Weak disorder in the stochastic mean-field model of distance II

TL;DR

This paper investigates the behavior of shortest paths in a complete graph with i.i.d. edge weights drawn from a distribution related to exponential variables, revealing different asymptotic properties depending on the distribution's parameter.

Contribution

It extends previous work by analyzing the case where edge weights follow an inverse exponential distribution, showing that the hopcount converges to a fixed value or a mixture for special parameters.

Findings

Hopcount converges in probability to a fixed integer for almost all s.

For special s values, hopcount takes two values with positive probability.

The distribution of minimal path weight is characterized for different s regimes.

Abstract

In this paper, we study the complete graph $K_n$ with n vertices, where we attach an independent and identically distributed (i.i.d.) weight to each of the n(n-1)/2 edges. We focus on the weight $W_n$ and the number of edges $H_n$ of the minimal weight path between vertex 1 and vertex n. It is shown in (Ann. Appl. Probab. 22 (2012) 29-69) that when the weights on the edges are i.i.d. with distribution equal to that of $E^s$, where $s>0$ is some parameter, and E has an exponential distribution with mean 1, then $H_n$ is asymptotically normal with asymptotic mean $s\log n$ and asymptotic variance $s^2\log n$. In this paper, we analyze the situation when the weights have distribution $E^{-s},s>0$, in which case the behavior of $H_n$ is markedly different as $H_n$ is a tight sequence of random variables. More precisely, we use the method of Stein-Chen for Poisson approximations to show that, for almost all $s>0$, the hopcount $H_n$ converges in probability to the nearest integer of s+1 greater than or equal to 2, and identify the limiting distribution of the recentered and rescaled minimal weight. For a countable set of special s values denoted by $\mathcal{S}=\{s_j\}_{j\geq2}$, the hopcount $H_n$ takes on the values j and j+1 each with positive probability.