AM  Vol.5 No.21 , December 2014
Energy-Minimizing Curve Fitting for High-Order Surface Mesh Generation
ABSTRACT
We investigate different techniques for fitting Bézier curves to surfaces in context of high-order curvilinear mesh generation. Starting from distance-based least-squares fitting we develop an incremental algorithm, which incorporates approximations of stretch and bending energy. In the process, the algorithm reduces the energy weight in favor of accuracy, leading to an optimized set of sampling points. This energy-minimizing fitting strategy is applied to analytically defined as well as triangulated surfaces. The results confirm that the proposed method straightens and shortens the curves efficiently. Moreover the method preserves the accuracy and convergence behavior of distance-based fitting. Preliminary application to surface mesh generation shows a remarkable improvement of patch quality in high curvature regions.

Cite this paper
Bock, K. and Stiller, J. (2014) Energy-Minimizing Curve Fitting for High-Order Surface Mesh Generation. Applied Mathematics, 5, 3318-3327. doi: 10.4236/am.2014.521309.
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