A fixed-point approximation for a routing model in equilibrium

Abstract

We use a method of Luczak (arXiv:1212.3231) to investigate the equilibrium distribution of a dynamic routing model on a network. In this model, there are n nodes, each pair joined by a link of capacity C. For each pair of nodes, calls arrive for this pair of endpoints as a Poisson process with rate λ. A call for endpoints \u,v\ is routed directly onto the link between the two nodes if there is spare capacity; otherwise d two-link paths between u and v are considered, and the call is routed along a path with lowest maximum load, if possible. The duration of each call is an exponential random variable with unit mean. In the case d=1, it was suggested by Gibbens, Hunt and Kelly in 1990 that the equilibrium of this process is related to the fixed points of a certain equation. We show that this is indeed the case, for every d 1, provided the arrival rate λ is either sufficiently small or sufficiently large. In either regime, we show that the equation has a unique fixed point, and that, in equilibrium, for each j, the proportion of links at each node with load j is strongly concentrated around the jth coordinate of the fixed point.