English

On the Split Reliability of Graphs

Combinatorics 2023-06-07 v1 Probability

Abstract

A common model of robustness of a graph against random failures has all vertices operational, but the edges independently operational with probability pp. One can ask for the probability that all vertices can communicate ({\em all-terminal reliability}) or that two specific vertices (or {\em terminals}) can communicate with each other ({\em two-terminal reliability}). A relatively new measure is {\em split reliability}, where for two fixed vertices ss and tt, we consider the probability that every vertex communicates with one of ss or tt, but not both. In this paper, we explore the existence for fixed numbers n2n \geq 2 and mn1m \geq n-1 of an {\em optimal} connected (n,m)(n,m)-graph Gn,mG_{n,m} for split reliability, that is, a connected graph with nn vertices and mm edges for which for any other such graph HH, the split reliability of Gn,mG_{n,m} is at least as large as that of HH, for {\em all} values of p[0,1]p \in [0,1]. Unlike the similar problems for all-terminal and two-terminal reliability, where only partial results are known, we completely solve the issue for split reliability, where we show that there is an optimal (n,m)(n,m)-graph for split reliability if and only if n3n\leq 3, m=n1m=n-1, or n=m=4n=m=4.

Keywords

Cite

@article{arxiv.2306.03884,
  title  = {On the Split Reliability of Graphs},
  author = {Jason I. Brown and Isaac McMullin},
  journal= {arXiv preprint arXiv:2306.03884},
  year   = {2023}
}

Comments

12 pages, 9 figures

R2 v1 2026-06-28T10:58:05.072Z