小尺寸零件的无标志点扫描测量方法 -

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小尺寸零件的无标志点扫描测量方法

doi:10.37188/CO.2023-0103

莫彩利^{1, 3,},
王立忠^{1, 2,,},
赵建博^{2, 3},
王森^{1, 3},
周皓骏^{2, 3},
任茂栋³

1.
新疆大学机械工程学院, 新疆乌鲁木齐 830046
2.
西安交通大学机械工程学院机械制造系统工程国家重点实验室, 陕西西安 710049
3.
新拓三维技术有限公司创新实验室, 广东深圳 518060

基金项目:国家重点研发计划(No. 2022 YFB4601802)

详细信息

作者简介:
莫彩利（1995—），女，河南洛阳人，硕士研究生，2018年于长安大学获得学士学位，主要从事三维光学测量方面的研究。E-mail：18292880263@163.com
王立忠（1968—），男，山东梁山人，博士，教授，博士生导师，2004年于西安交通大学获得博士学位，主要从事三维光学测量技术的研究。E-mail：wanglz@mail.xjtu.edu.cn

中图分类号:TP391.7；TH741
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出版历程
- 网络出版日期:2023-09-22

Scanning measurement method of small size parts without marks

MO Cai-li^{1, 3,},
WANG Li-zhong^{1, 2,,},
ZHAO Jian-bo^{2, 3},
WANG Sen^{1, 3},
ZHOU Hao-jun^{2, 3},
REN Mao-dong³

1.
School of Mechanical Engineering, Xinjiang University, Urumqi 830046, China
2.
State Key Laboratory for Manufacturing System Engineering, School of Mechanical Engineering, Xi’an Jiaotong University, Xi’an 710049, China
3.
Innovation Lab, XTOP 3D Technology Co. Ltd, Shenzhen 518060, China

Funds:Supported by National Key Research and Development Program (No. 2022 YFB4601802)

More Information

Corresponding author:wanglz@mail.xjtu.edu.cn

摘要

摘要:
小尺寸零件的表面积小、结构复杂，传统标志点拼接方法需要在零件表面人工粘贴标志点，导致表面的测量数据缺失成为孔洞；基于特征的点云拼接方法要求零件表面具有易区分的几何或距离特征，不适用于包含重复性特征的回转体零件。本文提出一种基于机械拼接的无标志点扫描测量方法，不需要粘贴标志点，不依赖于零件表面特征。首先，采用基于摄影测量的相机标定方法重建标定板上靶点的高精度三维坐标，通过跟踪编码靶点的位置建立转台不同转角对应的旋转矩阵，进而解算出转轴方向向量和轴上定点坐标，实现转轴和相机的同步标定。其次，在完成两个转轴位姿精确标定的基础上，利用转台转角构建旋转拼接矩阵，实现多视角点云粗配准。最后，基于法向迭代最近点算法(Normal Iterative Closest Point, NICP)完成点云的精配准。实验结果表明：使用靶点跟踪法标定后的两转轴夹角误差较传统的标准球拟合法低0.023°，标定后测量标准球的整体平均尺寸误差小于0.012 mm；在小尺寸零件自动化测量时，机械拼接方法在精配准后的点云拼接效果与标志点拼接方法相近，且拼接稳定性更高。机械拼接方法适用于无法粘贴标记点的小尺寸零件三维形貌测量场景。
- 结构光/
- 机械拼接/
- 小尺寸零件/
- 转轴标定/
- NICP算法
Abstract:
Small size parts have a small surface area and complex structure. The traditional mark splicing method needs to manually paste marks on the surface of parts, resulting in missing the measurement data of the surface and becoming holes. The feature splicing method requires the surface of parts to have easily distinguishable geometric or distance features, which are not suitable for rotating parts containing repetitive features. We propose a scanning measurement method without marks based on mechanical splicing, which does not need to paste marks or depend on the surface features of parts. First, the camera calibration method based on photogrammetry is used to reconstruct the high precision 3D coordinates of the target on the calibration board. By tracking the position of the encoded target, the rotation matrix corresponding to different angles of the turntable is established, and the direction vector of the rotation axis and the fixed point coordinates on the axis are solved. Then the synchronous calibration of the rotation axis and the camera is completed. Second, based on the accurate calibration of poses of two rotation axes, the rotation mosaic matrix is constructed by using the turntable angle to realize the rough registration of multi-view point clouds. Finally, based on the Normal Iterative Closest Point (NICP) algorithm, the fine registration of the point clouds is completed. Experimental results show that the angle error between the two rotation axes calibrated by the target tracking method is 0.023° lower than that of the traditional standard ball fitting method. After calibration, the average size error of the standard ball is less than 0.012 mm. In the automatic measurement of small-size parts, the point cloud splicing effect of the mechanical splicing method after fine registration is similar to that of the mark splicing method, and the splicing stability is higher. The mechanical splicing method is suitable for the 3D topography measurement of small-size parts where the marks cannot be pasted.
- Structured light/
- mechanical splicing/
- small-size parts/
- axis calibration/
- NICP algorithm

