Litcius/Paper detail

Low Tucker rank tensor completion using a symmetric block coordinate descent method

Quan Yu, Xinzhen Zhang, Yannan Chen, Liqun Qi

2022Numerical Linear Algebra with Applications22 citationsDOI

Abstract

Abstract Low Tucker rank tensor completion has wide applications in science and engineering. Many existing approaches dealt with the Tucker rank by unfolding matrix rank. However, unfolding a tensor to a matrix would destroy the data's original multi‐way structure, resulting in vital information loss and degraded performance. In this article, we establish a relationship between the Tucker ranks and the ranks of the factor matrices in Tucker decomposition. Then, we reformulate the low Tucker rank tensor completion problem as a multilinear low rank matrix completion problem. For the reformulated problem, a symmetric block coordinate descent method is customized. For each matrix rank minimization subproblem, the classical truncated nuclear norm minimization is adopted. Furthermore, temporal characteristics in image and video data are introduced to such a model, which benefits the performance of the method. Numerical simulations illustrate the efficiency of our proposed models and methods.

Topics & Concepts

Matrix completionCoordinate descentMathematicsTucker decompositionRank (graph theory)Multilinear mapMatrix normLow-rank approximationMatrix (chemical analysis)Tensor (intrinsic definition)Mathematical optimizationMinificationMatrix decompositionSparse matrixApplied mathematicsAlgorithmCombinatoricsTensor decompositionGeometryPure mathematicsEigenvalues and eigenvectorsComposite materialGaussianQuantum mechanicsMaterials sciencePhysicsTensor decomposition and applicationsSparse and Compressive Sensing TechniquesImage and Signal Denoising Methods