Abstract
Remote-sensing technology, combined with depth-inversion algorithms, presents a promising opportunity to quantify the morphological evolution of sandy beaches during storms. Current depth-inversion algorithms such as cBathy rely on the linear wave dispersion relation to invert depth from remotely-sensed dispersion properties. In the surf zone, however, non-linear amplitude dispersion effects become important and significant deviations from the linear dispersion are expected (Martins et al., 2021). Optical imagery also suffers from other technical limitations when dealing with breaking waves (e.g., saturated pixels and phase shifts), which affects the stability and accuracy of remotely-sensed wave dispersive properties. These limitations explain the poor accuracy reached with common approaches in the surf zone (typically 100 percent error). This contribution paves the way to new depth-inversion algorithms suited to the surf zone, based on remotely-sensed free surface elevation data (e.g., by lidar scanners). We here report on the first efforts to account for non-linear amplitude dispersion effects.References
Herbers, T.H.C., S. Elgar, N. A. Sarap and R. T. Guza, 2002: Nonlinear dispersion of surface gravity waves in shallow water. J. Phys. Oceanogr., 32, 1181–1193.
Martins, K., P. Bonneton and H. Michallet, 2021: Dispersive characteristics of non-linear waves propagating and breaking over a mildly sloping laboratory beach. Coastal Eng., 167, 103917.
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Copyright (c) 2023 Kévin Martins, Philippe Bonneton, Olivier de Viron, Ian Turner, Mitchell Harley, Kristen Splinter