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用于多尺度非线性随机系统的条件高斯系统:预测、状态估计与不确定性量化

Conditional Gaussian Systems for Multiscale Nonlinear Stochastic Systems: Prediction, State Estimation and Uncertainty Quantification.

作者信息

Chen Nan, Majda Andrew J

机构信息

Department of Mathematics and Center for Atmosphere Ocean Science, Courant Institute of Mathematical Sciences, New York University, New York, NY 10012, USA.

Center for Prototype Climate Modeling, New York University Abu Dhabi, Saadiyat Island, Abu Dhabi 129188, UAE.

出版信息

Entropy (Basel). 2018 Jul 4;20(7):509. doi: 10.3390/e20070509.

DOI:10.3390/e20070509
PMID:33265599
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7513031/
Abstract

A conditional Gaussian framework for understanding and predicting complex multiscale nonlinear stochastic systems is developed. Despite the conditional Gaussianity, such systems are nevertheless highly nonlinear and are able to capture the non-Gaussian features of nature. The special structure of the system allows closed analytical formulae for solving the conditional statistics and is thus computationally efficient. A rich gallery of examples of conditional Gaussian systems are illustrated here, which includes data-driven physics-constrained nonlinear stochastic models, stochastically coupled reaction-diffusion models in neuroscience and ecology, and large-scale dynamical models in turbulence, fluids and geophysical flows. Making use of the conditional Gaussian structure, efficient statistically accurate algorithms involving a novel hybrid strategy for different subspaces, a judicious block decomposition and statistical symmetry are developed for solving the Fokker-Planck equation in large dimensions. The conditional Gaussian framework is also applied to develop extremely cheap multiscale data assimilation schemes, such as the stochastic superparameterization, which use particle filters to capture the non-Gaussian statistics on the large-scale part whose dimension is small whereas the statistics of the small-scale part are conditional Gaussian given the large-scale part. Other topics of the conditional Gaussian systems studied here include designing new parameter estimation schemes and understanding model errors.

摘要

开发了一种用于理解和预测复杂多尺度非线性随机系统的条件高斯框架。尽管具有条件高斯性,但此类系统仍然高度非线性,并且能够捕捉自然的非高斯特征。系统的特殊结构允许使用封闭的解析公式来求解条件统计量,因此计算效率很高。这里展示了丰富的条件高斯系统示例库,其中包括数据驱动的物理约束非线性随机模型、神经科学和生态学中的随机耦合反应扩散模型,以及湍流、流体和地球物理流中的大规模动力学模型。利用条件高斯结构,开发了高效的统计精确算法,这些算法涉及针对不同子空间的新颖混合策略、明智的块分解和统计对称性,用于求解高维福克 - 普朗克方程。条件高斯框架还被应用于开发极其廉价的多尺度数据同化方案,例如随机超参数化,它使用粒子滤波器来捕捉大规模部分(其维度较小)的非高斯统计量,而小规模部分的统计量在给定大规模部分的情况下是条件高斯的。这里研究的条件高斯系统的其他主题包括设计新的参数估计方案和理解模型误差。

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