Eigenvalue Bounds for Random Matrices via Zerofreeness

Abstract

We introduce a new technique to prove bounds for the spectral radius of a random matrix, based on using Jensen's formula to establish the zerofreeness of the associated characteristic polynomial in a region of the complex plane. Our techniques are entirely non-asymptotic, and we instantiate it in three settings: (i) The spectral radius of non-asymptotic Girko matrices -- these are asymmetric matrices M ∈ Cn × n whose entries are independent and satisfy E Mij = 0 and E |Mij2| 1n. (ii) The spectral radius of non-asymptotic Wigner matrices -- these are symmetric matrices M ∈ Cn × n whose entries above the diagonal are independent and satisfy E Mij = 0, E |Mij2| 1n, and E |Mij4| 1n. (iii) The second eigenvalue of the adjacency matrix of a random d-regular graph on n vertices, as drawn from the configuration model. In all three settings, we obtain constant-probability eigenvalue bounds that are tight up to a constant. Applied to specific random matrix ensembles, we recover classic bounds for Wigner matrices, as well as results of Bordenave--Chafa\"i--Garc\'ia-Zelada, Bordenave--Lelarge--Massouli\'e, and Friedman, up to constants.