HTML全文

图 1无标志点扫描测量方法的流程图

Figure 1.Flowchart of the scanning measurement method without marks

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图 2针孔相机成像模型

Figure 2.Imaging model of pinhole camera

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图 3相机标定过程图

Figure 3.Camera calibration process diagram

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图 4标定板图像

Figure 4.Image of calibration board

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图 5标准球拟合法标定单个转轴位姿

Figure 5.Calibration of single rotation axis pose using standard ball fitting method

下载: 全尺寸图片幻灯片

图 6多视角点云旋转拼接原理图

Figure 6.Schematic diagram of multi-view point cloud rotation splicing

下载: 全尺寸图片幻灯片

图 7绕空间任意转轴的旋转变换关系

Figure 7.The rotation transformation relation around any rotation axis in space

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图 8NICP算法流程图

Figure 8.Flowchart of NICP algorithm

下载: 全尺寸图片幻灯片

图 9(a)桌面式数控转台光学测量系统及(b)示意图

Figure 9.(a) Tabletop CNC turntable optical measurement system and (b) its schematic diagram

下载: 全尺寸图片幻灯片

图 10基于标准球的精度验证实验

Figure 10.Accuracy verification experiment based on standard ball

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图 11标准球机械拼接绝对值误差统计结果

Figure 11.Statistical results of absolute value error of standard ball mechanical splicing

下载: 全尺寸图片幻灯片

图 12小尺寸零件的点云拼接效果图

Figure 12.Point cloud splicing effect diagrams of small-size parts

下载: 全尺寸图片幻灯片

表 1相机标定内参数

Table 1.Camera calibration internal parameters

内参数	左相机	右相机
f/pixel	4666.2300	4666.5600
$ {x}_{0}/pixel $	47.6090	−14.4401
$ {y}_{0}/pixel $	10.2786	−14.5546
$ {K}_{1} $	−3.4003e−09	−4.1734e−09
$ {K}_{2} $	1.1598e−15	1.8279e−15
$ {K}_{3} $	1.8523e−22	−2.2075e−23
$ {P}_{1} $	−7.4732e−08	1.5797e−08
$ {P}_{2} $	1.0306e−08	−2.0569e−09
$ {b}_{1} $	1.2749e−4	2.4643e−06
$ {b}_{2} $	−2.2662e−05	3.9066e−05

下载: 导出CSV

表 2相机标定外参数

Table 2.Camera calibration external parameters

相机编号	${{\boldsymbol{R}}_C}$			${{\boldsymbol{T}}_C}$
左相机	1	0	0	0
	0	1	0	0
	0	0	1	0
右相机	0.8992	−0.0098	0.4374	176.2110
	0.0063	0.9999	0.0094	−0.1690
	−0.4374	−0.0057	0.8992	−40.5125

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表 3标准球拟合法与所提方法的对比

Table 3.Comparison between standard ball fitting method and proposed method

实验编号	标准球拟合法^[22]			文中所提方法
实验编号	夹角/°	点积	夹角误差/°	夹角/°	点积	夹角误差/°
1	89.938	0.001078	0.062	89.962	0.000666	0.038
2	89.923	0.001341	0.077	89.949	0.000883	0.051
3	89.934	0.001145	0.066	89.962	0.000658	0.038
4	89.939	0.001072	0.061	89.955	0.000786	0.045
5	89.940	0.001048	0.060	89.961	0.000686	0.039
6	89.929	0.001245	0.071	89.965	0.000604	0.035
7	89.938	0.001079	0.062	89.952	0.000838	0.048
8	89.938	0.001085	0.062	89.947	0.000922	0.053
9	89.939	0.001058	0.061	89.965	0.000606	0.035
10	89.940	0.001048	0.060	89.967	0.000583	0.033
平均	89.936	0.001120	0.064	89.959	0.000723	0.041

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表 4不同点云拼接方式的精度对比

Table 4.Accuracy comparison of different point cloud splicing methods unit: mm

实验对象	特征拼接^[13]	标志点拼接^[9-10]	机械拼接
实验对象	特征拼接^[13]	标志点拼接^[9-10]	粗配准	精配准
注塑件	0.0116	0.0098	0.1135	0.0102
假牙	0.0124	0.0106	0.1213	0.0113
涡轮	0.6845	0.0129	0.1265	0.0123
平均误差	0.2362	0.0111	0.1204	0.0113

