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Volume 6, Issue 1
Fluid Flow Estimation with Multiscale Ensemble Filters Based on Motion Measurements Under Location Uncertainty

Sébastien Beyou, Thomas Corpetti, Sai Gorthi & Etienne Mémin

Numer. Math. Theor. Meth. Appl., 6 (2013), pp. 21-46.

Published online: 2013-06

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  • Abstract

This paper proposes a novel multi-scale fluid flow data assimilation approach, which integrates and complements the advantages of a Bayesian sequential assimilation technique, the Weighted Ensemble Kalman filter (WEnKF) [27]. The data assimilation proposed in this work incorporates measurement brought by an efficient multiscale stochastic formulation of the well-known Lucas-Kanade (LK) estimator. This estimator has the great advantage to provide uncertainties associated to the motion measurements at different scales. The proposed assimilation scheme benefits from this multiscale uncertainty information and enables to enforce a physically plausible dynamical consistency of the estimated motion fields along the image sequence. Experimental evaluations are presented on synthetic and real fluid flow sequences.

  • AMS Subject Headings

65M10, 78A48

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COPYRIGHT: © Global Science Press

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@Article{NMTMA-6-21, author = {Sébastien Beyou, Thomas Corpetti, Sai Gorthi and Etienne Mémin}, title = {Fluid Flow Estimation with Multiscale Ensemble Filters Based on Motion Measurements Under Location Uncertainty}, journal = {Numerical Mathematics: Theory, Methods and Applications}, year = {2013}, volume = {6}, number = {1}, pages = {21--46}, abstract = {

This paper proposes a novel multi-scale fluid flow data assimilation approach, which integrates and complements the advantages of a Bayesian sequential assimilation technique, the Weighted Ensemble Kalman filter (WEnKF) [27]. The data assimilation proposed in this work incorporates measurement brought by an efficient multiscale stochastic formulation of the well-known Lucas-Kanade (LK) estimator. This estimator has the great advantage to provide uncertainties associated to the motion measurements at different scales. The proposed assimilation scheme benefits from this multiscale uncertainty information and enables to enforce a physically plausible dynamical consistency of the estimated motion fields along the image sequence. Experimental evaluations are presented on synthetic and real fluid flow sequences.

}, issn = {2079-7338}, doi = {https://doi.org/10.4208/nmtma.2013.mssvm02}, url = {http://global-sci.org/intro/article_detail/nmtma/5893.html} }
TY - JOUR T1 - Fluid Flow Estimation with Multiscale Ensemble Filters Based on Motion Measurements Under Location Uncertainty AU - Sébastien Beyou, Thomas Corpetti, Sai Gorthi & Etienne Mémin JO - Numerical Mathematics: Theory, Methods and Applications VL - 1 SP - 21 EP - 46 PY - 2013 DA - 2013/06 SN - 6 DO - http://doi.org/10.4208/nmtma.2013.mssvm02 UR - https://global-sci.org/intro/article_detail/nmtma/5893.html KW - Data assimilation, stochastic filter, particle filters, fluid motion estimation. AB -

This paper proposes a novel multi-scale fluid flow data assimilation approach, which integrates and complements the advantages of a Bayesian sequential assimilation technique, the Weighted Ensemble Kalman filter (WEnKF) [27]. The data assimilation proposed in this work incorporates measurement brought by an efficient multiscale stochastic formulation of the well-known Lucas-Kanade (LK) estimator. This estimator has the great advantage to provide uncertainties associated to the motion measurements at different scales. The proposed assimilation scheme benefits from this multiscale uncertainty information and enables to enforce a physically plausible dynamical consistency of the estimated motion fields along the image sequence. Experimental evaluations are presented on synthetic and real fluid flow sequences.

Sébastien Beyou, Thomas Corpetti, Sai Gorthi and Etienne Mémin. (2013). Fluid Flow Estimation with Multiscale Ensemble Filters Based on Motion Measurements Under Location Uncertainty. Numerical Mathematics: Theory, Methods and Applications. 6 (1). 21-46. doi:10.4208/nmtma.2013.mssvm02
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