Nonstationary Spatial Process Models with Spatially Varying Covariance Kernels

Spatial process models for capturing nonstationary behavior in scientific data present several challenges with regard to statistical inference and uncertainty quantification. While nonstationary spatially-varying kernels are attractive for their flexibility and richness, their practical implementation has been reported to be overwhelmingly cumbersome because of the high-dimensional parameter spaces resulting from the spatially varying process parameters. Matters are considerably exacerbated with the massive numbers of spatial locations over which measurements are available. With limited theoretical tractability offered by nonstationary spatial processes, overcoming such computational bottlenecks require a synergy between model construction and algorithm development. We build a class of scalable nonstationary spatial process models using spatially varying covariance kernels. We present some novel consequences of such representations that befit computationally efficient implementation. More specifically, we operate within a coherent Bayesian modeling framework to achieve full uncertainty quantification using a Hybrid Monte-Carlo with nested interweaving. We carry out experiments on synthetic data sets to explore model selection and parameter identifiability and assess inferential improvements accrued from the nonstationary modeling. We illustrate strengths and pitfalls with a data set on remote sensed normalized difference vegetation index with further analysis of a lead contamination data set in the Supplement.