Litcius/Paper detail

Bayesian Tensor Tucker Completion With a Flexible Core

Xueke Tong, Lei Cheng, Yik‐Chung Wu

2023IEEE Transactions on Signal Processing15 citationsDOI

Abstract

Tensor completion is a vital task in multidimensional signal processing and machine learning. To recover the missing data in a tensor, various low-rank structures of a tensor can be assumed, and Tucker format is a popular choice. However, the promising capability of Tucker completion is realized only when we can determine a suitable multilinear rank, which controls the model complexity and thus is essential to avoid overfitting/underfitting. Rather than exhaustively searching the best multilinear rank, which is computationally inefficient, recent advances have proposed a Bayesian way to learn the multilinear rank from training data automatically. However, in prior arts, only a single parameter is dedicated to learn the variance of the core tensor elements. This rigid assumption restricts the modeling capabilities of existing methods in real-world data, where the core tensor elements may have a wide range of variances. To have a flexible core tensor while still retaining succinct Bayesian modeling, we first bridge the tensor Tucker decomposition to the canonical polyadic decomposition (CPD) with low-rank factor matrices, and then propose a novel Bayesian modeling based on the Gaussian-inverse Wishart prior. Inference algorithm is further derived under the variational inference framework. Extensive numerical studies on synthetic data and real-world datasets demonstrate the significantly improved performance of the proposed algorithm in terms of multilinear rank learning and missing data recovery.

Topics & Concepts

Multilinear mapTucker decompositionTensor (intrinsic definition)OverfittingRank (graph theory)Computer scienceArtificial intelligenceBayesian probabilityMissing dataInferenceAlgorithmMathematicsMachine learningTensor decompositionArtificial neural networkPure mathematicsCombinatoricsTensor decomposition and applicationsAdvanced SAR Imaging TechniquesSparse and Compressive Sensing Techniques
Bayesian Tensor Tucker Completion With a Flexible Core | Litcius