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Bibliographic Details
Main Authors: Bulhões, Rodrigo de Souza, Paez, Marina Silva, Gamerman, Dani
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2511.18201
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author Bulhões, Rodrigo de Souza
Paez, Marina Silva
Gamerman, Dani
author_facet Bulhões, Rodrigo de Souza
Paez, Marina Silva
Gamerman, Dani
contents In this paper, we propose a Bayesian matrix-variate spatiotemporal modeling framework for jointly analyzing multiple response variables observed at spatial locations over time. The approach relaxes the standard assumption of spatial isotropy by incorporating a deformation-based mechanism, allowing the covariance structure to capture directional effects and nonstationary spatial dependence. Temporal dynamics are modeled through dynamic linear models, enabling coherent uncertainty propagation within a state-space formulation. Missing observations are handled via a data augmentation strategy that preserves the joint structure of the multivariate responses. The proposed methodology is evaluated through simulation studies and an application to air quality data. Results indicate that accounting for spatial deformation leads to substantial gains in predictive performance in anisotropic settings, while cross-variable dependence plays a secondary role in improving overall fit. The framework is computationally tractable for moderate numbers of spatial locations and responses, and provides a flexible basis for modeling multivariate spatiotemporal processes under incomplete data.
format Preprint
id arxiv_https___arxiv_org_abs_2511_18201
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Spatial deformation in a Bayesian spatiotemporal model for incomplete matrix-variate responses
Bulhões, Rodrigo de Souza
Paez, Marina Silva
Gamerman, Dani
Methodology
In this paper, we propose a Bayesian matrix-variate spatiotemporal modeling framework for jointly analyzing multiple response variables observed at spatial locations over time. The approach relaxes the standard assumption of spatial isotropy by incorporating a deformation-based mechanism, allowing the covariance structure to capture directional effects and nonstationary spatial dependence. Temporal dynamics are modeled through dynamic linear models, enabling coherent uncertainty propagation within a state-space formulation. Missing observations are handled via a data augmentation strategy that preserves the joint structure of the multivariate responses. The proposed methodology is evaluated through simulation studies and an application to air quality data. Results indicate that accounting for spatial deformation leads to substantial gains in predictive performance in anisotropic settings, while cross-variable dependence plays a secondary role in improving overall fit. The framework is computationally tractable for moderate numbers of spatial locations and responses, and provides a flexible basis for modeling multivariate spatiotemporal processes under incomplete data.
title Spatial deformation in a Bayesian spatiotemporal model for incomplete matrix-variate responses
topic Methodology
url https://arxiv.org/abs/2511.18201