计算机科学
稳健性(进化)
数学优化
约束优化
最优化问题
歧管(流体力学)
拓扑优化
拓扑(电路)
数学
热力学
基因
工程类
有限元法
组合数学
物理
化学
生物化学
机械工程
作者
Bo-Yi Hu,Chunyang Ye,Jian‐Ping Su,Ligang Liu
标识
DOI:10.1109/tvcg.2021.3112896
摘要
Many geometric optimization problems contain manifold constraints that restrict the optimized vertices on some specified manifold surface. The constraints are highly nonlinear and non-convex, therefore existing methods usually suffer from a breach of condition or low optimization quality. In this article, we present a novel divide-and-conquer methodology for manifold-constrained geometric optimization problems. Central to our methodology is to use local parameterizations to decouple the optimization with hard constraints, which transforms nonlinear constraints into linear constraints. We decompose the input mesh into a set of developable or nearly-developable overlapping patches with disc topology, then flatten each patch into the planar domain with very low isometric distortion, optimize vertices with linear constraints and recover the patch. Finally, we project it onto the constrained manifold surface. We demonstrate the applicability and robustness of our methodology through a variety of geometric optimization tasks. Experimental results show that our method performs much better than existing methods.
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