Robust and GPU-friendly Isotropic Meshing Based on Narrow-banded Euclidean Distance Transformation

Proceedings. Pacific Conference on Computer Graphics and Applications Pub Date : 2015-01-01 DOI:10.2312/PG.20151273

Yuen-Shan Leung, Xiaoning Wang, Ying He, Yong-Jin Liu, Charlie C. L. Wang

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引用次数: 3

Abstract

In this paper, we propose a simple-yet-effective method for isotropic meshing via Euclidean distance transformation based Centroidal Voronoi Tessellation (CVT). The proposed approach aims at improving the performance as well as robustness of computing CVT on curved domains while simultaneously maintaining the high-quality of the output meshes. In contrast to the conventional extrinsic methods which compute CVTs in the entire volume bounded by the input model, our idea is to restrict the computation in a 3D shell space with user-controlled thickness. Taking the voxels which contain the surface samples as the sites, we compute the exact Euclidean distance transform on the GPU. Our algorithm is fully parallel and memory-efficient, and it can construct the shell space with resolution up to 20483 at interactive speed. Since the shell space is able to bridge holes and gaps up to a certain tolerance, and tolerate non-manifold edges and degenerate triangles, our algorithm works well on models with such defects, whereas the conventional remeshing methods often fail.

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基于窄带欧氏距离变换的鲁棒且gpu友好的各向同性网格划分

本文提出了一种简单而有效的基于欧氏距离变换的质心Voronoi镶嵌(CVT)的各向同性网格划分方法。该方法旨在提高CVT在曲线域上的性能和鲁棒性，同时保持输出网格的质量。与传统的外在方法在输入模型限定的整个体积内计算cvt不同，我们的想法是将计算限制在用户控制厚度的三维壳空间中。以包含表面样本的体素为点，在GPU上计算精确的欧氏距离变换。该算法具有完全并行性和高内存效率，可在交互速度下构造分辨率高达20483的壳空间。由于壳空间能够在一定的公差范围内桥接孔和间隙，并且能够容忍非流形边和退化三角形，因此我们的算法在具有此类缺陷的模型上效果很好，而传统的重网格方法往往失败。

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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Proceedings. Pacific Conference on Computer Graphics and Applications

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