基于Morse-Smale拓扑特征的文物碎片拼接算法

袁洁; 周明全; 耿国华; 张雨禾

doi:10.16383/j.aas.2017.c160778

基于Morse-Smale拓扑特征的文物碎片拼接算法

doi: 10.16383/j.aas.2017.c160778

袁洁^1,,
周明全^2, ,,
耿国华^1,,
张雨禾^1,

1.
西北大学信息科学与技术学院西安 710127
2.
北京师范大学信息科学与技术学院北京 100875

基金项目:

国家自然科学基金 61673319

陕西省产业创新链项目：秦汉都城虚拟修复建模及其增强现实展示应用示范工程 2016TZC-G-3-5

国家自然科学基金 61373117

高等学校博士学科点专项科研基金 20136101110019

详细信息

作者简介:
袁洁  西北大学信息科学与技术学院硕士研究生.2015年获得西北大学计算机科学与技术学士学位.主要研究方向为图形几何处理, 可视化技术.E-mail:yuanjie4920@163.com

耿国华  西北大学信息科学与技术学院教授.主要研究方向为计算机图形图像处理, 可视化技术.E-mail:ghgeng@nwu.edu.cn

张雨禾  西北大学信息科学与技术学院博士研究生.2012年获得西北大学计算机科学与技术学士学位.主要研究方向为图形几何处理, 可视化技术及3D打印技术.E-mail:zhangyuhe0601@126.com

通讯作者:
周明全北京师范大学信息科学与技术学院教授.主要研究方向为虚拟现实与可视化技术, 智能信息处理, 数据库与知识库, 图形图像处理.本文通信作者.E-mail:mqzhou@bnu.edu.cn

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出版历程
- 收稿日期: 2016-11-21
- 录用日期: 2017-05-22
- 刊出日期: 2018-08-20

Automatic Reassembly of Fractured Fragments Using Morse Topological Features

1.
School of Information Science and Technology, Northwest University, Xi'an 710127
2.
College of Information Science and Technology, Beijing Normal University, Beijing 100875

Funds:

National Natural Science Foundation of China 61673319

Qinhan Metropolis Metropolitan Virtual Repair Modeling and Its Augmented Reality Display Application Demonstration Project 2016TZC-G-3-5

National Natural Science Foundation of China 61373117

Special Research Fund for the Doctoral Program of Higher Education 20136101110019

More Information

Author Bio:
Master student at the School of Information Science and Technology, Northwest University. She received her bachelor degree from Northwest University in 2015. Her research interest covers graphics geometry processing, and visualization technology

Ph. D. Professor at the School of Information Science and Technology, Northwest University. Her research interest covers graphics image processing and visualization technology

Ph. D. candidate at the School of Information Science and Technology, Northwest University. She received her bachelor degree from Northwest University in 2012. Her research interest covers graphics geometry processing, visualization technology, and 3D printing technology

Corresponding author: ZHOU Ming-Quan Professor at the School of Information Science and Technology, Beijing Normal University. His research interest covers virtual reality and visualization technology, intelligent information processing, database and knowledge base, graphics and image processing. Corresponding author of this paper

摘要

摘要: 针对计算机辅助文物虚拟复原中由于破损文物断裂部位边缘受损而引起的轮廓线不能充分表示断裂面几何特征的问题，提出了一种基于断裂面拓扑特征的破碎文物自动拼接算法.首先，定义碎片模型顶点显著度指标函数，提取断裂面特征点，依据Morse-Smale复形理论构建并简化断裂面的几何拓扑图；然后，通过定义基准点与0值面，从而计算目标点的对应高度差值，将拓扑图中四边形曲面构造成为能完整表示断裂面几何特征的特征描述符，并根据凹凸互补性计算初始特征四边形匹配集的误差，筛选出最优匹配集；最后，采用四元组方法计算旋转、平移矩阵，利用穷举搜索法实现碎片的精确拼接.实验结果表明，该方法针对断裂部位边缘受损的破碎文物模型可获得较满意的拼接效果.
- Morse-Smale复形 /
- 刚体变换 /
- 特征描述符 /
- 四元数 /
- 穷举搜索
Abstract: In order to address the problem that the traditional break-curves methods fail to reassemble fractured fragments with incompleteness in contours, a novel automatic reassembly method is proposed using topological feature of fracture surfaces in this paper. First, the Morse-Smale complex on the fractured surfaces of fragments is constructed with curvedness as the indicator function. Then, the tangent plane is calculated through height comparison among key points and the quadrilateral descriptor is obtained by computing height difference. After that, according to the correlation between adjacent regions, optimal quadrilateral descriptors are selected. The rigid transformation matrices that maximize the contact area between surfaces are obtained by quaternion method, such that two fragments can be precisely aligned based on optimal rigid motion through exhaustive search. Experimental results show that satisfactory performance can be achieved by several uses of the algorithm on the fragments of the terracotta warriors.
- Morse-Smale complex /
- rigid transformation /
- quadrilateral descriptor /
- quaternion method /
- exhaustive search
注释:

1) 本文责任编委刘成林

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图 1 本文方法步骤

Fig. 1 Procedures for the method proposed in the paper

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图 2 顶点邻域关系图

Fig. 2 Diagrams of vertex neighborhoods

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图 3 环状和孤立临界点

Fig. 3 Diagrams of cyclic and solitary critical points

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图 4 路径点位选择

Fig. 4 Paths selected by points

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图 5 特征线构成

Fig. 5 Feature line composition

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图 6 顶点高度差值

Fig. 6 Vertex height difference

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图 7 断裂面拓扑图

Fig. 7 Topological diagram of fracture surface

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图 8 匹配集优化结果

Fig. 8 Optimization results of matching set

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图 9 G10-26号俑部分邻接碎片拼接结果

Fig. 9 Reassembly results of some adjacent fragments of Warriors G10-26

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图 10 G10-19号俑部分邻接碎片拼接结果

Fig. 10 Reassembly results of some adjacent fragments of Warriors G10-19

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图 11 G10-23号俑部分邻接碎片拼接结果

Fig. 11 Reassembly results of some adjacent fragments of Warriors G10-23

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图 12 G10-18号俑部分邻接碎片拼接结果

Fig. 12 Reassembly results of some adjacent fragments of Warriors G10-18

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图 13 G10-36号俑部分邻接碎片拼接结果

Fig. 13 Reassembly results of some adjacent fragments of Warriors G10-36

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图 14 G10-22号俑部分邻接碎片拼接结果

Fig. 14 Reassembly results of some adjacent fragments of Warriors G10-22

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图 15 薄壁碎片断裂面特征提取图

Fig. 15 Feature extraction in thin fragments

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图 16 传统算法实验结果

Fig. 16 Experimental results of traditional methods

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表 1 兵马俑碎片实验数据

Table 1 Experimental datas of the Terracotta Army fragments

编号	碎片数量	网格总数	特征四边形总数	匹配精度
G10-18	7	674 477	253	0.924
G10-26	2	38 602	32	0.929
G10-36	6	591 641	191	0.961
G10-22	5	451 750	103	0.975
G10-19	3	94 276	93	0.924
G10-23	3	12 147	84	0.896

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表 2 本文算法运行时间

Table 2 Execute times of the proposed algorithm

编号	T1 (s)	T2 (s)	T3 (s)	总时间(s)
G10-18	68.461	17.436	7.246	93.143
G10-36	53.534	16.990	6.128	76.652
G10-22	30.157	12.631	4.021	46.809
G10-26	7.065	3.518	0.981	11.564
G10-19	17.913	6.349	2.065	26.327
G10-23	19.254	7.521	2.731	29.506

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