A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models

A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models

In this paper, we propose an efficient EnKF implementation for non-Gaussian data assimilation based on Gaussian Mixture Models and Markov-Chain-Monte-Carlo (MCMC) methods. The proposed method works as follows: based on an ensemble of model realizations, prior errors are estimated via a Gaussian Mixt...

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Main Authors: Elias D. Nino-Ruiz, Haiyan Cheng, Rolando Beltran
Format: Article
Language:English
Published: MDPI AG 2018-03-01
Series:Atmosphere
Subjects:
ensemble Kalman filter
Gaussian Mixture Models
non-linear observation operator
Markov-Chain-Monte-Carlo
Online Access:http://www.mdpi.com/2073-4433/9/4/126
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spelling doaj-0b6888e634514de08a2b58b6e442afd12020-11-24T22:42:43ZengMDPI AGAtmosphere2073-44332018-03-019412610.3390/atmos9040126atmos9040126A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear ModelsElias D. Nino-Ruiz0Haiyan Cheng1Rolando Beltran2Applied Math and Computational Science Laboratory, Department of Computer Science, Universidad del Norte, Barranquilla 080001, ColombiaDepartment of Computer Science, Willamette University, 900 State Street, Salem, OR 97301, USAApplied Math and Computational Science Laboratory, Department of Computer Science, Universidad del Norte, Barranquilla 080001, ColombiaIn this paper, we propose an efficient EnKF implementation for non-Gaussian data assimilation based on Gaussian Mixture Models and Markov-Chain-Monte-Carlo (MCMC) methods. The proposed method works as follows: based on an ensemble of model realizations, prior errors are estimated via a Gaussian Mixture density whose parameters are approximated by means of an Expectation Maximization method. Then, by using an iterative method, observation operators are linearized about current solutions and posterior modes are estimated via a MCMC implementation. The acceptance/rejection criterion is similar to that of the Metropolis-Hastings rule. Experimental tests are performed on the Lorenz 96 model. The results show that the proposed method can decrease prior errors by several order of magnitudes in a root-mean-square-error sense for nearly sparse or dense observational networks.http://www.mdpi.com/2073-4433/9/4/126ensemble Kalman filterGaussian Mixture Modelsnon-linear observation operatorMarkov-Chain-Monte-Carlo
collection DOAJ
language English
format Article
sources DOAJ
author Elias D. Nino-Ruiz
Haiyan Cheng
Rolando Beltran
spellingShingle Elias D. Nino-Ruiz
Haiyan Cheng
Rolando Beltran
A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models
Atmosphere
ensemble Kalman filter
Gaussian Mixture Models
non-linear observation operator
Markov-Chain-Monte-Carlo
author_facet Elias D. Nino-Ruiz
Haiyan Cheng
Rolando Beltran
author_sort Elias D. Nino-Ruiz
title A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models
title_short A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models
title_full A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models
title_fullStr A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models
title_full_unstemmed A Robust Non-Gaussian Data Assimilation Method for Highly Non-Linear Models
title_sort robust non-gaussian data assimilation method for highly non-linear models
publisher MDPI AG
series Atmosphere
issn 2073-4433
publishDate 2018-03-01
description In this paper, we propose an efficient EnKF implementation for non-Gaussian data assimilation based on Gaussian Mixture Models and Markov-Chain-Monte-Carlo (MCMC) methods. The proposed method works as follows: based on an ensemble of model realizations, prior errors are estimated via a Gaussian Mixture density whose parameters are approximated by means of an Expectation Maximization method. Then, by using an iterative method, observation operators are linearized about current solutions and posterior modes are estimated via a MCMC implementation. The acceptance/rejection criterion is similar to that of the Metropolis-Hastings rule. Experimental tests are performed on the Lorenz 96 model. The results show that the proposed method can decrease prior errors by several order of magnitudes in a root-mean-square-error sense for nearly sparse or dense observational networks.
topic ensemble Kalman filter
Gaussian Mixture Models
non-linear observation operator
Markov-Chain-Monte-Carlo
url http://www.mdpi.com/2073-4433/9/4/126
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