Estimation of (near) low-rank matrices with noise and high-dimensional scaling

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Abstract

We study an instance of high-dimensional statistical inference in which the goal is to use N noisy observations to estimate a matrix Θ* € Rk × p that is assumed to be either exactly low rank, or "near" low-rank, meaning that it can be well-approximated by a matrix with low rank. We consider an M-estimator based on regularization by the trace or nuclear norm over matrices, and analyze its performance under high-dimensional scaling. We provide non-asymptotic bounds on the Frobenius norm error that hold for a general class of noisy observation models, and apply to both exactly low-rank and approximately low-rank matrices. We then illustrate their consequences for a number of specific learning models, including low-rank multivariate or multi-task regression, system identification in vector autoregressive processes, and recovery of low-rank matrices from random projections. Simulations show excellent agreement with the high-dimensional scaling of the error predicted by our theory. Copyright 2010 by the author(s)/owner(s).

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APA

Negahban, S., & Wainwright, M. J. (2010). Estimation of (near) low-rank matrices with noise and high-dimensional scaling. In ICML 2010 - Proceedings, 27th International Conference on Machine Learning (pp. 823–830). https://doi.org/10.1214/10-aos850

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