Improved Boussinesq-type equations for highly variable depth

Abstract

Intermediate-depth, Boussinesq-type modelling is used to generalize previously known results for surface water waves propagating over arbitrarily shaped topographies. The improved reduced wave model is obtained after studying how small changes in the linear dispersion relation (over a flat bottom) can become dramatically important in the presence of a highly fluctuating topography. Numerical validation of the dispersive properties, regarding several possible truncations for the reduced models, are compared with the complete (non-truncated) linear potential theory model. Moreover, linear L 2 -estimates are extended from the analysis of KdV-type models to include the improved Boussinesq systems in contrast with potential theory. Discrepancies observed among the different possible reduced models become even more important in the wave-form inversion problem. The time reversal technique is used for recompressing a long fluctuating signal, representing a highly scattered wave that has propagated for very long distances. When properly back-propagated (through a numerical model), the scattered signal refocuses into a smooth profile representing the onset of the ocean's surface disturbance. Previous Boussinesq models underestimate the original disturbance's amplitude. The improved Boussinesq system agrees very well with the full potential theory predictions.