Local circular law for the product of a deterministic matrix with a random matrix

Abstract

It is well known that the spectral measure of eigenvalues of a rescaled square non-Hermitian random matrix with independent entries satisfies the circular law. We consider the product TX, where T is a deterministic N× M matrix and X is a random M× N matrix with independent entries having zero mean and variance (N M)-1. We prove a general local circular law for the empirical spectral distribution (ESD) of TX at any point z away from the unit circle under the assumptions that N M, and the matrix entries Xij have sufficiently high moments. More precisely, if z satisfies ||z|-1| τ for arbitrarily small τ>0, the ESD of TX converges to D(z) dA(z), where D is a rotation-invariant function determined by the singular values of T and dA denotes the Lebesgue measure on C. The local circular law is valid around z up to scale (N M)-1/4+ε for any ε>0. Moreover, if |z|>1 or the matrix entries of X have vanishing third moments, the local circular law is valid around z up to scale (N M)-1/2+ε for any ε>0.