Fast Detection Technology for Tunnel Slab Staggering Based on Oblique Line Structured Light

doi:10.3969/j.issn.1674-0696.2022.10.15

Abstract

Abstract: In order to realize the rapid and automatic detection of tunnel slab staggering and ensure the safety of tunnel structure, a fast-detecting method for tunnel slab staggering based on oblique line structure light was proposed. Firstly, based on the principle of oblique laser triangulation and imaging, the theoretical formula for calculating the amount of misalignment was derived. And the random sampling consistency (RANSAC) algorithm was used for linear function fitting approximation to convert the angle parameters that were difficult to measure into function constants. Then, the region of interest (ROI) of the image was extracted by combining the target detection algorithm Yolo-v3 and the image gradient features. The sub-pixel level of the center of the light strip was extracted by gray square weighted center of gravity method. And the pixel displacement was obtained according to the distance formula between straight lines. Finally, the laboratory test data and actual engineering data were verified. The research results indicate that the algorithm Yolo-v3 can locate the tunnel slab staggering region, with an accuracy rate of 97.35% and a computational efficiency of 26 images per second. Meanwhile, compared with the extreme value method, the Steger method, and the gray center of gravity method, the proposed algorithm is more accurate in extracting the center of the light bar. Moreover, the absolute error of 87% of slab staggering detection results and actual measurement results is within 0.6mm, and the maximum absolute error is no more than 1.5mm. The proposed method can meet the engineering application.

Key words: tunnel engineering; slab staggering detection; laser triangulation method; structured light; gray square weighted center of gravity method

摘要： 为实现隧道错台快速、自动检测，保障隧道结构安全，提出基于斜射式线结构光的错台快速检测方法。首先，基于斜射式激光三角法原理和成像原理推导出错台量计算的理论公式，并且采用随机抽样一致性(RANSAC)算法进行线性函数拟合逼近，将不易测量的角度参数转换为函数常量；然后，结合目标检测算法Yolo-v3和图像梯度特征提取图像感兴趣区域(ROI)，采用灰度平方加权重心法对光条中心点进行亚像素级提取，依据直线间距离公式获得像素位移量；最后，对室内试验数据和实际工程数据进行验证。研究结果表明：利用Yolo-v3算法实现错台区域定位，准确率可达97.35%，计算效率每秒26张图像，同时与极值法、Steger法、灰度重心法相比，提出的算法在光条中心点提取方面更加精准，并且87%的错台检测结果与实际测量结果绝对误差在0.6 mm以内，最大绝对误差不大于1.5 mm，满足工程应用。

关键词: 隧道工程；错台检测；激光三角法；结构光；灰度平方加权重心法

CLC Number:

U457.2

LIU Xingen1,2, CHEN Yingying1,2, LI Mingdong1. Fast Detection Technology for Tunnel Slab Staggering Based on Oblique Line Structured Light[J]. Journal of Chongqing Jiaotong University(Natural Science), 2022, 41(10): 108-115.

刘新根1,2，陈莹莹1,2，李明东1. 基于斜射式线结构光的隧道错台快速检测技术[J]. 重庆交通大学学报（自然科学版）, 2022, 41(10): 108-115.

