Generation of two-dimensional water waves by moving bottom disturbances
For engineers designing wavemakers, this provides a computational methodology, though the idealized BBM model limits practical applicability.
The paper investigates generating two-dimensional water waves using moving bottom disturbances, formulating the problem as a constrained nonlinear optimization to determine wavemaker shape and trajectory. Numerical results demonstrate feasibility, but no concrete performance numbers are provided.
We investigate the potential and limitations of the wave generation by disturbances moving at the bottom. More precisely, we assume that the wavemaker is composed of an underwater object of a given shape which can be displaced according to a prescribed trajectory. We address the practical question of computing the wavemaker shape and trajectory generating a wave with prescribed characteristics. For the sake of simplicity we model the hydrodynamics by a generalized forced Benjamin-Bona-Mahony (BBM) equation. This practical problem is reformulated as a constrained nonlinear optimization problem. Additional constraints are imposed in order to fulfill various practical design requirements. Finally, we present some numerical results in order to demonstrate the feasibility and performance of the proposed methodology.