Moment-Based Spectral Analysis of Random Graphs with Given Expected Degrees

Abstract

In this paper, we analyze the limiting spectral distribution of the adjacency matrix of a random graph ensemble, proposed by Chung and Lu, in which a given expected degree sequence wn^T = (w(n)1,…,w(n)n) is prescribed on the ensemble. Let ai,j =1 if there is an edge between the nodes \i,j\ and zero otherwise, and consider the normalized random adjacency matrix of the graph ensemble: An = [ai,j/n]i,j=1n. The empirical spectral distribution of An denoted by Fn(·) is the empirical measure putting a mass 1/n at each of the n real eigenvalues of the symmetric matrix An. Under some technical conditions on the expected degree sequence, we show that with probability one, Fn(·) converges weakly to a deterministic distribution F(·). Furthermore, we fully characterize this distribution by providing explicit expressions for the moments of F(·). We apply our results to well-known degree distributions, such as power-law and exponential. The asymptotic expressions of the spectral moments in each case provide significant insights about the bulk behavior of the eigenvalue spectrum.