A reduced order model based on Kalman filtering for sequential data assimilation of turbulent flows

A Kalman filter based sequential estimator is presented in this work. The estimator is integrated in the structure of segregated solvers for the analysis of incompressible flows. This technique provides an augmented flow state integrating available observation in the CFD model, naturally preserving...

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Bibliographic Details
Published in:Journal of computational physics 2017-10, Vol.347, p.207-234
Main Authors: Meldi, M., Poux, A.
Format: Article
Language:English
Subjects:
Computational fluid dynamics
Computational physics
Computer simulation
Covariance
Divergence
Filtration
Fluid Dynamics
Fluid flow
Fluid mechanics
Incompressible flow
Kalman Filter
Kalman filters
Mathematical models
Mechanics
Model reduction
Numerical analysis
Numerical simulation
Physics
Reduced order filters
Reduced order models
Solvers
Studies
Turbulent flow
Turbulent flows
Velocity distribution
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Summary:A Kalman filter based sequential estimator is presented in this work. The estimator is integrated in the structure of segregated solvers for the analysis of incompressible flows. This technique provides an augmented flow state integrating available observation in the CFD model, naturally preserving a zero-divergence condition for the velocity field. Because of the prohibitive costs associated with a complete Kalman Filter application, two model reduction strategies have been proposed and assessed. These strategies dramatically reduce the increase in computational costs of the model, which can be quantified in an augmentation of 10%–15% with respect to the classical numerical simulation. In addition, an extended analysis of the behavior of the numerical model covariance Q has been performed. Optimized values are strongly linked to the truncation error of the discretization procedure. The estimator has been applied to the analysis of a number of test cases exhibiting increasing complexity, including turbulent flow configurations. The results show that the augmented flow successfully improves the prediction of the physical quantities investigated, even when the observation is provided in a limited region of the physical domain. In addition, the present work suggests that these Data Assimilation techniques, which are at an embryonic stage of development in CFD, may have the potential to be pushed even further using the augmented prediction as a powerful tool for the optimization of the free parameters in the numerical simulation.
ISSN:0021-9991
1090-2716
DOI:10.1016/j.jcp.2017.06.042