Spectrally Robust Covariance Shrinkage for Hotelling's T2 in High Dimensions
Abstract
We investigate covariance shrinkage for Hotelling's T2 in the regime where the data dimension p and the sample size n grow in a fixed ratio -- without assuming that the population covariance matrix is spiked or well-conditioned. When p/nφ ∈ (0,1), we propose a practical finite-sample shrinker that, for any maximum-entropy signal prior and any fixed significance level, (a) asymptotically maximizes power under Gaussian data, and (b) asymptotically saturates the Hanson--Wright lower bound on power in the more general sub-Gaussian case. Our approach is to formulate and solve a variational problem characterizing the optimal limiting shrinker, and to show that our finite-sample method consistently approximates this limit by extending recent local random matrix laws. Empirical studies on simulated and real-world data, including the Crawdad UMich/RSS data set, demonstrate up to a 50\% gain in power over leading linear and nonlinear competitors at a significance level of 10-4.
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