Optimal Eigenvalue Rigidity of Random Regular Graphs
Abstract
Consider the normalized adjacency matrices of random -regular graphs on vertices with fixed degree , and denote the eigenvalues as . We prove that the optimal (up to an extra factor, where can be arbitrarily small) eigenvalue rigidity holds. More precisely, denote as the classical location of the -th eigenvalue under the Kesten-Mckay law in decreasing order. Then with probability , \begin{align*} |\lambda_i-\gamma_i|\leq \frac{N^{{\rm o}_N(1)}}{N^{2/3} (\min\{i,N-i+1\})^{1/3}},\quad \text{ for all } i\in \{2,3,\cdots,N\}. \end{align*} In particular, the fluctuations of extreme eigenvalues are bounded by . This gives the same order of fluctuation as for the eigenvalues of matrices from the Gaussian Orthogonal Ensemble.
Keywords
Cite
@article{arxiv.2405.12161,
title = {Optimal Eigenvalue Rigidity of Random Regular Graphs},
author = {Jiaoyang Huang and Theo McKenzie and Horng-Tzer Yau},
journal= {arXiv preprint arXiv:2405.12161},
year = {2024}
}
Comments
62 pages, 2 figures