IF-TONIR:基于隐式神经网络表征的无迭代拓扑优化

IF 3 3区 计算机科学 Q2 COMPUTER SCIENCE, SOFTWARE ENGINEERING Computer-Aided Design Pub Date : 2023-11-04 DOI:10.1016/j.cad.2023.103639
Jiangbei Hu , Ying He , Baixin Xu , Shengfa Wang , Na Lei , Zhongxuan Luo
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引用次数: 0

摘要

拓扑优化是机械工程领域中具有重要意义的研究课题,其目的是在遵守特定约束条件的前提下,对结构进行设计和优化,使其达到预期的性能。然而,其较高的计算复杂度和迭代优化过程严重影响了效率,给其实际应用带来了很大的障碍。为了应对这一挑战,最近的研究致力于利用神经网络和深度学习的无迭代拓扑优化方法的进步,旨在通过优化问题配置直接预测最优结构。在本文中,我们提出了IF-TONIR,一种利用隐式神经表示的数据驱动拓扑优化方法。我们的方法使用带符号距离字段来表示结构,提供紧凑和平滑的表示,有效地消除了基于密度的方法中常见的棋盘现象。IF-TONIR利用条件变分自编码器,它使用基于cnn的编码器和基于mlp的解码器来学习和重建最优结构。我们使用从物理信息中提取的特征作为条件来指导解码器生成符合特定设计域形状和边界条件的最佳结构。此外,我们提出了基于持久同调的拓扑损失集成来训练模型。这种损失函数有效地惩罚了重建输出中存在的结构断裂,从而提高了生成结构的整体物理可靠性。各种实验表明,基于隐式表示的无迭代拓扑优化方法可以准确识别高应变能区域,并生成低柔度的连续结构。该方法还具有在任何期望分辨率下输出最优结构的理论能力。我们的代码和数据集可在https://github.com/jbHu67/IF-TONIR.git上获得
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IF-TONIR: Iteration-free Topology Optimization based on Implicit Neural Representations

Topology optimization holds great significance as a research topic in the field of mechanical engineering, aiming to design and optimize structures to achieve desired performance while adhering to specific constraints. However, its high computational complexity and iterative optimization process severely impact the efficiency, which presents substantial obstacles to its practical applications. To tackle this challenge, recent research is dedicated to the advancement of iteration-free topology optimization methods that leverage neural networks and deep learning, aiming to directly predict optimal structures through optimization problem configurations. In this paper, we propose IF-TONIR, a novel data-driven topology optimization method that utilizes implicit neural representations. Our approach employs signed distance fields to represent structures, offering compact and smooth representations that effectively eliminate the checkerboard phenomenon commonly observed in density-based methods. IF-TONIR leverages Conditional Variational Autoencoders, which use a CNN-based encoder and a MLP-based decoder to learn and reconstruct optimal structures. We employ the features extracted from physical information as conditions to guide the decoder in generating optimal structures that adhere to specific design domain shapes and boundary conditions. Furthermore, we propose the integration of a topological loss based on persistent homology to train the model. This loss function effectively penalizes the existence of structural disconnections in the reconstructed output, thereby enhancing the overall physical reliability of the generated structures. Various experiments have demonstrated that our iteration-free topology optimization method based on implicit representations can accurately identify regions of high strain energy and generate continuous structures with low compliance. The methods also holds the theoretical capability of outputting optimal structures at any desired resolution. Our code and dataset are available on https://github.com/jbHu67/IF-TONIR.git

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来源期刊
Computer-Aided Design
Computer-Aided Design 工程技术-计算机:软件工程
CiteScore
5.50
自引率
4.70%
发文量
117
审稿时长
4.2 months
期刊介绍: Computer-Aided Design is a leading international journal that provides academia and industry with key papers on research and developments in the application of computers to design. Computer-Aided Design invites papers reporting new research, as well as novel or particularly significant applications, within a wide range of topics, spanning all stages of design process from concept creation to manufacture and beyond.
期刊最新文献
Reconstruction and Preservation of Feature Curves in 3D Point Cloud Processing Editorial Board Texture-Driven Adaptive Mesh Refinement with Application to 3D Relief IF-TONIR: Iteration-free Topology Optimization based on Implicit Neural Representations Interface-Based Search and Automatic Reassembly of CAD Models for Database Expansion and Model Reuse
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