N. Booij scite author profile

Abstract. A third-generation numerical wave model to compute random, short-crested waves in coastal regions with shallow water and ambient currents (Simulating Waves Nearshore (SWAN)) has been developed, implemented, and validated. The model is based on a Eulerian formulation of the discrete spectral balance of action density that accounts for refractive propagation over arbitrary bathymetry and current fields. It is driven by boundary conditions and local winds. As in other third-generation wave models, the processes of wind generation, whitecapping, quadruplet wave-wave interactions, and bottom dissipation are represented explicitly. In SWAN, triad wave-wave interactions and depth-induced wave breaking are added. In contrast to other third-generation wave models, the numerical propagation scheme is implicit, which implies that the computations are more economic in shallow water. The model results agree well with analytical solutions, laboratory observations, and (generalized) field observations.

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A third‐generation wave model for coastal regions: 2. Verification

Ris¹,

Holthuijsen²,

Booij³

1999

J. Geophys. Res.

762

344

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Abstract. A third-generation spectral wave model (Simulating Waves Nearshore (SWAN)) for small-scale, coastal regions with shallow water, (barrier) islands, tidal flats, local wind, and ambient currents is verified in stationary mode with measurements in five real field cases. These verification cases represent an increasing complexity in twodimensional bathymetry and added presence of currents. In the most complex of these cases, the waves propagate through a tidal gap between two barrier islands into a bathymetry of channels and shoals with tidal currents where the waves are regenerated by a local wind. The wave fields were highly variable with up to 3 orders of magnitude difference in energy scale in individual cases. The model accounts for shoaling, refraction, generation by wind, whitecapping, triad and quadruplet wave-wave interactions, and bottom and depth-induced wave breaking. The effect of alternative formulations of these processes is shown. In all cases a relatively large number of wave observations is available, including observations of wave directions. The average rms error in the computed significant wave height and mean wave period is 0.30 m and 0.7 s, respectively, which is 10% of the incident values for both. IntroductionThe wave model Simulating Waves Nearshore (SWAN) has been developed by the authors (described by Booij et al. The results of the SWAN computations are presented and compared with the observed significant wave height, mean wave period, and mean wave direction. In addition, a comparison is made between computed and observed spectra. The structure of the paper is as follows. The SWAN model is briefly described in section 2. The verification cases are described in section 3. A quantitative analysis of these verifications is given in section 4. A discussion and the conclusions of this study are given in sections 5 and 6, respectively.•Now at WL/Delft Hydraulics, Delft, Netherlands.

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The "Swan" Wave Model for Shallow Water

1997

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A prediction model for stationary, short-crested waves in shallow water with ambient currents

Holthuijsen

Booij

Herbers

1989

Coastal Engineering

266

114

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Phase-decoupled refraction–diffraction for spectral wave models

Holthuijsen

Herman

Booij

2003

Coastal Engineering

180

112

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N. Booij

A third‐generation wave model for coastal regions: 1. Model description and validation

A third‐generation wave model for coastal regions: 2. Verification

The "Swan" Wave Model for Shallow Water

A prediction model for stationary, short-crested waves in shallow water with ambient currents

Phase-decoupled refraction–diffraction for spectral wave models

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