Abstract
For each $n$, let $A_n=(\sigma_{ij})$ be an $n\times n$ deterministic matrix and let $X_n=(X_{ij})$ be an $n\times n$ random matrix with i.i.d. centered entries of unit variance. We study the asymptotic behavior of the empirical spectral distribution $\mu_n^Y$ of the rescaled entry-wise product \[ Y_n = \left(\frac1{\sqrt{n}} \sigma_{ij}X_{ij}\right). \] For our main result we provide a deterministic sequence of probability measures $\mu_n$, each described by a family of Master Equations, such that the difference $\mu^Y_n - \mu_n$ converges weakly in probability to the zero measure. A key feature of our results is to allow some of the entries $\sigma_{ij}$ to vanish, provided that the standard deviation profiles $A_n$ satisfy a certain quantitative irreducibility property. An important step is to obtain quantitative bounds on the solutions to an associate system of Schwinger--Dyson equations, which we accomplish in the general sparse setting using a novel graphical bootstrap argument.
Highlights
For our main result we provide a deterministic sequence of probability measures μn, each described by a family of Master Equations, such that the difference μYn − μn converges weakly in probability to the zero measure
Bounds of this form on the expected density of states for random Hermitian operators are sometimes referred to as local Wegner estimates. Their application to the convergence of the empirical spectral distribution for non-Hermitian random matrices goes back to Bai’s proof of the circular law [15]; our presentation of the argument is closer to the one in [34]
We remark that under the stronger broad connectivity assumption on the standard deviation profile, Wegner-type estimates that are sufficient for the purposes of this paper were obtained by the first author by a completely different argument, following a geometric approach introduced by Tao and Vu in [60] – see [24, Theorem 4.5.1]
Summary
In this article we study the following general class of random matrices with nonidentically distributed entries. Definition 1.2 (Random matrix with a variance profile). The empirical spectral distribution of Yn is denoted by μYn. We refer to An as the standard deviation profile and to An An = (σi(jn)) as the variance profile. We define the normalized variance profile as Vn = n−1An An. When no ambiguity occurs, we will drop the index n and write σij , Xij , V , etc. Our goal is to describe the asymptotic behavior of the ESDs μYn given a sequence of standard deviation profiles An which can be sparse, and may not converge in any sense to a limiting standard deviation profile
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