Neural Level Set Topology Optimization Using Unfitted Finite Elements

IF 2.7 3区工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY

International Journal for Numerical Methods in Engineering Pub Date : 2025-03-19 DOI:10.1002/nme.70004

Connor N. Mallon, Aaron W. Thornton, Matthew R. Hill, Santiago Badia

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Abstract

To facilitate the widespread adoption of automated engineering design techniques, existing methods must become more efficient and generalizable. In the field of topology optimization, this requires the coupling of modern optimization methods with solvers capable of handling arbitrary problems. In this work, a topology optimization method for general multiphysics problems is presented. We leverage a convolutional neural parameterization of a level set for a description of the geometry and use this in an unfitted finite element method that is differentiable with respect to the level set everywhere in the domain. We construct the parameter to objective map in such a way that the gradient can be computed entirely by automatic differentiation at roughly the cost of an objective function evaluation. Without handcrafted initializations, the method produces regular topologies close to the optimal solution for standard benchmark problems whilst maintaining the ability to solve a more general class of problems than standard methods, for example, interface-coupled multiphysics.

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基于非拟合有限元的神经网络水平集拓扑优化

为了促进自动化工程设计技术的广泛采用，现有的方法必须变得更有效和可推广。在拓扑优化领域，这需要将现代优化方法与能够处理任意问题的求解器相结合。本文提出了一种求解一般多物理场问题的拓扑优化方法。我们利用水平集的卷积神经参数化来描述几何形状，并将其用于非拟合有限元方法中，该方法对域内任何地方的水平集都是可微的。我们构造了参数到目标映射的方法，使得梯度完全可以通过自动微分来计算，而目标函数的计算代价大致为一次。无需手工初始化，该方法生成的规则拓扑接近标准基准问题的最佳解决方案，同时保持了解决比标准方法（例如接口耦合多物理场）更一般的一类问题的能力。

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来源期刊

International Journal for Numerical Methods in Engineering 工程技术-工程：综合

CiteScore

5.70

自引率

6.90%

发文量

276

审稿时长

5.3 months

期刊介绍： The International Journal for Numerical Methods in Engineering publishes original papers describing significant, novel developments in numerical methods that are applicable to engineering problems. The Journal is known for welcoming contributions in a wide range of areas in computational engineering, including computational issues in model reduction, uncertainty quantification, verification and validation, inverse analysis and stochastic methods, optimisation, element technology, solution techniques and parallel computing, damage and fracture, mechanics at micro and nano-scales, low-speed fluid dynamics, fluid-structure interaction, electromagnetics, coupled diffusion phenomena, and error estimation and mesh generation. It is emphasized that this is by no means an exhaustive list, and particularly papers on multi-scale, multi-physics or multi-disciplinary problems, and on new, emerging topics are welcome.