下载: 导出CSV

参考文献 (28)

[1]	吕虹毓, 李茂月, 蔡东辰, 等. 光栅投影在机三维形貌检测技术研究进展[J]. 中国光学,2023,16(3):500-513. LV H Y, LI M Y, CAI D CH,et al. Research progress of grating projection on machine 3D topography inspection technology[J].Chinese Optics, 2023, 16(3): 500-513. (in Chinese)
[2]	HELLE R H, LEMU H G. A case study on use of 3D scanning for reverse engineering and quality control[J].Materials Today:Proceedings, 2021, 45: 5255-5262.doi:10.1016/j.matpr.2021.01.828
[3]	YANG X X, ZHU SH SH. Application of 3D laser scanner in digitization of movable cultural relics[C].2021 IEEE International Conference on Power Electronics, Computer Applications, Shenyang, IEEE, 2021: 550-553.
[4]	李茂月, 刘泽隆, 赵伟翔, 等. 面结构光在机检测的叶片反光抑制技术[J]. 中国光学,2022,15(3):464-475.doi:10.37188/CO.2021-0194 LI M Y, LIU Z L, ZHAO W X,et al. Blade reflection suppression technology based on surface structured light on-machine detection[J].Chinese Optics, 2022, 15(3): 464-475. (in Chinese)doi:10.37188/CO.2021-0194
[5]	MEZA J, CONTRERAS-ORTIZ S H, PEREZ L A R,et al. Three-dimensional multimodal medical imaging system based on freehand ultrasound and structured light[J].Optical Engineering, 2021, 60(5): 054106.
[6]	王永红, 张倩, 胡寅, 等. 显微条纹投影小视场三维表面成像技术综述[J]. 中国光学,2021,14(3):447-457.doi:10.37188/CO.2020-0199 WANG Y H, ZHANG Q, HU Y,et al. 3D small-field surface imaging based on microscopic fringe projection profilometry: a review[J].Chinese Optics, 2021, 14(3): 447-457. (in Chinese)doi:10.37188/CO.2020-0199
[7]	任明阳, 王立忠, 赵建博, 等. 复杂曲面零件面结构光扫描视点规划[J]. 中国光学,2023,16(1):113-126. REN M Y, WANG L ZH, ZHAO J B,et al. Viewpoint planning of surface structured light scanning for complex surface parts[J].Chinese Optics, 2023, 16(1): 113-126. (in Chinese)
[8]	杨鹏程, 杨朝, 孟杰, 等. 基于法向量和面状指数特征的文物点云棱界配准方法[J]. 中国光学,2023,16(3):654-662.doi:10.37188/CO.2022-0156 YANG P CH, YANG ZH, MENG J,et al. Aligning method for point cloud prism boundaries of cultural relics based on normal vector and faceted index features[J].Chinese Optics, 2023, 16(3): 654-662. (in Chinese)doi:10.37188/CO.2022-0156
[9]	马国庆, 刘丽, 于正林, 等. 大型复杂曲面三维形貌测量及应用研究进展[J]. 中国光学,2019,12(2):214-228.doi:10.3788/co.20191202.0214 MA G Q, LIU L, YU Z L,et al. Application and development of three-dimensional profile measurement for large and complex surface[J].Chinese Optics, 2019, 12(2): 214-228. (in Chinese)doi:10.3788/co.20191202.0214
[10]	LIN X B, ZHOU Y W, LIN CH. Study on 3D data mosaic method of point cloud data in reverse engineering[C].2021 Asia-Pacific Conference on Communications Technology and Computer Science, IEEE, 2021: 143-147.
[11]	QIN L, CHEN X, GONG X. An improved 3D reconstruction method for weak texture objects combined with calibration and ICP registration[C].2023 IEEE 6th International Conference on Industrial Cyber-Physical Systems, IEEE, 2023: 1-5.
[12]	XIANG J, FAN W Q, LIU P,et al. Point cloud alignment method based on improved ISS-ICP algorithm[C].2022 5th International Conference on Information Communication and Signal Processing, IEEE, 2022: 249-253.
[13]	LI J L, CHEN B R, YUAN M,et al. Matching algorithm for 3D point cloud recognition and registration based on multi-statistics histogram descriptors[J].Sensors, 2022, 22(2): 417.doi:10.3390/s22020417
[14]	ZOU Z S, WANG R, ZOU J L,et al. Robust descriptor for key-point detection and matching in color images with radial distortion[J].Journal of Electronic Imaging, 2022, 31(2): 023038.
