Weighted Matrix Completion and Recovery with Prior Subspace Information

Dehui Yang; Michael  Wakin; Armin  Eftekhari

doi:10.1109/TIT.2018.2816685

Weighted Matrix Completion and Recovery with Prior Subspace Information

Dehui Yang, Michael Wakin, Armin Eftekhari

Colorado School of Mines

Research output: Contribution to journal › Article › peer-review

39 Citations (Scopus)

Abstract

An incoherent low-rank matrix can be efficiently reconstructed after observing a few of its entries at random, and then, solving a convex program that minimizes the nuclear norm. In many applications, in addition to these entries, potentially valuable prior knowledge about the column and row spaces of the matrix is also available to the practitioner. In this paper, we incorporate this prior knowledge in matrix completion - by minimizing a weighted nuclear norm - and precisely quantify any improvements. In particular, we find in theory that reliable prior knowledge reduces the sample complexity of matrix completion by a logarithmic factor, and the observed improvement in numerical simulations is considerably more magnified. We also present similar results for the closely related problem of matrix recovery from generic linear measurements.

Original language	English
Pages (from-to)	4044-4071
Number of pages	28
Journal	IEEE Transactions on Information Theory
Volume	64
Issue number	6
DOIs	https://doi.org/10.1109/TIT.2018.2816685
Publication status	Published - 16 Mar 2018
Externally published	Yes

Keywords

Weighted matrix completion
convex optimization
nuclear norm minimization

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10.1109/TIT.2018.2816685

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abstract = "An incoherent low-rank matrix can be efficiently reconstructed after observing a few of its entries at random, and then, solving a convex program that minimizes the nuclear norm. In many applications, in addition to these entries, potentially valuable prior knowledge about the column and row spaces of the matrix is also available to the practitioner. In this paper, we incorporate this prior knowledge in matrix completion - by minimizing a weighted nuclear norm - and precisely quantify any improvements. In particular, we find in theory that reliable prior knowledge reduces the sample complexity of matrix completion by a logarithmic factor, and the observed improvement in numerical simulations is considerably more magnified. We also present similar results for the closely related problem of matrix recovery from generic linear measurements.",

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N2 - An incoherent low-rank matrix can be efficiently reconstructed after observing a few of its entries at random, and then, solving a convex program that minimizes the nuclear norm. In many applications, in addition to these entries, potentially valuable prior knowledge about the column and row spaces of the matrix is also available to the practitioner. In this paper, we incorporate this prior knowledge in matrix completion - by minimizing a weighted nuclear norm - and precisely quantify any improvements. In particular, we find in theory that reliable prior knowledge reduces the sample complexity of matrix completion by a logarithmic factor, and the observed improvement in numerical simulations is considerably more magnified. We also present similar results for the closely related problem of matrix recovery from generic linear measurements.

AB - An incoherent low-rank matrix can be efficiently reconstructed after observing a few of its entries at random, and then, solving a convex program that minimizes the nuclear norm. In many applications, in addition to these entries, potentially valuable prior knowledge about the column and row spaces of the matrix is also available to the practitioner. In this paper, we incorporate this prior knowledge in matrix completion - by minimizing a weighted nuclear norm - and precisely quantify any improvements. In particular, we find in theory that reliable prior knowledge reduces the sample complexity of matrix completion by a logarithmic factor, and the observed improvement in numerical simulations is considerably more magnified. We also present similar results for the closely related problem of matrix recovery from generic linear measurements.

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Weighted Matrix Completion and Recovery with Prior Subspace Information

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Keywords

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