Projected Shadowing-based Data Assimilation

Bart de Leeuw; Svetlana Dubinkina; Jason Frank; Andrew Steyer; Xuemin Tu; Erik Van Vleck

Projected Shadowing-based Data Assimilation

Bart de Leeuw, Svetlana Dubinkina, Jason Frank, Andrew Steyer, Xuemin Tu, Erik Van Vleck

Research output: Working paper › Preprint › Academic

Abstract

In this article we develop algorithms for data assimilation based upon a computational time dependent stable/unstable splitting. Our particular method is based upon shadowing refinement and synchronization techniques and is motivated by work on Assimilation in the Unstable Subspace (AUS) and Pseudo-orbit Data Assimilation (PDA). The algorithm utilizes time dependent projections onto the non-stable subspace determined by employing computational techniques for Lyapunov exponents/vectors. The method is extended to parameter estimation without changing the problem dynamics and we address techniques for adapting the method when (as is commonly the case) observations are not available in the full model state space. We use a combination of analysis and numerical experiments (with the Lorenz 63 and Lorenz 96 models) to illustrate the efficacy of the techniques and show that the results compare favorably with other variational techniques.

Original language	English
Publication status	Published - 28 Jul 2017

Publication series

Name	arXiv

Keywords

math.DS
math.NA
nlin.CD
62M20, 37C50, 34D06, 37M25

Cite this

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title = "Projected Shadowing-based Data Assimilation",

abstract = "In this article we develop algorithms for data assimilation based upon a computational time dependent stable/unstable splitting. Our particular method is based upon shadowing refinement and synchronization techniques and is motivated by work on Assimilation in the Unstable Subspace (AUS) and Pseudo-orbit Data Assimilation (PDA). The algorithm utilizes time dependent projections onto the non-stable subspace determined by employing computational techniques for Lyapunov exponents/vectors. The method is extended to parameter estimation without changing the problem dynamics and we address techniques for adapting the method when (as is commonly the case) observations are not available in the full model state space. We use a combination of analysis and numerical experiments (with the Lorenz 63 and Lorenz 96 models) to illustrate the efficacy of the techniques and show that the results compare favorably with other variational techniques.",

keywords = "math.DS, math.NA, nlin.CD, 62M20, 37C50, 34D06, 37M25",

author = "Leeuw, {Bart de} and Svetlana Dubinkina and Jason Frank and Andrew Steyer and Xuemin Tu and Vleck, {Erik Van}",

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day = "28",

language = "English",

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T1 - Projected Shadowing-based Data Assimilation

AU - Leeuw, Bart de

AU - Dubinkina, Svetlana

AU - Frank, Jason

AU - Steyer, Andrew

AU - Tu, Xuemin

AU - Vleck, Erik Van

PY - 2017/7/28

Y1 - 2017/7/28

N2 - In this article we develop algorithms for data assimilation based upon a computational time dependent stable/unstable splitting. Our particular method is based upon shadowing refinement and synchronization techniques and is motivated by work on Assimilation in the Unstable Subspace (AUS) and Pseudo-orbit Data Assimilation (PDA). The algorithm utilizes time dependent projections onto the non-stable subspace determined by employing computational techniques for Lyapunov exponents/vectors. The method is extended to parameter estimation without changing the problem dynamics and we address techniques for adapting the method when (as is commonly the case) observations are not available in the full model state space. We use a combination of analysis and numerical experiments (with the Lorenz 63 and Lorenz 96 models) to illustrate the efficacy of the techniques and show that the results compare favorably with other variational techniques.

AB - In this article we develop algorithms for data assimilation based upon a computational time dependent stable/unstable splitting. Our particular method is based upon shadowing refinement and synchronization techniques and is motivated by work on Assimilation in the Unstable Subspace (AUS) and Pseudo-orbit Data Assimilation (PDA). The algorithm utilizes time dependent projections onto the non-stable subspace determined by employing computational techniques for Lyapunov exponents/vectors. The method is extended to parameter estimation without changing the problem dynamics and we address techniques for adapting the method when (as is commonly the case) observations are not available in the full model state space. We use a combination of analysis and numerical experiments (with the Lorenz 63 and Lorenz 96 models) to illustrate the efficacy of the techniques and show that the results compare favorably with other variational techniques.

KW - math.DS

KW - math.NA

KW - nlin.CD

KW - 62M20, 37C50, 34D06, 37M25

M3 - Preprint

T3 - arXiv

BT - Projected Shadowing-based Data Assimilation

ER -

Projected Shadowing-based Data Assimilation

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Keywords

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