通过自适应边界优化解开所有六边形网格

IF 2.5 4区计算机科学 Q2 COMPUTER SCIENCE, SOFTWARE ENGINEERING

Graphical Models Pub Date : 2022-05-01 DOI:10.1016/j.gmod.2022.101136

Qing Huang, Wen-Xiang Zhang, Qi Wang, Ligang Liu, Xiao-Ming Fu

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引用次数: 2

摘要

我们提出了一种新的方法来解开和优化所有的六边形网格。该算法的核心是自适应边界优化过程，该过程显著提高了实际鲁棒性。给定具有许多倒六面体单元的全六边形网格，我们首先优化对输入边界具有较小近似误差的高质量四边形边界网格。由于边界约束限制了搜索无反转网格的优化空间，因此我们放松边界约束以生成无反转的全十六进制网格。我们开发了一种自适应边界松弛算法，以隐含地限制松弛边界和输入边界之间的形状差异，从而促进下一步工作。最后，开发了一种自适应边界差最小化方法，以有效地迫使第一步的松弛边界和优化边界之间的距离差接近零，同时避免倒置元素。我们在包含1004个全六边形网格的数据集上展示了我们的算法的有效性。与以前的方法相比，我们的方法具有更高的实用鲁棒性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

Untangling all-hex meshes via adaptive boundary optimization

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Untangling all-hex meshes via adaptive boundary optimization

We propose a novel method to untangle and optimize all-hex meshes. Central to this algorithm is an adaptive boundary optimization process that significantly improves practical robustness. Given an all-hex mesh with many inverted hexahedral elements, we first optimize a high-quality quad boundary mesh with a small approximation error to the input boundary. Since the boundary constraints limit the optimization space to search for the inversion-free meshes, we then relax the boundary constraints to generate an inversion-free all-hex mesh. We develop an adaptive boundary relaxation algorithm to implicitly restrict the shape difference between the relaxed and input boundaries, thereby facilitating the next step. Finally, an adaptive boundary difference minimization is developed to effectively and efficiently force the distance difference between the relaxed boundary and the optimized boundary of the first step to approach zero while avoiding inverted elements. We demonstrate the efficacy of our algorithm on a data set containing 1004 all-hex meshes. Compared to previous methods, our method achieves higher practical robustness.

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来源期刊

Graphical Models 工程技术-计算机：软件工程

CiteScore

3.60

自引率

5.90%

发文量

审稿时长

47 days

期刊介绍： Graphical Models is recognized internationally as a highly rated, top tier journal and is focused on the creation, geometric processing, animation, and visualization of graphical models and on their applications in engineering, science, culture, and entertainment. GMOD provides its readers with thoroughly reviewed and carefully selected papers that disseminate exciting innovations, that teach rigorous theoretical foundations, that propose robust and efficient solutions, or that describe ambitious systems or applications in a variety of topics. We invite papers in five categories: research (contributions of novel theoretical or practical approaches or solutions), survey (opinionated views of the state-of-the-art and challenges in a specific topic), system (the architecture and implementation details of an innovative architecture for a complete system that supports model/animation design, acquisition, analysis, visualization?), application (description of a novel application of know techniques and evaluation of its impact), or lecture (an elegant and inspiring perspective on previously published results that clarifies them and teaches them in a new way). GMOD offers its authors an accelerated review, feedback from experts in the field, immediate online publication of accepted papers, no restriction on color and length (when justified by the content) in the online version, and a broad promotion of published papers. A prestigious group of editors selected from among the premier international researchers in their fields oversees the review process.