Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm

Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm

The matrix completion problem (MC) has been approximated by using the nuclear norm relaxation. Some algorithms based on this strategy require the computationally expensive singular value decomposition (SVD) at each iteration. One way to avoid SVD calculations is to use alternating methods, which p...

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Bibliographic Details
Main Authors: Hugo Lara, Harry Oviedo, Jinjun Yuan
Format: Article
Language:English
Published: Universidad Simón Bolívar 2015-02-01
Series:Bulletin of Computational Applied Mathematics
Subjects:
matrix completion
alternanting minimization
nonlinear Gauss-Seidel method
nonlinear SOR method
Augmented Lagrange method
Online Access:http://drive.google.com/open?id=0B5GyVVQ6O030bEVPb3owckh5YVE
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spelling doaj-51d51a82defa4ba18782696211ea66ad2020-11-24T22:53:41ZengUniversidad Simón BolívarBulletin of Computational Applied Mathematics2244-86592244-86592015-02-01222146Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation AlgorithmHugo Lara0Harry Oviedo1Jinjun Yuan2Department of Operational Research and Statistics, Universidad CentroOccidental Lisandro Alvarado, Núcleo Obelisco 3001, Barquisimeto, VenezuelaMaestria en Optimización, Universidad CentroOccidental Lisandro Alvarado, Núcleo Obelisco, 3001, Barquisimeto, VenezuelaDepartment of Mathematics, Federal University of Parana, Centro Politecnico, Curitiba, CEP 81531-990, PR, BrazilThe matrix completion problem (MC) has been approximated by using the nuclear norm relaxation. Some algorithms based on this strategy require the computationally expensive singular value decomposition (SVD) at each iteration. One way to avoid SVD calculations is to use alternating methods, which pursue the completion through matrix factorization with a low rank condition. In this work an augmented Lagrangean-type alternating algorithm is proposed. The new algorithm uses duality information to define the iterations, in contrast to the solely primal LMaFit algorithm, which employs a Successive Over Relaxation scheme. The convergence result is studied. Some numerical experiments are given to compare numerical performance of both proposals.http://drive.google.com/open?id=0B5GyVVQ6O030bEVPb3owckh5YVEmatrix completionalternanting minimizationnonlinear Gauss-Seidel methodnonlinear SOR methodAugmented Lagrange method
collection DOAJ
language English
format Article
sources DOAJ
author Hugo Lara
Harry Oviedo
Jinjun Yuan
spellingShingle Hugo Lara
Harry Oviedo
Jinjun Yuan
Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm
Bulletin of Computational Applied Mathematics
matrix completion
alternanting minimization
nonlinear Gauss-Seidel method
nonlinear SOR method
Augmented Lagrange method
author_facet Hugo Lara
Harry Oviedo
Jinjun Yuan
author_sort Hugo Lara
title Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm
title_short Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm
title_full Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm
title_fullStr Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm
title_full_unstemmed Matrix completion via a low rank factorization model and an Augmented Lagrangean Succesive Overrelaxation Algorithm
title_sort matrix completion via a low rank factorization model and an augmented lagrangean succesive overrelaxation algorithm
publisher Universidad Simón Bolívar
series Bulletin of Computational Applied Mathematics
issn 2244-8659
2244-8659
publishDate 2015-02-01
description The matrix completion problem (MC) has been approximated by using the nuclear norm relaxation. Some algorithms based on this strategy require the computationally expensive singular value decomposition (SVD) at each iteration. One way to avoid SVD calculations is to use alternating methods, which pursue the completion through matrix factorization with a low rank condition. In this work an augmented Lagrangean-type alternating algorithm is proposed. The new algorithm uses duality information to define the iterations, in contrast to the solely primal LMaFit algorithm, which employs a Successive Over Relaxation scheme. The convergence result is studied. Some numerical experiments are given to compare numerical performance of both proposals.
topic matrix completion
alternanting minimization
nonlinear Gauss-Seidel method
nonlinear SOR method
Augmented Lagrange method
url http://drive.google.com/open?id=0B5GyVVQ6O030bEVPb3owckh5YVE
work_keys_str_mv AT hugolara matrixcompletionviaalowrankfactorizationmodelandanaugmentedlagrangeansuccesiveoverrelaxationalgorithm
AT harryoviedo matrixcompletionviaalowrankfactorizationmodelandanaugmentedlagrangeansuccesiveoverrelaxationalgorithm
AT jinjunyuan matrixcompletionviaalowrankfactorizationmodelandanaugmentedlagrangeansuccesiveoverrelaxationalgorithm
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