Separation of the initial conditions in the inverse problem for 1D non-linear tsunami wave run-up theory

Abstract

We investigate the inverse tsunami wave problem within the framework of the 1D nonlinear shallow water equations (SWE). Specifically, we focus on determining the initial displacement η0(x) and velocity u0(x) of the wave, given the known motion of the shoreline R(t) (the wet/dry free boundary). We demonstrate that for power-shaped inclined bathymetries, this problem admits a complete solution for any η0 and u0, provided the wave does not break. In particular, we show that the knowledge of R(t) enables the unique recovery of both η0(x) and u0(x) in terms of the Abel transform. It is important to note that, in contrast to the direct problem (also known as the tsunami wave run-up problem), where R(t) can be computed exactly only for u0(x)=0, our algorithm can recover η0 and u0 exactly for any non-zero u0. This highlights an interesting asymmetry between the direct and inverse problems. Our results extend the work presented in Rybkin23,Rybkin24, where the inverse problem was solved for u0(x)=0. As in previous work, our approach utilizes the Carrier-Greenspan transformation, which linearizes the SWE for inclined bathymetries. Extensive numerical experiments confirm the efficiency of our algorithms.