number. Moreover, we characterize connected graphs with . Then, we show that determining for an input graph is an NP-complete problem, even for apex graphs. There exists a polynomial-time logarithmic-factor approximation algorithm, however it is NP-hard to compute an asymptotically better approximation, even for bipartite graphs of small diameter and for bipartite subcubic graphs. For such instances, the problem is also unlikey to be fixed parameter tractable when parameterized by the solution size.
Keywords
Cite
@article{arxiv.2011.00029,
title = {Monitoring the edges of a graph using distances},
author = {Florent Foucaud and Shih-Shun Kao and Ralf Klasing and Mirka Miller and Joe Ryan},
journal= {arXiv preprint arXiv:2011.00029},
year = {2022}
}
Comments
19 pages; 5 figures. A preliminary version appeared in the proceedings of CALDAM 2020