Joint variable selection of both fixed and random effects for Gaussian process-based spatially varying coefficient models

Joint variable selection of both fixed and random effects for Gaussian process-based spatially varying coefficient models

Spatially varying coefficient (SVC) models are a type of regression models for spatial data where covariate effects vary over space. If there are several covariates, a natural question is which covariates have a spatially varying effect and which not. We present a new variable selection approach for...

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Bibliographic Details
Published in:International journal of geographical information science : IJGIS Vol. 36; no. 12; pp. 2525 - 2548
Main Authors: Dambon, Jakob A., Sigrist, Fabio, Furrer, Reinhard
Format: Journal Article
Language:English
Published: Abingdon Taylor & Francis 02-12-2022
Taylor & Francis LLC
Subjects:
Adaptive LASSO
Bayesian optimization
coordinate descent algorithm
Gaussian process
Maximum likelihood estimation
model-based optimization
penalized maximum likelihood estimation
Performance prediction
Regression analysis
Regression models
Simulation
Spatial data
spatial statistics
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Summary:Spatially varying coefficient (SVC) models are a type of regression models for spatial data where covariate effects vary over space. If there are several covariates, a natural question is which covariates have a spatially varying effect and which not. We present a new variable selection approach for Gaussian process-based SVC models. It relies on a penalized maximum likelihood estimation and allows joint variable selection both with respect to fixed effects and Gaussian process random effects. We validate our approach in a simulation study as well as a real world data set. In the simulation study, the penalized maximum likelihood estimation correctly identifies zero fixed and random effects, while the penalty-induced bias of non-zero estimates is negligible. In the real data application, our proposed penalized maximum likelihood estimation yields sparser SVC models and achieves a smaller information criterion than classical maximum likelihood estimation. In a cross-validation study applied on the real data, we show that our proposed penalized maximum likelihood estimation consistently yields the sparsest SVC models while achieving similar predictive performance compared to other SVC modeling methodologies.
ISSN:1365-8816
1365-8824
1362-3087
DOI:10.1080/13658816.2022.2097684