The friendship paradox for sparse random graphs
Abstract
Let Gn be an undirected finite graph on n∈N vertices labelled by [n] = \1,…,n\. For i ∈ [n], let i,n be the friendship bias of vertex i, defined as the difference between the average degree of the neighbours of vertex i and the degree of vertex i itself when i is not isolated, and zero when i is isolated. Let μn denote the friendship-bias empirical distribution, i.e., the measure that puts mass 1n at each i,n, i ∈ [n]. The friendship paradox says that ∫R xμn(dx) ≥ 0, with equality if and only if in each connected component of Gn all the degrees are the same. We show that if (Gn)n∈N is a sequence of sparse random graphs that converges to a rooted random tree in the sense of convergence locally in probability, then μn converges weakly to a limiting measure μ that is expressible in terms of the law of the rooted random tree. We study μ for four classes of sparse random graphs: the homogeneous Erdos-R\'enyi random graph, the inhomogeneous Erdos-R\'enyi random graph, the configuration model and the preferential attachment model. In particular, we compute the first two moments of μ, identify the right tail of μ, and argue that μ([0,∞))≥12, a property we refer to as friendship paradox significance.
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