On a data-model assimilation method to inverse wave-dominated beach bathymetry using heterogeneous video-derived observations

On a data-model assimilation method to inverse wave-dominated beach bathymetry using heterogeneous video-derived observations

A data-model assimilation method is presented that can combine heterogeneous remotely sensed video observations to inverse wave-dominated beach bathymetry. The ability of our method is assessed using synthetic cases from a laboratory experiment. For relatively flat beach profiles, good bathymetry in...

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Bibliographic Details
Published in:Ocean engineering Vol. 73; pp. 126 - 138
Main Authors: Birrien, Florent, Castelle, Bruno, Marieu, Vincent, Dubarbier, Benjamin
Format: Journal Article
Language:English
Published: Kidlington Elsevier Ltd 15-11-2013
Elsevier
Subjects:
Applied sciences
Buildings. Public works
Data-model assimilation
Depth inversion
Exact sciences and technology
Hydraulic constructions
Kalman filter
Nearshore bathymetry
Port facilities and coastal structures. Lighthouses and beacons
Remotely sensed observation
Nearshore bathymetry
Remotely sensed observation
Data-model assimilation
Kalman filter
Depth inversion
Morphological variation
Bathymetry
Beaches
Coastal zone
Data assimilation
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Summary:A data-model assimilation method is presented that can combine heterogeneous remotely sensed video observations to inverse wave-dominated beach bathymetry. The ability of our method is assessed using synthetic cases from a laboratory experiment. For relatively flat beach profiles, good bathymetry inversion can be obtained with a small number (O(1)) of observations and a simple Gaussian-type background error matrix. For more complex barred-beach profiles, localisation of the background error matrix is crucial to depth inversion and the required number of observations is increased (O(10)). In the latter situation, both relevant location of observations and the corresponding localisation length scales can be properly defined without the knowledge of the local bathymetry, resulting in accurate bathymetry inversion, which is a major asset for practical applications. Our method also allows shifting between several sources of bathymetry proxy as well as overlapping which provides flexibility in data management. Multi-1D reconstruction can also be performed to estimate complex 3D beach morphologies. Our study therefore suggests that high-performing time-efficient nearshore bathymetry inversion can be achieved using a limited set of heterogeneous video-derived observations. •We present a novel data-model assimilation method to inverse beach bathymetry.•The method can combine heterogeneous remotely sensed video observations.•Good bathymetric inversion is obtained using one or multiple sources of observations.•Relevance and location of the observations are more reliable than data abundance.
ISSN:0029-8018
1873-5258
DOI:10.1016/j.oceaneng.2013.08.002