Advanced stationary and nonstationary kernel designs for domain-aware Gaussian processes

IF 1.9 3区 数学 Q1 MATHEMATICS, APPLIED Communications in Applied Mathematics and Computational Science Pub Date : 2022-10-07 DOI:10.2140/camcos.2022.17.131
Marcus M. Noack, James A. Sethian
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引用次数: 12

Abstract

Gaussian process regression is a widely applied method for function approximation and uncertainty quantification. The technique has recently gained popularity in the machine learning community due to its robustness and interpretability. The mathematical methods we discuss in this paper are an extension of the Gaussian process framework. We are proposing advanced kernel designs that only allow for functions with certain desirable characteristics to be elements of the reproducing kernel Hilbert space (RKHS) that underlies all kernel methods and serves as the sample space for Gaussian process regression. These desirable characteristics reflect the underlying physics; two obvious examples are symmetry and periodicity constraints. In addition, we want to draw attention to nonstationary kernel designs that can be defined in the same framework to yield flexible multitask Gaussian processes. We will show the impact of advanced kernel designs on Gaussian processes using several synthetic and two scientific data sets. The results show that informing a Gaussian process of domain knowledge, combined with additional flexibility and communicated through advanced kernel designs, has a significant impact on the accuracy and relevance of the function approximation.

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领域感知高斯过程的高级平稳和非平稳核设计
高斯过程回归是一种应用广泛的函数逼近和不确定性量化方法。由于其鲁棒性和可解释性,该技术最近在机器学习社区中得到了普及。本文讨论的数学方法是高斯过程框架的一种扩展。我们提出了先进的核设计,只允许具有某些理想特征的函数成为再现核希尔伯特空间(RKHS)的元素,该空间是所有核方法的基础,并作为高斯过程回归的样本空间。这些理想的特性反映了潜在的物理特性;两个明显的例子是对称约束和周期性约束。此外,我们希望提请注意非平稳核设计,它可以在相同的框架中定义,以产生灵活的多任务高斯过程。我们将使用几个合成数据集和两个科学数据集来展示高级核设计对高斯过程的影响。结果表明,将领域知识告知高斯过程,结合额外的灵活性,并通过先进的核设计进行交流,对函数逼近的准确性和相关性有显著影响。
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来源期刊
Communications in Applied Mathematics and Computational Science
Communications in Applied Mathematics and Computational Science MATHEMATICS, APPLIED-PHYSICS, MATHEMATICAL
CiteScore
3.50
自引率
0.00%
发文量
3
审稿时长
>12 weeks
期刊介绍: CAMCoS accepts innovative papers in all areas where mathematics and applications interact. In particular, the journal welcomes papers where an idea is followed from beginning to end — from an abstract beginning to a piece of software, or from a computational observation to a mathematical theory.
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