Numerical Analysis for Neumann Optimal Control Problems on Convex Polyhedral Domains

Johannes Pfefferer, Boris Vexler
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Abstract

This paper is concerned with finite element error estimates for Neumann boundary control problems posed on convex and polyhedral domains. Different discretization concepts are considered and for each optimal discretization error estimates are established. In particular, for a full discretization with piecewise linear and globally continuous functions for the control and standard linear finite elements for the state optimal convergence rates for the controls are proven which solely depend on the largest interior edge angle. To be more precise, below the critical edge angle of $2\pi/3$, a convergence rate of two (times a log-factor) can be achieved for the discrete controls in the $L^2$-norm on the boundary. For larger interior edge angles the convergence rates are reduced depending on their size, which is due the impact of singular (domain dependent) terms in the solution. The results are comparable to those for the two dimensional case. However, new techniques in this context are used to prove the estimates on the boundary which also extend to the two dimensional case. Moreover, it is shown that the discrete states converge with a rate of two in the $L^2$-norm in the domain independent of the interior edge angles, i.e. for any convex and polyhedral domain. It is remarkable that this not only holds for a full discretization using piecewise linear and globally continuous functions for the control, but also for a full discretization using piecewise constant functions for the control, where the discrete controls only converge with a rate of one in the $L^2$-norm on the boundary at best. At the end, the theoretical results are confirmed by several numerical experiments.
凸多面体域上 Neumann 优化控制问题的数值分析
本文关注在凸域和多面体域上提出的 Neumann 边界控制问题的有限元误差估计。本文考虑了不同的离散化概念,并为每种最佳离散化建立了误差估计。特别是,对于使用片断线性和全局连续函数进行控制的完全离散化,以及使用标准线性有限元进行状态离散化,证明了控制的最优收敛率仅取决于最大内边缘角。更精确地说,在临界边缘角 2\pi/3$ 以下,离散控制在边界上的 L^2$ 正则收敛率可达 2(对数因子的 2 倍)。对于较大的内部边缘角,收敛率会根据其大小而降低,这是由于解中奇异(与域相关)项的影响。这些结果与二维情况下的结果相当。然而,在这种情况下,使用了新技术来证明边界上的估计值,这些估计值也扩展到了二维情况。此外,研究还表明,离散状态在与内部边角无关的域中,即在任何凸多面体域中,以 $L^2$ 规范的 2 的速率收敛。值得注意的是,这不仅适用于使用片断线性和全局连续函数进行控制的完全离散化,也适用于使用片断常数函数进行控制的完全离散化,在这种情况下,离散控制在边界上最多只能以 $L^2$-norm 的一收敛率收敛。最后,几个数值实验证实了理论结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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