TPMS2STEP: error-controlled and C2 continuity-preserving translation of TPMS models to STEP files based on constrained-PIA

arXiv - CS - Computational Geometry Pub Date : 2024-05-13 DOI:arxiv-2405.07946

Yaonaiming Zhao, Qiang Zou, Guoyue Luo, Jiayu Wu, Sifan Chen

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Abstract

Triply periodic minimal surface (TPMS) is emerging as an important way of designing microstructures. However, there has been limited use of commercial CAD/CAM/CAE software packages for TPMS design and manufacturing. This is mainly because TPMS is consistently described in the functional representation (F-rep) format, while modern CAD/CAM/CAE tools are built upon the boundary representation (B-rep) format. One possible solution to this gap is translating TPMS to STEP, which is the standard data exchange format of CAD/CAM/CAE. Following this direction, this paper proposes a new translation method with error-controlling and $C^2$ continuity-preserving features. It is based on an approximation error-driven TPMS sampling algorithm and a constrained-PIA algorithm. The sampling algorithm controls the deviation between the original and translated models. With it, an error bound of $2\epsilon$ on the deviation can be ensured if two conditions called $\epsilon$-density and $\epsilon$-approximation are satisfied. The constrained-PIA algorithm enforces $C^2$ continuity constraints during TPMS approximation, and meanwhile attaining high efficiency. A theoretical convergence proof of this algorithm is also given. The effectiveness of the translation method has been demonstrated by a series of examples and comparisons.

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TPMS2STEP：基于约束-PIA，将 TPMS 模型翻译为 STEP 文件的误差控制和 C2 连续性保护功能

三周期最小表面（TPMS）正在成为设计微结构的一种重要方法。然而，商业 CAD/CAM/CAE 软件包在 TPMS 设计和制造方面的应用还很有限。这主要是因为 TPMS 始终采用功能表示（F-rep）格式进行描述，而现代 CAD/CAM/CAE 工具则基于边界表示（B-rep）格式。针对这一差距，一种可能的解决方案是将 TPMS 转换为 STEP，STEP 是 CAD/CAM/CAE 的标准数据交换格式。该方法基于近似误差驱动的 TPMS 采样算法和约束 PIA 算法。采样算法控制原始模型和翻译模型之间的偏差。有了它，如果满足两个条件（称为 $\epsilon$-density 和 $\epsilon$-approximation ），就能确保偏差的误差约束为 $2\epsilon$。约束 PIA 算法在 TPMS 近似过程中执行了$C^2$连续性约束，同时达到了很高的效率。同时给出了该算法的理论收敛性证明。通过一系列实例和比较，证明了翻译方法的有效性。

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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arXiv - CS - Computational Geometry

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