Degree centrality and root finding in growing random networks

Abstract

We consider growing random networks \ Gn\n 1 where, at each time, a new vertex attaches itself to a collection of existing vertices via a fixed number m 1 of edges, with probability proportional to an attachment function f of their degree. It was shown in BBpersistence that such network models exhibit two regimes: (i) the persistent regime, corresponding to Σi=1∞f(i)-2 < ∞, where the top K maximal degree vertices fixate over time for any given K, and (ii) the non-persistent regime, with Σi=1∞f(i)-2 = ∞, where the identities of these vertices keep changing infinitely often over time. We develop root finding algorithms using the empirical degree structure and local network information based on a snapshot of such a network at some large time. In the persistent regime, the algorithm is purely based on degree centrality, that is, for a given error tolerance ∈ (0,1), there exists K such that for any n 1, the confidence set for the root in Gn, which contains the root with probability at least 1 - , consists of the top K maximal degree vertices. In particular, the size of the confidence set is stable in the network size. Upper and lower bounds on K are explicitly characterized in terms of the error tolerance and the attachment function f. In the non-persistent regime, for an appropriate choice of rn → ∞ at a rate much smaller than the diameter of the network, the neighborhood of radius rn around the maximal degree vertex is shown to contain the root with high probability, and a size estimate for this set is obtained. It is shown that, when f(k) = kα, k 1, for any α ∈ (0,1/2], this size grows at a smaller rate than any positive power of the network size.