Covariance Estimation for Matrix-variate Data via Fixed-rank Core Covariance Geometry

Abstract

We study the geometry of the fixed-rank core covariance manifold arising from the Kronecker-core decomposition of covariance matrices. As shown in Hoff, McCormack, and Zhang (2023), every covariance matrix of p1× p2 matrix-variate data uniquely decomposes into a separable component K and a core component C. Such a decomposition also exists for rank-r if p1/p2+p2/p1<r, with C sharing the same rank. If this core C exhibits a partial-isotropy structure, then a partial-isotropy rank-r core is a non-trivial convex combination of a rank-r core and Ip for p:=p1p2, where the weight on Ip measures the deviation of from separability. This motivates studying the geometry of the space of rank-r cores, Cp1,p2,r+. We show that Cp1,p2,r+ is a smooth manifold, except for a measure-zero subset associated with canonical decomposability. When r=p, Cp1,p2++:=Cp1,p2,p+ is itself a smooth manifold. The geometric properties, including smoothness of the positive definite cone via separability and the Riemannian gradient and Hessian operator relevant to Cp1,p2,r+, are also derived. As an application, we propose a partial-isotropy core shrinkage estimator for matrix-variate data.

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