Please use this identifier to cite or link to this item: http://hdl.handle.net/10739/3266
Title: Spectral boundary element modeling of water waves in Pohang New Harbor and Paradip Port
Authors: Rupali, .
Kumar, Prashant
Rajni
Keywords: Spectral boundary element method
Chebyshev point discretization
Helmholtz equation
Paradip port and pohang new harbor
Spectral density
Issue Date: 15-Jan-2020
Publisher: Elsevier
Citation: Rupali, Kumar, Prashant and Rajni (2020) Spectral boundary element modeling of water waves in Pohang New Harbor and Paradip Port. Ocean Engineering. Volume 196, 15 January 2020, 106765
Abstract: A novel mathematical model formulation based on spectral boundary element method (SBEM) is presented to examine the wave response in the Pohang New Harbor (PNH), South Korea and Paradip port, Odisha, India. In SBEM, the boundary element method (BEM) is coupled with the spectral element method (SEM) to enhance the numerical accuracy of the present numerical scheme. The numerical solution on each boundary element is obtained by using boundary integral associated with Chebyshev point discretization. The boundary Integrals are transformed using Jacobians and evaluated with Clenshaw Curtis Quadrature rule. Convergence analysis is performed on rectangular domain for present scheme, BEM and hybrid finite element method (HFEM), which shows that the present numerical scheme is better as compared to other traditional numerical schemes. Further, the simulation results are validated with BEM, analytical method and experimental data from Lee (1971) and Ippen and Goda (1963). The wave amplification is obtained at six record stations inside the PNH, South Korea and Paradip port, Odisha, India. In addition, the spectral density is also determined for multidirectional random waves propagating towards the PNH and Paradip port at the same record station. The resonant frequencies are estimated in PNH and Paradip port for the safe navigation of moored ship.
URI: http://hdl.handle.net/10739/3266
Appears in Collections:JGU Research Publications

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