Phase Transition of Spectral Fluctuations in Large Gram Matrices with a Variance Profile: A Unified Framework for Sparse CLTs

Abstract

We study the asymptotic spectral behavior of high-dimensional random Gram matrices with sparsity and a variance profile, motivated by applications in wireless communications. Specifically, we consider the Gram matrices Sn= Yn Yn*, where the entries of Yn are independent, centered, heteroscedastic, and sparse through Bernoulli masking. The sparsity level is parameterized as s=q2/n, where q ranges from polynomial order up to order n1/2. We investigate two asymptotic regimes: a moderate-sparsity regime with fixed s∈(0,1], and a high-sparsity regime where s0. In both regimes, we establish the convergence of the empirical spectral distribution of Sn to a deterministic limit, and further derive central limit theorems for linear spectral statistics using resolvent techniques and martingale difference arguments. Our analysis reveals a phase transition in the fluctuation behavior across the two regimes. In the high-sparsity regime, the asymptotic fluctuations are entirely governed by fourth-moment effects, with sparsity-scaled contributions being suppressed. Moreover, the leading deterministic term and the variance of the linear spectral statistic scale at different rates in q, causing the standard centering to fail and necessitating an explicit correction to recover a valid CLT. The results apply to both Gaussian and non-Gaussian entries and are illustrated through applications to hypothesis testing and outage probability analysis in large-scale MIMO systems.