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Steady-State Configuration and Tension Calculations of Marine Cables Under Complex Currents via Separated Particle Swarm Optimization?

Steady-State Configuration and Tension Calculations of Marine Cables Under Complex Currents via Separated Particle Swarm Optimization?
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摘要 Under complex currents, the motion governing equations of marine cables are complex and nonlinear, and the calculations of cable configuration and tension become difficult compared with those under the uniform or simple currents. To obtain the numerical results, the usual Newton-Raphson iteration is often adopted, but its stability depends on the initial guessed solution to the governing equations. To improve the stability of numerical calculation, this paper proposed separated the particle swarm optimization, in which the variables are separated into several groups, and the dimension of search space is reduced to facilitate the particle swarm optimization. Via the separated particle swarm optimization, these governing nonlinear equations can be solved successfully with any initial solution, and the process of numerical calculation is very stable. For the calculations of cable configuration and tension of marine cables under complex currents, the proposed separated swarm particle optimization is more effective than the other particle swarm optimizations. Under complex currents, the motion governing equations of marine cables are complex and nonlinear, and the calculations of cable configuration and tension become difficult compared with those under the uniform or simple currents. To obtain the numerical results, the usual Newton-Raphson iteration is often adopted, but its stability depends on the initial guessed solution to the governing equations. To improve the stability of numerical calculation, this paper proposed separated the particle swarm optimization, in which the variables are separated into several groups, and the dimension of search space is reduced to facilitate the particle swarm optimization. Via the separated particle swarm optimization, these governing nonlinear equations can be solved successfully with any initial solution, and the process of numerical calculation is very stable. For the calculations of cable configuration and tension of marine cables under complex currents, the proposed separated swarm particle optimization is more effective than the other particle swarm optimizations.
作者 徐雪松
机构地区 State Key Laboratory of Ocean Engineering
出处 《China Ocean Engineering》 SCIE EI CSCD 2014年第6期815-828,共14页 中国海洋工程(英文版)
基金 supported by the National Natural Science Foundation of China(Grant Nos.51009092 and 51279107) the Scientific Research Foundation of State Education Ministry for the Returned Overseas Chinese Scholars
关键词 nonlinear equations particle swarm optimization marine cables towed marine systems nonlinear equations particle swarm optimization marine cables towed marine systems
分类号 U665.1 [交通运输工程—船舶及航道工程]
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参考文献4

  • 1P.W. Jansen,R.E. Perez.Constrained structural design optimization via a parallel augmented Lagrangian particle swarm optimization approach[J].Computers and Structures.2010(13)
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二级参考文献15

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共引文献9

China Ocean Engineering
2014年 第6期

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