A Lagrangian shape and topology optimization framework based on semi-discrete optimal transport

Charles Dapogny, Bruno Levy, Edouard Oudet
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Abstract

This article revolves around shape and topology optimization, in the applicative context where the objective and constraint functionals depend on the solution to a physical boundary value problem posed on the optimized domain. We introduce a novel framework based on modern concepts from computational geometry, optimal transport and numerical analysis. Its pivotal feature is a representation of the optimized shape by the cells of an adapted version of a Laguerre diagram. Although such objects are originally described by a collection of seed points and weights, recent results from optimal transport theory suggest a more intuitive parametrization in terms of the seed points and measures of the associated cells. The polygonal mesh of the shape induced by this diagram serves as support for the deployment of the Virtual Element Method for the numerical solution of the physical boundary value problem at play and the calculation of the objective and constraint functionals. The sensitivities of the latter are derived next; at first, we calculate their derivatives with respect to the positions of the vertices of the Laguerre diagram by shape calculus techniques; a suitable adjoint methodology is then developed to express them in terms of the seed points and cell measures of the diagram. The evolution of the shape is realized by first updating the design variables according to these sensitivities and then reconstructing the diagram with efficient algorithms from computational geometry. Our shape optimization strategy is versatile: it can be applied to a wide gammut of physical situations. It is Lagrangian by essence, and it thereby benefits from all the assets of a consistently meshed representation of the shape. Yet, it naturally handles dramatic motions, including topological changes, in a very robust fashion. These features, among others, are illustrated by a series of 2d numerical examples.
基于半离散优化传输的拉格朗日形状和拓扑优化框架
本文围绕形状和拓扑优化展开论述,其应用背景是目标函数和约束函数取决于在优化域上提出的物理边界值问题的解。我们引入了一个基于计算几何、最优传输和数值分析等现代概念的新框架。其关键特征是通过拉盖尔图的改编单元来表示优化形状。虽然这种对象最初是通过种子点和权重的集合来描述的,但最优传输理论的最新结果表明,用相关单元格的种子点和度量来进行参数化更为直观。由该图引起的多边形网格支持采用虚拟元素法对物理边界值问题进行数值求解,并计算目标函数和约束函数。首先,我们通过形状微积分技术计算它们相对于拉盖尔图顶点位置的导数;然后开发了一种合适的邻接方法,用图中的种子点和单元度量来表示它们。首先根据这些敏感性更新设计变量,然后利用计算几何的高效算法重新构建图表,从而实现形状的演变。我们的形状优化策略用途广泛:可适用于各种物理情况。从本质上讲,它是拉格朗日式的,因此可以从形状的一致性网格表示的所有优点中获益。然而,它能以非常稳健的方式自然地处理剧烈运动,包括拓扑变化。这些特点将通过一系列二维数值示例加以说明。
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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