Optimal Eigenvalue Rigidity of Random Regular Graphs

Abstract

Consider the normalized adjacency matrices of random d-regular graphs on N vertices with fixed degree d≥ 3, and denote the eigenvalues as λ1=d/d-1≥ λ2≥λ3·s≥ λN. We prove that the optimal (up to an extra N oN(1) factor, where oN(1) can be arbitrarily small) eigenvalue rigidity holds. More precisely, denote γi as the classical location of the i-th eigenvalue under the Kesten-Mckay law in decreasing order. Then with probability 1-N-1+ oN(1), align* |λi-γi|≤ N oN(1)N2/3 (\i,N-i+1\)1/3, for all i∈ \2,3,·s,N\. align* In particular, the fluctuations of extreme eigenvalues are bounded by N-2/3+ oN(1). This gives the same order of fluctuation as for the eigenvalues of matrices from the Gaussian Orthogonal Ensemble.

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