Fitting subdivision surfaces to unorganized point data using SDM

12th Pacific Conference on Computer Graphics and Applications, 2004. PG 2004. Proceedings. Pub Date : 2004-10-06 DOI:10.1109/PCCGA.2004.1348330

K. D. Cheng, Wenping Wang, Hong Qin, Kwan-Yee Kenneth Wong, Huaiping Yang, Yang Liu

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引用次数: 52

Abstract

We study the reconstruction of smooth surfaces from point clouds. We use a new squared distance error term in optimization to fit a subdivision surface to a set of unorganized points, which defines a closed target surface of arbitrary topology. The resulting method is based on the framework of squared distance minimization (SDM) proposed by Pottmann et al. Specifically, with an initial subdivision surface having a coarse control mesh as input, we adjust the control points by optimizing an objective function through iterative minimization of a quadratic approximant of the squared distance function of the target shape. Our experiments show that the new method (SDM) converges much faster than the commonly used optimization method using the point distance error function, which is known to have only linear convergence. This observation is further supported by our recent result that SDM can be derived from the Newton method with necessary modifications to make the Hessian positive definite and the fact that the Newton method has quadratic convergence.

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用SDM方法拟合无组织点数据的细分曲面

我们研究了从点云重建光滑表面。我们在优化中使用了一个新的距离平方误差项来拟合一个细分曲面到一组无组织的点上，从而定义了一个任意拓扑的封闭目标曲面。该方法基于Pottmann等人提出的平方距离最小化(SDM)框架。具体而言，以粗糙控制网格为输入的初始细分曲面，通过迭代最小化目标形状距离平方函数的二次近似来优化目标函数，从而调整控制点。我们的实验表明，新方法(SDM)的收敛速度远远快于常用的优化方法，使用点距离误差函数，已知只有线性收敛。我们最近的结果进一步支持了这一观察，即SDM可以通过牛顿方法进行必要的修正而得到，使Hessian正定，并且牛顿方法具有二次收敛性。

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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12th Pacific Conference on Computer Graphics and Applications, 2004. PG 2004. Proceedings.

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