Characterization of locally most split reliable graphs
Abstract
A two-terminal graph is a graph equipped with two distinguished vertices, called terminals. Let Tn,m be the set of all nonisomorphic connected simple two-terminal graphs on n vertices and m edges. Let G be any two-terminal graph in Tn,m. For every number p in [0,1] we let each of the edges in G be independently deleted with probability 1-p. The split reliability SRG(p) is the probability that the resulting spanning subgraph has precisely 2 connected components, each one including one terminal. The two-terminal graph G is uniformly most split reliable if SRG(p)≥ SRH(p) for each H in Tn,m and every p in [0,1]. We say G is locally most split reliable if there exists δ>0 such that SRG(p)≥ SRH(p) for each H in Tn,m and every p in (1-δ,1). Brown and McMullin showed that there exists uniformly most split reliable graphs in each class Tn,m such that m=n-1, m=n2, or m=n2-1. The authors also proved that there is no uniformly most split reliable two-terminal graph in Tn,n when n≥ 6 and specified in which classes Tn,m such that n≤ 7 there exist uniformly most split reliable graphs. The existence or nonexistence of uniformly most split reliable graphs in the remaining cases is posed by Brown and McMullin as an open problem. In this work, the set Gn,m consisting of all locally most split reliable graphs is characterized in each nonempty class Tn,m. It is proved that a graph in Tn,m is locally most split reliable if and only if its split reliability equals that of the balloon graph equipped with two terminals whose distance equals its diameter. Finally, it is proved that there is no uniformly most split reliable graph in Tn,m when n≥ 7 and n≤ m ≤ n-32+3.
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