Non-backtracking eigenvalues and eigenvectors of random regular graphs and hypergraphs

Abstract

The non-backtracking operator of a graph is a powerful tool in spectral graph theory and random matrix theory. Most existing results for the non-backtracking operator of a random graph concern only eigenvalues or top eigenvectors. In this paper, we take the first step in analyzing its bulk eigenvector behaviors. We demonstrate that for the non-backtracking operator B of a random d-regular graph, its eigenvectors corresponding to nontrivial eigenvalues are completely delocalized with high probability. Additionally, we show complete delocalization for a reduced 2n × 2n non-backtracking matrix B. By projecting all eigenvalues of B onto the real line, we obtain an empirical measure that converges weakly in probability to the Kesten-McKay law for fixed d≥ 3 and to a semicircle law as d ∞ with n ∞. We extend our analysis to random regular hypergraphs, including the limiting measure of the real part of the spectrum for B, ∞-norm bounds for the eigenvectors of B and B, and a deterministic relation between eigenvectors of B and the eigenvectors of the adjacency matrix. As an application, we analyze the non-backtracking spectrum of the regular stochastic block model (RSBM) and provide a spectral method based on eigenvectors of B to recover the community structure exactly. We also show that there exists an isolated real eigenvalue with an informative eigenvector inside the circle of radius d1+d2-1 in the spectrum of B, analogous to the "eigenvalue insider" phenomenon for the Erdos-R\'enyi stochastic block model conjectured in Dall'Amico et al. (2019).

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