Green-Naghdi Theory, Part B: Green-Naghdi Equations for Deep Water Waves

Green-Naghdi Theory, Part B: Green-Naghdi Equations for Deep Water Waves

“Green — Naghdi Theory, Part A: Green — Naghdi (GN) Equations for Shallow Water Waves” have investigated the linear dispersion relations of high-level GN equations in shallow water. In this study, the GN equations for deep water waves are investigated. In the traditional GN equations for deep water...

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Veröffentlicht in:Journal of marine science and application 2023-03, Vol.22 (1), p.44-51
Hauptverfasser: Duan, Shiliang, Zhao, Binbin, Webster, W. C.
Format: Artikel
Sprache:eng
Schlagworte:
Deep water
Dispersion
Distribution
Electrical Machines and Networks
Engineering
Finite difference method
Geotechnical Engineering & Applied Earth Sciences
Machinery and Machine Elements
Mathematical analysis
Offshore Engineering
Power Electronics
Research Article
Shallow water
Shallow water waves
Shape functions
Three dimensional analysis
Velocity
Velocity distribution
Water depth
Water waves
Wave number
Wavelengths
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Zusammenfassung:“Green — Naghdi Theory, Part A: Green — Naghdi (GN) Equations for Shallow Water Waves” have investigated the linear dispersion relations of high-level GN equations in shallow water. In this study, the GN equations for deep water waves are investigated. In the traditional GN equations for deep water waves, the velocity distribution assumption involves only one representative wave number. Herein, a new velocity distribution shape function with multiple representative wave numbers is employed. Further, we have derived the three-dimensional GN equations and analyzed the linear dispersion relations of the GN-3 and GN-5 equations. In this study, the finite difference method is used to simulate focus waves in the time domain. Additionally, the GN-5 equations are used to validate the wave profile and horizontal velocity distribution along water depth for different focused waves.
ISSN:1671-9433
1993-5048
DOI:10.1007/s11804-023-00316-y