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Discrete Gaussian Vector Fields On Meshes

Methodology 2025-07-29 v1 Statistics Theory Machine Learning Statistics Theory

Abstract

Though the underlying fields associated with vector-valued environmental data are continuous, observations themselves are discrete. For example, climate models typically output grid-based representations of wind fields or ocean currents, and these are often downscaled to a discrete set of points. By treating the area of interest as a two-dimensional manifold that can be represented as a triangular mesh and embedded in Euclidean space, this work shows that discrete intrinsic Gaussian processes for vector-valued data can be developed from discrete differential operators defined with respect to a mesh. These Gaussian processes account for the geometry and curvature of the manifold whilst also providing a flexible and practical formulation that can be readily applied to any two-dimensional mesh. We show that these models can capture harmonic flows, incorporate boundary conditions, and model non-stationary data. Finally, we apply these models to downscaling stationary and non-stationary gridded wind data on the globe, and to inference of ocean currents from sparse observations in bounded domains.

Keywords

Cite

@article{arxiv.2507.20024,
  title  = {Discrete Gaussian Vector Fields On Meshes},
  author = {Michael Gillan and Stefan Siegert and Ben Youngman},
  journal= {arXiv preprint arXiv:2507.20024},
  year   = {2025}
}
R2 v1 2026-07-01T04:20:22.788Z