Phase transition in a sequential assignment problem on graphs

Abstract

We study the following game on a finite graph G = (V, E). At the start, each edge is assigned an integer ne 0, n = Σe ∈ E ne. In round t, 1 t n, a uniformly random vertex v ∈ V is chosen and one of the edges f incident with v is selected by the player. The value assigned to f is then decreased by 1. The player wins, if the configuration (0, …, 0) is reached; in other words, the edge values never go negative. Our main result is that there is a phase transition: as n ∞, the probability that the player wins approaches a constant cG > 0 when (ne/n : e ∈ E) converges to a point in the interior of a certain convex set RG, and goes to 0 exponentially when (ne/n : e ∈ E) is bounded away from RG. We also obtain upper bounds in the near-critical region, that is when (ne/n : e ∈ E) lies close to ∂ RG. We supply quantitative error bounds in our arguments.