Alternating size field optimizing and parameterization domain CAD model remeshing

• Published in: Computer aided geometric design Vol. 111; p. 102294
• Main Authors: Wang, Shiyi, Yang, Bochun, Bao, Hujun, Huang, Jin
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.06.2024
• Subjects: Geometric modeling; Remeshing; Triangulation; Geometric modeling; Triangulation; Remeshing
• ISSN: 0167-8396; 1879-2332
• DOI: 10.1016/j.cagd.2024.102294

Tessellating CAD models into triangular meshes is a long-lasting problem. Size field is widely used to accommodate varieties of requirements in remeshing, and it is usually discretized and optimized on a prescribed background mesh and kept constant in the subsequent remeshing procedure. Instead, we propose optimizing the size field on the current mesh, then using it as guidance to generate the next mesh. This simple strategy eliminates the need of building a proper background mesh and greatly simplifies the size field query. For better quality and convergence, we also propose a geodesic distance based initialization and adaptive re-weighting strategy in size field optimization. Similar to existing methods, we also view the remeshing of a CAD model as the remeshing of its parameterization domain, which guarantees that all the vertices lie exactly on the CAD surfaces and eliminates the need for costly and error-prone projection operations. However, for vertex smoothing which is important for mesh quality, we carefully optimize the vertex's location in the parameterization domain for the optimal Delaunay triangulation condition, along with a high-order cubature scheme for better accuracy. Experiments show that our method is fast, accurate and controllable. Compared with state-of-the-art methods, our approach is fast and usually generates meshes with smaller Hausdorff error, larger minimal angle with a comparable number of triangles. •A novel framework for alternative size field optimization and meshing.•Size field optimization with a penalty, initialization and re-weighting strategies.•Parameterization domain vertex smoothing with an accurate ODT condition on the surface.