Stochastic recursions on directed random graphs

Abstract

For a directed graph G(Vn, En) on the vertices Vn = \1,2, …, n\, we study the distribution of a Markov chain \ R(k): k ≥ 0\ on Rn such that the ith component of R(k), denoted Ri(k), corresponds to the value of the process on vertex i at time k. We focus on processes \ R(k): k ≥ 0\ where the value of Ri(k+1) depends only on the values \ Rj(k): j i\ of its inbound neighbors, and possibly on vertex attributes. We then show that, provided G(Vn, En) converges in the local weak sense to a marked Galton-Watson process, the dynamics of the process for a uniformly chosen vertex in Vn can be coupled, for any fixed k, to a process \ R(r): 0 ≤ r ≤ k\ constructed on the limiting marked Galton-Watson tree. Moreover, we derive sufficient conditions under which R(k) converges, as k ∞, to a random variable R* that can be characterized in terms of the attracting endogenous solution to a branching distributional fixed-point equation. Our framework can also be applied to processes \ R(k): k ≥ 0\ whose only source of randomness comes from the realization of the graph G(Vn, En).