Evaluation of numerical wave model for typhoon wave simulation in South China Sea

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英文篇名：Evaluation of numerical wave model for typhoon wave simulation in South China Sea 作者：Zhi-yuan ; Wu ; Chang-bo ; Jiang ; Bin ; Deng ; Jie ; Chen ; Yong-gang ; Cao ; Lian-jie ; Li 英文作者：Zhi-yuan Wu;Chang-bo Jiang;Bin Deng;Jie Chen;Yong-gang Cao;Lian-jie Li;School of Hydraulic Engineering, Changsha University of Science and Technology;Key Laboratory of Water-Sediment Sciences and Water Disaster Prevention of Hunan Province;School for Marine Science and Technology, University of Massachusetts Dartmouth;Key Laboratory of Technology for Safeguarding of Maritime Rights and Interests and Application,State Oceanic Administration; 英文关键词：Typhoon wave;;South China Sea;;SWAN model;;Numerical wave model;;Wave prediction and simulation 中文刊名：OWSE 英文刊名：水科学与水工程(英文版) 机构：School of Hydraulic Engineering, Changsha University of Science and Technology;Key Laboratory of Water-Sediment Sciences and Water Disaster Prevention of Hunan Province;School for Marine Science and Technology, University of Massachusetts Dartmouth;Key Laboratory of Technology for Safeguarding of Maritime Rights and Interests and Application,State Oceanic Administration; 出版日期：2018-07-15 出版单位：Water Science and Engineering 年：2018 期：v.11 基金：supported by the National Natural Science Foundation of China(Grants No.51239001,51179015,and 51509023);; the Open Research Foundation of the Key Laboratory of the Pearl River Estuarine Dynamics and Associated Process Regulation,the Ministry of Water Resources(Grant No.2018KJ03);; the Key Laboratory of Water-Sediment Sciences and Water Disaster Prevention of Hunan Province(Grant No.2017SS04);; the Key Laboratory of Technology for Safeguarding of Maritime Rights and Interests and Application,State Oceanic Administration(Grant No.SCS1606) 语种：英文; 页：OWSE201803007 页数：7 CN：03 ISSN：32-1785/TV 分类号：57-63

摘要

The simulating waves nearshore(SWAN) model has typically been designed for wave simulations in near-shore regions. In this study, the model's applicability to the simulation of typhoon waves in the South China Sea(SCS) was evaluated. A blended wind field, consisting of an interior domain based on Fujita's model and an exterior domain based on Takahashi's model, was used as the driving wind field. The waves driven by Typhoon Kai-tak over the SCS that occurred in 2012 were selected for the numerical simulation research. Sensitivity analyses of time step, grid resolution, and angle resolution were performed in order to obtain optimal model settings. Through sensitivity analyses, it can be found that the time step has a large influence on the results, while grid resolution and angle resolution have a little effect on the results.
        The simulating waves nearshore(SWAN) model has typically been designed for wave simulations in near-shore regions. In this study, the model's applicability to the simulation of typhoon waves in the South China Sea(SCS) was evaluated. A blended wind field, consisting of an interior domain based on Fujita's model and an exterior domain based on Takahashi's model, was used as the driving wind field. The waves driven by Typhoon Kai-tak over the SCS that occurred in 2012 were selected for the numerical simulation research. Sensitivity analyses of time step, grid resolution, and angle resolution were performed in order to obtain optimal model settings. Through sensitivity analyses, it can be found that the time step has a large influence on the results, while grid resolution and angle resolution have a little effect on the results.

引文

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