Space-filling lattice designs for computer experiments
Abstract
This paper investigates the construction of space-filling designs for computer experiments. The space-filling property is characterized by the covering and separation radii of a design, which are integrated through the unified criterion of quasi-uniformity. We focus on a special class of designs, known as quasi-Monte Carlo (QMC) lattice point sets, and propose two construction algorithms. The first algorithm generates rank-1 lattice point sets as an approximation of quasi-uniform Kronecker sequences, where the generating vector is determined explicitly. As a byproduct of our analysis, we prove that this explicit point set achieves an isotropic discrepancy of . The second algorithm utilizes Korobov lattice point sets, employing the Lenstra--Lenstra--Lov\'{a}sz (LLL) basis reduction algorithm to identify the generating vector that ensures quasi-uniformity. Numerical experiments are provided to validate our theoretical claims regarding quasi-uniformity. Furthermore, we conduct empirical comparisons between various QMC point sets in the context of Gaussian process regression, showcasing the efficacy of the proposed designs for computer experiments.
Cite
@article{arxiv.2602.15390,
title = {Space-filling lattice designs for computer experiments},
author = {Naoki Sakai and Takashi Goda},
journal= {arXiv preprint arXiv:2602.15390},
year = {2026}
}
Comments
24 pages, 5 figures