用于沿海洪水评估的非连续伽勒金浅水操作模型

IF 3.1 3区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
A.G. Filippini , L. Arpaia , V. Perrier , R. Pedreros , P. Bonneton , D. Lannes , F. Marche , S. De Brye , S. Delmas , S. Lecacheux , F. Boulahya , M. Ricchiuto
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引用次数: 0

摘要

用于沿岸洪水风险评估的水动力模型是一个非常重要的课题。许多用于这一目的的操作工具所使用的数值技术和实施范式,在面对现代分辨率和性能要求时,已经达到了极限。在这项工作中,我们介绍了一种新的沿海灾害预测实用工具,该工具目前被法国地质调查局 (BRGM)用来在国际和法国领土上开展洪水灾害暴露研究和沿海风险预防计划。该模型名为 UHAINA(巴斯克语中的波浪),是基于非线性浅水方程的任意高阶非连续 Galerkin 离散法,在非结构化三角形网格上采用 SSP Runge-Kutta 时间步进。它建立在有限元库 AeroSol 的基础上,该库提供了现代 C++ 软件架构和高可扩展性,使其适用于 HPC 应用。论文详细介绍了该模型的数学和数值框架,重点介绍了两个关键要素:(i) 部分干燥单元中求解的实用 P0 处理,可在任何多项式阶数下有效保证平衡性、正性和质量守恒;(ii) 基于物理耗散的人工粘性方法,可为非光滑求解提供非线性稳定性。在学术基准上进行了一系列数值验证,以突出这些方法的效率。最后,将 UHAINA 应用于实际运行案例的研究,结果令人非常满意。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
An operational discontinuous Galerkin shallow water model for coastal flood assessment
Hydrodynamic modeling for coastal flooding risk assessment is a highly relevant topic. Many operational tools available for this purpose use numerical techniques and implementation paradigms that reach their limits when confronted with modern requirements in terms of resolution and performances. In this work, we present a novel operational tool for coastal hazards predictions, currently employed by the BRGM agency (the French Geological Survey) to carry out its flooding hazard exposure studies and coastal risk prevention plans on International and French territories. The model, called UHAINA (wave in the Basque language), is based on an arbitrary high-order discontinuous Galerkin discretization of the nonlinear shallow water equations with SSP Runge–Kutta time stepping on unstructured triangular grids. It is built upon the finite element library AeroSol, which provides a modern C++ software architecture and high scalability, making it suitable for HPC applications. The paper provides a detailed development of the mathematical and numerical framework of the model, focusing on two key-ingredients : (i) a pragmatic P0 treatment of the solution in partially dry cells which guarantees efficiently well-balancedness, positivity and mass conservation at any polynomial order; (ii) an artificial viscosity method based on the physical dissipation of the system of equations providing nonlinear stability for non-smooth solutions. A set of numerical validations on academic benchmarks is performed to highlight the efficiency of these approaches. Finally, UHAINA is applied on a real operational case of study, demonstrating very satisfactory results.
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来源期刊
Ocean Modelling
Ocean Modelling 地学-海洋学
CiteScore
5.50
自引率
9.40%
发文量
86
审稿时长
19.6 weeks
期刊介绍: The main objective of Ocean Modelling is to provide rapid communication between those interested in ocean modelling, whether through direct observation, or through analytical, numerical or laboratory models, and including interactions between physical and biogeochemical or biological phenomena. Because of the intimate links between ocean and atmosphere, involvement of scientists interested in influences of either medium on the other is welcome. The journal has a wide scope and includes ocean-atmosphere interaction in various forms as well as pure ocean results. In addition to primary peer-reviewed papers, the journal provides review papers, preliminary communications, and discussions.
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