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Lagrangian model of zooplankton dispersion:numerical schemes comparisons and parameter sensitivity tests 被引量:1

Lagrangian model of zooplankton dispersion:numerical schemes comparisons and parameter sensitivity tests
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摘要 This paper presents two comparisons or tests for a Lagrangian model of zooplankton dispersion:numerical schemes and time steps.Firstly,we compared three numerical schemes using idealized circulations.Results show that the precisions of the advanced Adams-Bashfold-Moulton(ABM) method and the Runge-Kutta(RK) method were in the same order and both were much higher than that of the Euler method.Furthermore,the advanced ABM method is more efficient than the RK method in computational memory requirements and time consumption.We therefore chose the advanced ABM method as the Lagrangian particle-tracking algorithm.Secondly,we performed a sensitivity test for time steps,using outputs of the hydrodynamic model,Symphonie.Results show that the time step choices depend on the fluid response time that is related to the spatial resolution of velocity fields.The method introduced by Oliveira et al.in 2002 is suitable for choosing time steps of Lagrangian particle-tracking models,at least when only considering advection. This paper presents two comparisons or tests for a Lagrangian model of zooplankton dispersion: numerical schemes and time steps. Firstly, we compared three numerical schemes using idealized circulations. Results show that the precisions of the advanced Adams-Bashfold-Moulton (ABM) method and the Runge-Kutta (RK) method were in the same order and both were much higher than that of the Euler method. Furthermore, the advanced ABM method is more efficient than the RK method in computational memory requirements and time consumption. We therefore chose the advanced ABM method as the Lagrangian particle-tracking algorithm. Secondly, we performed a sensitivity test for time steps, using outputs of the hydrodynamic model, Symphonie. Results show that the time step choices depend on the fluid response time that is related to the spatial resolution of velocity fields. The method introduced by Oliveira et al. in 2002 is suitable for choosing time steps of Lagrangian particle-tracking models, at least when only considering advection.
作者 丘仲锋 Andrea M.DOGLIOLI 何宜军 Francois CARLOTTI
机构地区 Key Laboratory of Ocean Circulation and Waves Laboratoire d'Ocanographie Physique et Biogochimie
出处 《Chinese Journal of Oceanology and Limnology》 SCIE CAS CSCD 2011年第2期438-445,共8页 中国海洋湖沼学报(英文版)
基金 Supported by the Project Lagrangian Zooplankton Computation and Experiment (CNRS Programme EC2CO) the National Natural Science Fundation of China (Nos. 40821004,40706059)
关键词 LAGRANGIAN numerical scheme time steps ZOOPLANKTON 拉格朗日模型 数值方法 浮游动物 敏感性试验 分散 时间消耗 粒子追踪 水动力模型
分类号 Q958.8 [生物学—动物学]
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参考文献18

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Chinese Journal of Oceanology and Limnology
2011年 第2期

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