English

Rapid Approximation Prediction for Kriging

Methodology 2026-05-29 v1 Applications Computation

Abstract

Exact Kriging and conditional simulation (CS) for uncertainty quantification are computationally infeasible for modern spatial analyses with large numbers of observations and dense prediction grids. We present a rapid approximation to the Kriging prediction step for stationary Gaussian processes for a regular prediction grid by approximating each off-grid covariance vector by a sparse linear combination of on-grid covariances within a local LL-order neighborhood of M=(2L)2M = (2L)^2 neighboring grid points. This reformulation reduces complexity from O(Nn3)O(N n^3) to O(NlogN+nM+M3)O(N \log N + nM + M^3) while preserving accuracy. A factorial study shows that approximation error decreases systematically with increased Mat\'{e}rn smoothness, neighbor order LL, and grid resolution, aligning with bounds from kernel approximation theory. In a North American summer-rainfall application (n=1368n=1368), our method produces predictions visually indistinguishable from exact Kriging with point-wise errors on the order of 10510^{-5} inches and achieves more than 150150 times speedups at a 350×350350\times350 grid, also outperforming Vecchia and LatticeKrig predictions. Embedded in a fast CS scheme, the approach reproduces Kriging standard errors and scales favorably with both nn and NN. We recommend a practical workflow that uses a fast method for parameter estimation followed by our rapid predictor for fine-grid mapping and uncertainty quantification.

Keywords

Cite

@article{arxiv.2605.29284,
  title  = {Rapid Approximation Prediction for Kriging},
  author = {Ziyu Li and Gregory Fasshauer and Douglas Nychka},
  journal= {arXiv preprint arXiv:2605.29284},
  year   = {2026}
}

Comments

11 figures, 38 pages