An infinite-order, Boussinesq-type differential equation for wave shoaling over variable bathymetry is derived. Defining three scaling parameters -nonlinearity, the dispersion parameter, and the bottom slope -the system is truncated to a finite order. Using Padé approximants the order in the dispersion parameter is effectively doubled. A derivation is made systematic by separately solving the Laplace equation in the undisturbed fluid domain and then addressing the nonlinear free-surface conditions. We show that the nonlinear interactions are faithfully captured. The shoaling and dispersion components are time independent.
We derive a deterministic directional shoaling model and a stochastic
directional
shoaling model for a gravity surface wave field, valid for a beach with
parallel depth
contours accounting for refraction and nonlinear quadratic (three wave)
interactions.
A new phenomenon of non-resonant spectral evolution arises due to the medium
inhomogeneity. The kernels of the kinetic equation depend on the bathymetry
through
an integral operator. Preliminary tests carried out on laboratory data
for a
unidirectional case indicate that the stochastic model also works rather
well
beyond the region
where the waves may be regarded as nearly Gaussian. The limit of its applicability
is decided by the dispersivity of the medium (relative to the nonlinearity).
Good
agreement with both laboratory data and the underlying deterministic model
is found
up to a value of about 1.5 for the spectral peak Ursell number. Beyond
that only the
deterministic model matches the measurements.
Evolution of a nonlinear wave field along a laboratory tank is studied experimentally
and numerically. The numerical study is based on the Zakharov nonlinear equation,
which is modified to describe slow spatial evolution of unidirectional waves as they
move along the tank. Groups with various initial shapes, amplitudes and spectral
contents are studied. It is demonstrated that the applied theoretical model, which
does not impose any constraints on the spectral width, is capable of describing
accurately, both qualitatively and quantitatively, the slow spatial variation of the
group envelopes. The theoretical model also describes accurately the variation along
the tank of the spectral shapes, including free wave components and the bound waves.
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