Abstract
We propose a Bayesian methodology for estimating spiked covariance matrices with a jointly sparse structure in high dimensions. The spiked covariance matrix is reparameterized in terms of the latent factor model, where the loading matrix is equipped with a novel matrix spike-and-slab LASSO prior, which is a continuous shrinkage prior for modeling jointly sparse matrices. We establish the rate-optimal posterior contraction for the covariance matrix with respect to the spectral norm as well as that for the principal subspace with respect to the projection spectral norm loss. We also study the posterior contraction rate of the principal subspace with respect to the two-to-infinity norm loss, a novel loss function measuring the distance between subspaces that is able to capture entrywise eigenvector perturbations. We show that the posterior contraction rate with respect to the two-to-infinity norm loss is tighter than that with respect to the routinely used projection spectral norm loss under certain low-rank and bounded coherence conditions. In addition, a point estimator for the principal subspace is proposed with the rate-optimal risk bound with respect to the projection spectral norm loss. The numerical performance of the proposed methodology is assessed through synthetic examples and the analysis of a real-world face data example.
Funding Statement
The work of Xu was supported by NSF 1918854 and NSF 1940107.
Citation
Fangzheng Xie. Joshua Cape. Carey E. Priebe. Yanxun Xu. "Bayesian Sparse Spiked Covariance Model with a Continuous Matrix Shrinkage Prior." Bayesian Anal. 17 (4) 1193 - 1217, December 2022. https://doi.org/10.1214/21-BA1292
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