TY - JOUR
T1 - An extremely efficient boundary element method for wave interaction with long cylindrical structures based on free-surface Green's function
AU - Liu, Yingyi
AU - Gou, Ying
AU - Teng, Bin
AU - Yoshida, Shigeo
N1 - Publisher Copyright:
© 2016 by the authors.
PY - 2016/9/16
Y1 - 2016/9/16
N2 - The present study aims to develop an efficient numerical method for computing the diffraction and radiation of water waves with horizontal long cylindrical structures, such as floating breakwaters in the coastal region, etc. A higher-order scheme is used to discretize geometry of the structure as well as the physical wave potentials. As the kernel of this method, Wehausen's free-surface Green function is calculated by a newly-developed Gauss-Kronrod adaptive quadrature algorithm after elimination of its Cauchy-type singularities. To improve its computation efficiency, an analytical solution is derived for a fast evaluation of the Green function that needs to be implemented thousands of times. In addition, the OpenMP parallelization technique is applied to the formation of the influence coefficient matrix, significantly reducing the running CPU time. Computations are performed on wave-exciting forces and hydrodynamic coefficients for the long cylindrical structures, either floating or submerged. Comparison with other numerical and analytical methods demonstrates a good performance of the present method.
AB - The present study aims to develop an efficient numerical method for computing the diffraction and radiation of water waves with horizontal long cylindrical structures, such as floating breakwaters in the coastal region, etc. A higher-order scheme is used to discretize geometry of the structure as well as the physical wave potentials. As the kernel of this method, Wehausen's free-surface Green function is calculated by a newly-developed Gauss-Kronrod adaptive quadrature algorithm after elimination of its Cauchy-type singularities. To improve its computation efficiency, an analytical solution is derived for a fast evaluation of the Green function that needs to be implemented thousands of times. In addition, the OpenMP parallelization technique is applied to the formation of the influence coefficient matrix, significantly reducing the running CPU time. Computations are performed on wave-exciting forces and hydrodynamic coefficients for the long cylindrical structures, either floating or submerged. Comparison with other numerical and analytical methods demonstrates a good performance of the present method.
KW - Free-surface Green function
KW - Gauss-Kronrod
KW - Higher-order boundary element method
KW - Long cylindrical structure
KW - Multipole expansion
KW - Numerical quadrature
KW - OpenMP parallelization
KW - Singularity elimination
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U2 - 10.3390/computation4030036
DO - 10.3390/computation4030036
M3 - Article
AN - SCOPUS:85048371669
SN - 2079-3197
VL - 4
JO - Computation
JF - Computation
IS - 3
M1 - 36
ER -