Nonparametric low-rank tensor imputation

Author

Bazerque, Juan Andrés ; Mateos, Gonzalo ; Giannakis, Georgios B.

Author_Institution

Dept. of ECE, Univ. of Minnesota, Minneapolis, MN, USA

fYear

2012

fDate

5-8 Aug. 2012

Firstpage

876

Lastpage

879

Abstract

Completion or imputation of three-way data arrays with missing entries is a basic problem encountered in various areas, including bio-informatics, image processing, and preference analysis. If available, prior information about the data at hand should be incorporated to enhance performance of the imputation method adopted. This is the motivation behind the proposed low-rank tensor estimator which leverages the correlation across slices of the data cube in the form of reproducing kernels. The rank of the tensor estimate is controlled by a novel regularization on the factors of its PARAFAC decomposition. Such a regularization is inspired by a reformulation of the nuclear norm for matrices, which allows to bypass the challenge that rank and singular values of tensors are unrelated quantities. The proposed technique is tested on MRI data of the brain with 30% missing data, resulting in a recovery error of -17dB.

Keywords

approximation theory; biomedical MRI; brain; lab-on-a-chip; matrix algebra; medical image processing; tensors; MRI data; PARAFAC decomposition; bioinformatics; brain; data cube; image processing; matrices; missing data; nonparametric low-rank tensor imputation; nonparametric tensor approximation; nuclear norm; preference analysis; three-way data arrays; Approximation methods; Correlation; Kernel; Matrix decomposition; Minimization; Tensile stress; Vectors; Tensor; kernel methods; low-rank; missing data;

fLanguage

English

Publisher

ieee

Conference_Titel

Statistical Signal Processing Workshop (SSP), 2012 IEEE

Conference_Location

Ann Arbor, MI

ISSN

pending

Print_ISBN

978-1-4673-0182-4

Electronic_ISBN

pending

Type

conf

DOI

10.1109/SSP.2012.6319847

Filename

6319847