Limiting Spectral Distribution of a Random Commutator Matrix

Abstract

We study the spectral properties of a class of random matrices of the form Sn- = n-1(X1 X2* - X2 X1*) where Xk = 1/2Zk, for k=1,2, Zk's are independent p× n complex-valued random matrices, and is a p× p positive semi-definite matrix, independent of the Zk's. We assume that Zk's have independent entries with zero mean and unit variance. The skew-symmetric/skew-Hermitian matrix Sn- will be referred to as a random commutator matrix associated with the samples X1 and X2. We show that, when the dimension p and sample size n increase simultaneously, so that p/n c ∈ (0,∞), there exists a limiting spectral distribution (LSD) for Sn-, supported on the imaginary axis, under the assumptions that the spectral distribution of converges weakly and the entries of Zk's have moments of sufficiently high order. This nonrandom LSD can be described through its Stieltjes transform, which satisfies a coupled Marcenko-Pastur-type functional equations. In the special case when = Ip, we show that the LSD of Sn- is a mixture of a degenerate distribution at zero (with positive mass if c > 2), and a continuous distribution with a symmetric density function supported on a compact interval on the imaginary axis. Moreover, we show that the companion matrix Sn+ = n12(Z1Z2* + Z2Z1*)n12, under identical assumptions, has an LSD supported on the real line, which can be similarly characterized.