Robust PCA by Manifold Optimization

Teng Zhang; Yi Yang

2018 JMLR JMLR 2018

Robust PCA by Manifold Optimization

Abstract

Robust PCA is a widely used statistical procedure to recover an underlying low-rank matrix with grossly corrupted observations. This work considers the problem of robust PCA as a nonconvex optimization problem on the manifold of low-rank matrices and proposes two algorithms based on manifold optimization. It is shown that, with a properly designed initialization, the proposed algorithms are guaranteed to converge to the underlying low-rank matrix linearly. Compared with a previous work based on the factorization of low-rank matrices Yi et al. (2016), the proposed algorithms reduce the dependence on the condition number of the underlying low-rank matrix theoretically. Simulations and real data examples confirm the competitive performance of our method. [abs] [ pdf ][ bib ] © JMLR 2018. (edit, beta)

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Authors

Teng Zhang , Yi Yang

Topics

Machine Learning > Core Methods > Representation Learning Mathematics & Optimization > Optimization > Continuous Optimization Machine Learning > Core Methods > Matrix Factorization

Keywords

nonconvex optimization robust pca manifold optimization low-rank matrix recovery robust principal component analysis linear convergence

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