Bayesian tensor regression using the Tucker decomposition for sparse spatial modeling
Daniela Michele Spencer,Rajarshi Guhaniyogi,Russell T. Shinohara,Raquel Prado +3 more
- 09 Mar 2022
TL;DR: A Bayesian method is proposed to model a scalar response with a tensor covariate using the Tucker tensor decomposition in order to retain the spatial relationship within a Tensor coefficient, while reducing the number of parameters varying within the model and applying regularization methods.
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Abstract: Modeling with multidimensional arrays, or tensors, often presents a problem due to high dimension-ality. In addition, these structures typically exhibit inherent sparsity, requiring the use of regularization methods to properly characterize an association between a tensor covariate and a scalar response. We propose a Bayesian method to efficiently model a scalar response with a tensor covariate using the Tucker tensor decomposition in order to retain the spatial relationship within a tensor coefficient, while reducing the number of parameters varying within the model and applying regularization methods. Simulated data are analyzed to compare the model to recently proposed methods. A neuroimaging analysis using data from the Alzheimer’s Data Neuroimaging Initiative is included to illustrate the benefits of the model structure in making inference.
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