Bayesian Kriging Approaches for Spatial Functional Data

Functional kriging approaches have been developed to predict the curves at unobserved spatial locations. However, most existing approaches are based on variogram fittings rather than constructing hierarchical statistical models. Therefore, it is challenging to analyze the relationships between functional variables, and uncertainty quantification of the model is not trivial. In this manuscript, we propose a Bayesian framework for spatial function-on-function regression. However, inference for the proposed model has computational and inferential challenges because the model needs to account for within and between-curve dependencies. Furthermore, high-dimensional and spatially correlated parameters can lead to the slow mixing of Markov chain Monte Carlo algorithms. To address these issues, we first utilize a basis transformation approach to simplify the covariance and apply projection methods for dimension reduction. We also develop a simultaneous band score for the proposed model to detect the significant region in the regression function. We apply the methods to simulated and real datasets, including data on particulate matter in Japan and mobility data in South Korea. The proposed method is computationally efficient and provides accurate estimations and predictions.