P2M: A Fast Solver for Querying Distance from Point to Mesh Surface

Chen Zong, Jiacheng Xu, Jiantao Song, Shuangmin Chen, Shiqing Xin, Wenping Wang, Changhe Tu
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Abstract

Most of the existing point-to-mesh distance query solvers, such as Proximity Query Package (PQP), Embree and Fast Closest Point Query (FCPW), are based on bounding volume hierarchy (BVH). The hierarchical organizational structure enables one to eliminate the vast majority of triangles that do not help find the closest point. In this paper, we develop a totally different algorithmic paradigm, named P2M, to speed up point-to-mesh distance queries. Our original intention is to precompute a KD tree (KDT) of mesh vertices to approximately encode the geometry of a mesh surface containing vertices, edges and faces. However, it is very likely that the closest primitive to the query point is an edge e (resp., a face f), but the KDT reports a mesh vertex υ instead. We call υ an interceptor of e (resp., f). The main contribution of this paper is to invent a simple yet effective interception inspection rule and an efficient flooding interception inspection algorithm for quickly finding out all the interception pairs. Once the KDT and the interception table are precomputed, the query stage proceeds by first searching the KDT and then looking up the interception table to retrieve the closest geometric primitive. Statistics show that our query algorithm runs many times faster than the state-of-the-art solvers.
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P2M:查询点到网格表面距离的快速求解器
现有的点到网格距离查询求解器,如邻近查询包(PQP)、Embree和快速最近点查询(FCPW)等,大多是基于边界体积层次结构(BVH)。分层组织结构使人们能够消除绝大多数不能帮助找到最近点的三角形。在本文中,我们开发了一种完全不同的算法范式,称为P2M,以加快点到网格距离查询。我们的初衷是预先计算网格顶点的KD树(KDT),以近似编码包含顶点、边和面的网格表面的几何形状。然而,离查询点最近的原语很可能是边(rep)。,一个面f),但KDT报告一个网格顶点υ。我们称υ为e (resp)的拦截器。本文的主要贡献在于发明了一种简单有效的拦截检测规则和一种高效的泛洪拦截检测算法,可以快速找出所有拦截对。一旦预先计算了KDT和拦截表,查询阶段就会继续进行,首先搜索KDT,然后查找拦截表以检索最接近的几何原语。统计数据表明,我们的查询算法运行速度比最先进的求解器快很多倍。
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