Gaussian process regression with log-linear scaling for common non-stationary kernels

IF 2.6 2区数学 Q1 MATHEMATICS, APPLIED

Applied and Computational Harmonic Analysis Pub Date : 2025-07-05 DOI:10.1016/j.acha.2025.101792

P. Michael Kielstra , Michael Lindsey

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引用次数: 0

Abstract

We introduce a fast algorithm for Gaussian process regression in low dimensions, applicable to a widely-used family of non-stationary kernels. The non-stationarity of these kernels is induced by arbitrary spatially-varying vertical and horizontal scales. In particular, any stationary kernel can be accommodated as a special case, and we focus especially on the generalization of the standard Matérn kernel. Our subroutine for kernel matrix-vector multiplications scales almost optimally as

O (N \log N)

, where N is the number of regression points. Like the recently developed equispaced Fourier Gaussian process (EFGP) methodology, which is applicable only to stationary kernels, our approach exploits non-uniform fast Fourier transforms (NUFFTs). We offer a complete analysis controlling the approximation error of our method, and we validate the method's practical performance with numerical experiments. In particular we demonstrate improved scalability compared to state-of-the-art rank-structured approaches in spatial dimension

d > 1

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常见非平稳核的对数线性标度高斯过程回归

我们介绍了一种快速的低维高斯过程回归算法，适用于广泛使用的非平稳核族。这些核的非平稳性是由任意空间变化的垂直和水平尺度引起的。特别地，任何平稳核都可以作为一种特殊情况，我们特别关注标准mat核的推广。我们的核矩阵-向量乘法子程序的尺度几乎为O(Nlog (N))，其中N是回归点的数量。就像最近开发的均等化傅立叶高斯过程（EFGP）方法一样，该方法仅适用于平稳核，我们的方法利用了非均匀快速傅立叶变换（nufft）。对控制方法的逼近误差进行了完整的分析，并通过数值实验验证了该方法的实用性能。特别是，与空间维度d>；1的最先进的秩结构方法相比，我们展示了改进的可扩展性。

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来源期刊

Applied and Computational Harmonic Analysis 物理-物理：数学物理

CiteScore

5.40

自引率

4.00%

发文量

审稿时长

22.9 weeks

期刊介绍： Applied and Computational Harmonic Analysis (ACHA) is an interdisciplinary journal that publishes high-quality papers in all areas of mathematical sciences related to the applied and computational aspects of harmonic analysis, with special emphasis on innovative theoretical development, methods, and algorithms, for information processing, manipulation, understanding, and so forth. The objectives of the journal are to chronicle the important publications in the rapidly growing field of data representation and analysis, to stimulate research in relevant interdisciplinary areas, and to provide a common link among mathematical, physical, and life scientists, as well as engineers.