References

［1］魏新江, 洪文强, 魏纲, 等. 堆载引起临近地铁隧道的转动与错台变形计算［J］. 岩石力学与工程学报, 2018, 37(5): 1281-1289.
WEI Xinjiang, HONG Wenqiang, WEI Gang, et al. Rotation and shearing dislocation deformation of subway tunnels due to adjacent ground stack load［J］. Chinese Journal of Rock Mechanics and Engineering, 2018, 37(5): 1281-1289.
［2］张娟, 叶莉, 李伟. 水泥混凝土路面错台自动检测方法［J］. 交通运输工程学报, 2016, 16(4): 26-36.
ZHANG Juan, YE Li, LI Wei. Automatic detecting method of cement concrete pavement fault［J］. Journal of Traffic and Transportation Engineering, 2016, 16(4): 26-36.
［3］陈富强，陈富坚，黄慧. 水泥混凝土路面接缝错台转换模型构建研究［J］. 重庆交通大学学报（自然科学版）, 2016, 35(5): 70-73.
CHEN Fuqiang, CHEN Fujian, HUANG Hui. Study on establish-ment of conversion model for joint faulting of cement-concrete pavement［J］. Journal of Chongqing Jiaotong University(Natural Science), 2016, 35(5): 70-73.
［4］ WANG K, LI L, LI J Q, et al. Automated joint faulting measure-ment using 3D pavement texture data at 1mm resolution［C］∥Second Transportation & Development Congress 2014. ［S.l.］: ASCE, 2014: 498-510.
［5］孙朝云, 郝雪丽, 沙爱民, 等. 水泥混凝土路面错台三维检测方法［J］. 长安大学学报: 自然科学版, 2016, 36(2): 1-8.
SUN Chaoyun, HAO Xueli, SHA Aimin, et al. 3D detection method of cement concrete joint faulting［J］. Journal of Changan University (Natural Science Edition), 2016, 36(2): 1-8.
［6］李伟, 沙爱民, 孙朝云, 等. 基于线结构光的水泥混凝土路面错台三维检测［J］. 同济大学学报: 自然科学版, 2015, 43(7): 1039-1044.
LI Wei, SHA Aimin, SUN Chaoyun, et al. Joint faulting three-dimension detection method on cement concrete pavement with line-structure light［J］. Journal of Tongji University（Natural Science）, 2015, 43(7): 1039-1044.
［7］王子彬, 马世旋, 靳杰. 三维激光路面错台检测方法的可靠性试验分析［J］. 中外公路, 2017, 37(1): 28-31.
WANG Zibin, MA Shixuan, JIN Jie. Reliability test analysis of three-dimensional laser pavement stagger detection method［J］. China and Foreign Highway, 2017, 37(1): 28-31.
［8］丁少闻, 张小虎, 于起峰, 等. 非接触式三维重建测量方法综述［J］. 激光与光电子学进展, 2017, 54(7): 21-35.
DING Shaowen, ZHANG Xiaohu, YU Qifeng, et al. Overview of non-contact 3D reconstruction measurement methods［J］. Laser & Optoelectronics Progress, 2017, 54(7): 21-35.
［9］ SOBEL I. On calibrating computer controlled cameras for perceiving 3-D scenes［J］. Artificial Intelligence, 1974, 5(2): 185-198.
［10］ TSAI R Y. A versatile camera calibration technique for high-accuracy 3D machine vision metrology using off-the-shelf TV cameras and lenses［J］. IEEE Journal on Robotics and Automation, 1987, 3(4): 323-344.
［11］ ZHANG Z. A flexible new technique for camera calibration［J］. IEEE Transactions on Pattern Analysis and Machine Intelligence, 2000, 22(11): 1330-1334.
［12］解则晓, 张安祺. 超大尺度线结构光传感器内外参数同时标定［J］. 光学学报, 2018, 38(3): 315-323.
XIE Zexiao, ZHANG Anqi. Simultaneous calibration of the intrinsic and extrinsic parameters of ultra-large-scale line structured-light sensor［J］. Acta Optica Sinica, 2018, 38(3): 315-323.
［13］王利, 陈念年, 巫玲, 等. 高噪声背景下激光条纹亚像素中心的提取［J］. 应用光学, 2016, 37(2): 321-326.
WANG Li, CHEN Niannian, WU Ling, et al. Extraction of laser stripe sub-pixel center in high-noise background［J］. Journal of Applied Optics, 2016, 37(2): 321-326.
［14］梅峻华, 赖磊捷. 结构光测量系统光条中心提取算法研究［J］. 电子测量技术, 2018, 41(21): 8-13.
MEI Junhua, LAI Leijie. Research on the algorithm for extracting the center of light stripe in structured light measurement system［J］. Electronic Measurement Technology, 2018, 41(21): 8-13.
［15］蔡怀宇, 冯召东, 黄战华. 基于主成分分析的结构光条纹中心提取方法［J］. 中国激光, 2015, 42(3): 270-275.
CAI Huaiyu, FENG Zhaodong, HUANG Zhanhua. Centerline extraction of structured light stripe based on principal component analysis［J］. Chinese Journal of Lasers, 2015, 42(3): 270-275.
［16］余乐文, 张达, 张元生. 基于线结构光的三维测量系统关键技术研究［J］. 光电子激光, 2016, 27(2): 156-161.
YU Lewen, ZHANG Da, ZHANG Yuansheng. Study on key technologies of three-dimensional measurement system based online structure light［J］. Journal of Optoelectronics Laser, 2016, 27(2): 156-161.
［17］李瑛, 成芳, 赵志林. 采用结构光的大跨度销孔加工精度在线测量［J］. 浙江大学学报:工学版, 2020, 54(3): 557-565, 613.
LI Ying, CHENG Fang, ZHAO Zhilin. Machining precision online measurement of large span pin hole using structured light［J］. Journal of Zhejiang University（Engineering Science）, 2020, 54(3): 557-565, 613.
［18］杨镇豪, 杨柳, 李辉. 复杂环境下结构光中心线提取算法［J］. 计算机技术与发展, 2018, 28(9):7-10.
YANG Zhenhao, YANG Liu, LI Hui. Stripecenter extraction algorithm for structured light in complex environment［J］. Computer Technology and Development, 2018, 28(9): 7-10.
［19］朱铮涛, 裴炜冬, 李渊, 等. 基于远心镜头的激光三角测距系统研究与实现［J］. 激光与光电子学进展, 2018, 55(3): 185-190.
ZHU Zhengtao, PEI Weidong, LI Yuan, et al. Research and implementation of laser triangulation system based on telecentric lens［J］. Laser & Optoelectronics Progress, 2018, 55(3): 185-190.
［20］杨桂栓, 陈涛, 张志峰. 基于激光三角法对透明平板厚度测量光线补偿的研究及应用［J］. 中国激光, 2015, 42(7): 211-218.
YANG Guishuan, CHEN Tao, ZHANG Zhifeng. Study and application on transparent plate thickness measurement based on laser triangulation with light compensation［J］. Chinese Journal of Lasers, 2015, 42(7): 211-218.
［21］肖春宝, 冯大政, 冯祥卫. 重抽样优化的快速随机抽样一致性算法［J］. 计算机辅助设计与图形学学报, 2016, 28(4): 606-613.
XIAO Chunbao, FENG Dazheng, FENG Xiangwei. Fast RANSAC algorithm with resample optimization［J］. Journal of Computer-Aided Design & Computer Graphics, 2016, 28(4): 606-613.
［22］ REDMON J, FARHADI A. YOLOv3: An incremental improvement［J/OL］.(2019-10-15)［2021-1-13］. https:∥pjreddie.com/media/files/papers/YOLOv3.pdf.
［23］ LIN T Y, Dollar P, GIRSHICK R, et al. Featurepyramid networks for object detection［C］∥2017 IEEE Conference on Computer Vision and Pattern Recognition (CVPR). IEEE, 2017.
［24］刘馨柔, 李洋, 宋文军. 基于SlimYOLOv3的工业场景目标检测算法［J］. 计算机应用研究. 2020,38(6):1889-1893.
LIU Xinrou, LI Yang, SONG Wenjun. Target detection algorithm in industrial scene based on SlimYOLOv3［J］. Application Research of Computers. 2020, 38(6): 1889-1893.