[15]	何成刚, 郑衡, 丁克, 等. 基于机械臂辅助的多视角三维点云拼接算法研究[J]. 与光电子学进展,2023,60(20):2015001. HE CH G, ZHENG H, DING K,et al. Research on multi-view 3D point cloud stitching algorithm based on robot arm assistance[J].Laser & Optoelectronics Progress, 2023, 60(20): 2015001. (in Chinese)
[16]	SILVA M Z, BRITO T, LIMA J L,et al. Industrial robotic arm in machining process aimed to 3D objects reconstruction[C].2021 22nd IEEE International Conference on Industrial Technology, IEEE, 2021: 1100-1105.
[17]	CAI X Q, ZHONG K J, FU Y J,et al. Calibration method for the rotating axis in panoramic 3D shape measurement based on a turntable[J].Measurement Science and Technology, 2021, 32(3): 035004.doi:10.1088/1361-6501/abcb7e
[18]	YE J, XIA G S, LIU F,et al. 3D reconstruction of line-structured light based on binocular vision calibration rotary axis[J].Applied Optics, 2020, 59(27): 8272-8278.doi:10.1364/AO.403356
[19]	胡民政, 习俊通. 面向结构光三维测量的两轴转台标定[J]. 上海交通大学学报,2010,44(4):506-511.doi:10.16183/j.cnki.jsjtu.2010.04.014 HU M ZH, XI J T. Two-axis turntable calibration in three-dimensional structured light measurement system[J].Journal of Shanghai Jiaotong University, 2010, 44(4): 506-511. (in Chinese)doi:10.16183/j.cnki.jsjtu.2010.04.014
[20]	YE Y P, SONG ZH. An accurate 3D point cloud registration approach for the turntable-based 3D scanning system[C].2015 IEEE International Conference on Information and Automation, IEEE, 2015: 982-986.
[21]	李杨, 许志闻, 宋展, 等. 面向全自动三维扫描系统的多视角三维数据自动配准技术[J]. 吉林大学学报(理学版),2014,52(2):319-325.doi:10.13413/j.cnki.jdxblxb.2014.02.31 LI Y, XU ZH W, SONG ZH,et al. Automated multi-view 3D data registration for fully-automated 3D scanning system[J].Journal of Jilin University (Science Edition), 2014, 52(2): 319-325. (in Chinese)doi:10.13413/j.cnki.jdxblxb.2014.02.31
[22]	LI W L, WU A, LI Z CH,et al. A new calibration method between an optical sensor and a rotating platform in turbine blade inspection[J].Measurement Science and Technology, 2017, 28(3): 035009.doi:10.1088/1361-6501/aa50df
[23]	吕海东, 任永潮, 戴士杰, 等. 基于2D靶标的摄像机与转台中心轴同步标定方法[J]. 传感器与微系统,2019,38(7):23-27.doi:10.13873/j.1000-9787(2019)07-0023-05 LV H D, REN Y CH, DAI SH J,et al. Synchronization calibration method of camera and turntable center axis based on 2D target[J].Transducer and Microsystem Technologies, 2019, 38(7): 23-27. (in Chinese)doi:10.13873/j.1000-9787(2019)07-0023-05
[24]	PANG X F, LAU R W H, SONG ZH,et al. A tool-free calibration method for turntable-based 3D scanning systems[J].IEEE Computer Graphics and Applications, 2016, 36(1): 52-61.doi:10.1109/MCG.2014.83
[25]	陈仁虹, 梁晋, 叶美图, 等. 柔性复合薄膜成形极限曲线的视觉测定方法[J]. 中国光学,2022,15(1):22-33. CHEN R H, LIANG J, YE M T,et al. Visual method for measuring forming limit curve of pliable composite film[J].Chinese Optics, 2022, 15(1): 22-33. (in Chinese)
[26]	任明阳, 王立忠, 付白强, 等. 高温数字图像相关法变形测量中玻璃介质误差校正[J]. 中国光学,2022,15(2):327-338. REN M Y, WANG L ZH, FU B Q,et al. Error correction of glass mediums in high-temperature digital image correlation deformation measurement[J].Chinese Optics, 2022, 15(2): 327-338. (in Chinese)
[27]	ZHU K, GONG L, GU D J,et al. An analytic calibration method for turntable-based 3D scanning system[C].2019 IEEE/ASME International Conference on Advanced Intelligent Mechatronics, IEEE, 2019: 495-500.
[28]	SERAFIN J, GRISETTI G. NICP: Dense normal based point cloud registration[C].2015 IEEE/RSJ International Conference on Intelligent Robots and Systems, IEEE, 2015: 742-749.