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Quadratic shrinkage for large covariance matrices

Olivier Ledoit, Michael Wolf

2022Bernoulli75 citationsDOIOpen Access PDF

Abstract

This paper constructs a new estimator for large covariance matrices by drawing a bridge between the classic (Stein (1975)) estimator in finite samples and recent progress under large-dimensional asymptotics. The estimator keeps the eigenvectors of the sample covariance matrix and applies shrinkage to the inverse sample eigenvalues. The corresponding formula is quadratic: it has two shrinkage targets weighted by quadratic functions of the concentration (that is, matrix dimension divided by sample size). The first target dominates mid-level concentrations and the second one higher levels. This extra degree of freedom enables us to outperform linear shrinkage when the optimal shrinkage is not linear, which is the general case. Both of our targets are based on what we term the “Stein shrinker”, a local attraction operator that pulls sample covariance matrix eigenvalues towards their nearest neighbors, but whose force diminishes with distance (like gravitation). We prove that no cubic or higher-order nonlinearities beat quadratic with respect to Frobenius loss under large-dimensional asymptotics. Non-normality and the case where the matrix dimension exceeds the sample size are accommodated. Monte Carlo simulations confirm state-of-the-art performance in terms of accuracy, speed, and scalability.

Topics & Concepts

MathematicsShrinkage estimatorEigenvalues and eigenvectorsEstimation of covariance matricesCovarianceShrinkageCovariance matrixQuadratic equationEstimatorMatrix (chemical analysis)Applied mathematicsDimension (graph theory)Bias of an estimatorStatisticsCombinatoricsGeometryMinimum-variance unbiased estimatorComposite materialPhysicsQuantum mechanicsMaterials scienceRandom Matrices and ApplicationsStatistical Methods and Bayesian InferenceMarkov Chains and Monte Carlo Methods