Fast and scalable inference for spatial extreme value models

IF 0.8 4区数学 Q3 STATISTICS & PROBABILITY

Canadian Journal of Statistics-Revue Canadienne De Statistique Pub Date : 2024-08-21 DOI:10.1002/cjs.11829

Meixi Chen, Reza Ramezan, Martin Lysy

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Abstract

The generalized extreme value (GEV) distribution is a popular model for analyzing and forecasting extreme weather data. To increase prediction accuracy, spatial information is often pooled via a latent Gaussian process (GP) on the GEV parameters. Inference for GEV-GP models is typically carried out using Markov Chain Monte Carlo (MCMC) methods, or using approximate inference methods such as the integrated nested Laplace approximation (INLA). However, MCMC becomes prohibitively slow as the number of spatial locations increases, whereas INLA is applicable in practice only to a limited subset of GEV-GP models. In this article, we revisit the original Laplace approximation for fitting spatial GEV models. In combination with a popular sparsity-inducing spatial covariance approximation technique, we show through simulations that our approach accurately estimates the Bayesian predictive distribution of extreme weather events, is scalable to several thousand spatial locations, and is several orders of magnitude faster than MCMC. A case study in forecasting extreme snowfall across Canada is presented.

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快速、可扩展的空间极值模型推理

广义极值（GEV）分布是分析和预测极端天气数据的常用模型。为了提高预测精度，通常会通过关于 GEV 参数的潜在高斯过程 (GP) 汇集空间信息。GEV-GP 模型的推断通常使用马尔可夫链蒙特卡罗（MCMC）方法，或使用近似推断方法，如集成嵌套拉普拉斯近似（INLA）。然而，随着空间位置数量的增加，MCMC 的速度会变得过慢，而 INLA 在实践中只适用于 GEV-GP 模型的有限子集。在本文中，我们重新审视了用于拟合空间 GEV 模型的原始拉普拉斯近似。结合流行的稀疏性诱导空间协方差近似技术，我们通过仿真表明，我们的方法能准确估计极端天气事件的贝叶斯预测分布，可扩展到数千个空间位置，而且比 MCMC 快几个数量级。我们还介绍了预测加拿大极端降雪的案例研究。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Canadian Journal of Statistics-Revue Canadienne De Statistique 数学-统计学与概率论

CiteScore

1.40

自引率

0.00%

发文量

审稿时长

>12 weeks

期刊介绍： The Canadian Journal of Statistics is the official journal of the Statistical Society of Canada. It has a reputation internationally as an excellent journal. The editorial board is comprised of statistical scientists with applied, computational, methodological, theoretical and probabilistic interests. Their role is to ensure that the journal continues to provide an international forum for the discipline of Statistics. The journal seeks papers making broad points of interest to many readers, whereas papers making important points of more specific interest are better placed in more specialized journals. The levels of innovation and impact are key in the evaluation of submitted manuscripts.