Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays

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Standard

Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays. / Hinrich, Jesper Love; Morup, Morten.

I: Computing in Science and Engineering, 2024.

Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › fagfællebedømt

Harvard

Hinrich, JL & Morup, M 2024, 'Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays', Computing in Science and Engineering. https://doi.org/10.1109/MCSE.2024.3398054

APA

Hinrich, J. L., & Morup, M. (Accepteret/In press). Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays. Computing in Science and Engineering. https://doi.org/10.1109/MCSE.2024.3398054

Vancouver

Hinrich JL, Morup M. Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays. Computing in Science and Engineering. 2024. https://doi.org/10.1109/MCSE.2024.3398054

Author

Hinrich, Jesper Love ; Morup, Morten. / Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays. I: Computing in Science and Engineering. 2024.

Bibtex

@article{eb90d28935c54a549202e92cf7ba0719,

title = "Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays",

abstract = "Tensors are ubiquitous in science and engineering and tensor factorization approaches have become important tools. This paper explores the use of Bayesian modeling in the context of tensor factorization and presents a probabilistic extension of the so-called Block-Term Decomposition (BTD) model and show how it can interpolate between two common decomposition models - the Canonical Polyadic Decomposition (CPD) and the Tucker decomposition. This probabilistic extension is obtained by applying Bayesian inference to the BTD model, allowing for uncertainty quantification, robustness to corruption by noise and model miss-specification. The novelty of this model is its applicability to Nth-order tensors, incorporating mode specific orthogonality within each block, and priors that penalizing complexity of the core arrays. On synthetic and two real datasets, we highlight the benefits of probabilistic tensor factorization considering the BTD, demonstrating that the probabilistic BTD can successfully quantify multi-linear structures and is robust to noise.",

keywords = "Bayes methods, Computational modeling, Data models, Maximum likelihood estimation, Noise, Probabilistic logic, Tensors",

author = "Hinrich, {Jesper Love} and Morten Morup",

note = "Publisher Copyright: IEEE",

year = "2024",

doi = "10.1109/MCSE.2024.3398054",

language = "English",

journal = "Computing in Science and Engineering",

issn = "1521-9615",

publisher = "Institute of Electrical and Electronics Engineers",

}

RIS

TY - JOUR

T1 - Probabilistic Block Term Decomposition for the Modelling of Higher-order Arrays

AU - Hinrich, Jesper Love

AU - Morup, Morten

N1 - Publisher Copyright: IEEE

PY - 2024

Y1 - 2024

N2 - Tensors are ubiquitous in science and engineering and tensor factorization approaches have become important tools. This paper explores the use of Bayesian modeling in the context of tensor factorization and presents a probabilistic extension of the so-called Block-Term Decomposition (BTD) model and show how it can interpolate between two common decomposition models - the Canonical Polyadic Decomposition (CPD) and the Tucker decomposition. This probabilistic extension is obtained by applying Bayesian inference to the BTD model, allowing for uncertainty quantification, robustness to corruption by noise and model miss-specification. The novelty of this model is its applicability to Nth-order tensors, incorporating mode specific orthogonality within each block, and priors that penalizing complexity of the core arrays. On synthetic and two real datasets, we highlight the benefits of probabilistic tensor factorization considering the BTD, demonstrating that the probabilistic BTD can successfully quantify multi-linear structures and is robust to noise.

AB - Tensors are ubiquitous in science and engineering and tensor factorization approaches have become important tools. This paper explores the use of Bayesian modeling in the context of tensor factorization and presents a probabilistic extension of the so-called Block-Term Decomposition (BTD) model and show how it can interpolate between two common decomposition models - the Canonical Polyadic Decomposition (CPD) and the Tucker decomposition. This probabilistic extension is obtained by applying Bayesian inference to the BTD model, allowing for uncertainty quantification, robustness to corruption by noise and model miss-specification. The novelty of this model is its applicability to Nth-order tensors, incorporating mode specific orthogonality within each block, and priors that penalizing complexity of the core arrays. On synthetic and two real datasets, we highlight the benefits of probabilistic tensor factorization considering the BTD, demonstrating that the probabilistic BTD can successfully quantify multi-linear structures and is robust to noise.

KW - Bayes methods

KW - Computational modeling

KW - Data models

KW - Maximum likelihood estimation

KW - Noise

KW - Probabilistic logic

KW - Tensors

U2 - 10.1109/MCSE.2024.3398054

DO - 10.1109/MCSE.2024.3398054

M3 - Journal article

AN - SCOPUS:85192766710

JO - Computing in Science and Engineering

JF - Computing in Science and Engineering

SN - 1521-9615

ER -

ID: 393271451