Collaborative Research: Tuning-Free Adaptive Multilevel Discontinuous Galerkin Methods for Maxwell's Equations

合作研究：麦克斯韦方程组的免调优自适应多级间断伽辽金方法

• 批准号: 0810176
• 负责人: Ronald Hoppe
• 金额: $ 17.72万
• 依托单位: University of Houston
• 依托单位国家: 美国
• 项目类别: Continuing Grant
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-07-15 至 2012-06-30
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=0810176&HistoricalAwards=false
• 关键词: Collaborative; Research; Tuning; Free; Adaptive

The investigator and colleagues are formulating, analyzing, and implementing adaptive multilevel Discontinuous Galerkin methods for coupled interior/exterior domain problems associated with the time-harmonic Maxwell equations. These advanced finite element methods are being realized as multilevel techniques on the basis of an adaptively generated hierarchy of triangulations of the computational domain. The research team is focusing on three central issues related to the basic steps `SOLVE', `ESTIMATE', `MARK', and `REFINE' of the adaptive loop. First, the smoothing process within the multilevel solver is performed only on the newly refined part of the triangulation obtained by a residual type a posteriori error estimator. Second, the a posteriori error analysis, which additionally has to take into account the effect of such local smoothing, aims to provide conditions guaranteeing a reduction of the global discretization error at each refinement step. Third, the selection of elements, faces and edges of the triangulation for refinement are based on a bulk criterion with an automatic (`tuning free') choice of the parameters controlling the amount of refinement in order to achieve optimal performance of the overall algorithm. Finally, the team is developing criteria to choose the parameters of artificial radiation boundary conditions automatically, such that no tuning on behalf of the user is required there as well. Simulation of electromagnetic phenomena is a particularly challenging problem in computational mathematics. The investigator and colleagues are establishing a profound theoretical foundation for adaptive multilevel discontinuous Galerkin methods in electromagnetic field computations. They are developing a reliable algorithmic tool, of optimal computational complexity, that can be used for the numerical solution of challenging real-life problems in electrical engineering applications. The methods developed in this project have numerous technical and scientific applications, for instance semiconductor simulation or particle accelerator design. The results will be disseminated through publication of algorithms and results and reference computer codes being developed during this project will be made available to practitioners.

研究人员和同事们正在制定，分析和实施自适应多级不连续Galerkin方法耦合的内部/外部域与时间谐波麦克斯韦方程组的问题。这些先进的有限元方法被实现为多级技术的基础上，自适应生成的层次结构的计算域的三角剖分。该研究团队专注于与自适应循环的基本步骤“解决”，“估计”，“标记”和“细化”相关的三个中心问题。首先，在多级求解器内的平滑处理仅在由残差型后验误差估计器获得的三角测量的新细化部分上执行。其次，后验误差分析还必须考虑这种局部平滑的影响，旨在提供保证在每个细化步骤中减少全局离散误差的条件。第三，用于细化的三角测量的元素、面和边的选择是基于具有控制细化量的参数的自动（“自由调谐”）选择的批量标准，以便实现整个算法的最佳性能。最后，该团队正在开发自动选择人工辐射边界条件参数的标准，因此也不需要代表用户进行调整。电磁现象的模拟是计算数学中一个特别具有挑战性的问题。研究者和同事们正在为电磁场计算中的自适应多层间断Galerkin方法建立一个深刻的理论基础。他们正在开发一种可靠的算法工具，具有最佳的计算复杂度，可用于电气工程应用中具有挑战性的现实问题的数值解决方案。该项目开发的方法具有许多技术和科学应用，例如半导体模拟或粒子加速器设计。将通过公布算法和结果来传播结果，并将向从业人员提供在本项目期间开发的参考计算机代码。