Convergence of the empirical spectral distribution of Gaussian matrix-valued processes

Abstract

For a given normalized Gaussian symmetric matrix-valued process Y(n), we consider the process of its eigenvalues \(λ1(n)(t),…, λn(n)(t)); t 0\ as well as its corresponding process of empirical spectral measures μ(n)=(μt(n); t≥0). Under some mild conditions on the covariance function associated to Y(n), we prove that the process μ(n) converges in probability to a deterministic limit μ, in the topology of uniform convergence over compact sets. We show that the process μ is characterized by its Cauchy transform, which is a rescaling of the solution of a Burgers' equation. Our results extend those of Rogers and Shi for the free Brownian motion and Pardo et al. for the non-commutative fractional Brownian motion when H>1/2 whose arguments use strongly the non-collision of the eigenvalues. Our methodology does not require the latter property and in particular explains the remaining case of the non-commutative fractional Brownian motion for H< 1/2 which, up to our knowledge, was unknown.