基于YOLO网络的车辆四点标定测距研究

doi:10.3901/JME.2023.10.226

机械工程学报 ›› 2023, Vol. 59 ›› Issue (10): 226-235.doi: 10.3901/JME.2023.10.226

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基于YOLO网络的车辆四点标定测距研究

梁忠超^1,2, 黄茁¹, 胡兴¹, 陈杰¹

1. 东北大学机械工程与自动化学院沈阳 110819;
2. 东北大学流程工业综合自动化国家重点实验室沈阳 110819

收稿日期:2022-11-01 修回日期:2023-02-25 出版日期:2023-05-20 发布日期:2023-07-19
通讯作者: 陈杰(通信作者),男,1988年出生,博士,副教授,博士研究生导师。主要研究方向为智能机器人等。E-mail:chenjie@me.neu.edu.cn E-mail:chenjie@me.neu.edu.cn
作者简介:梁忠超,男,1984年出生,博士,副教授,博士研究生导师。主要研究方向为智能车辆、移动机器人、月球车等。E-mail:liangzc@me.neu.edu.cn;黄茁,男,1997年出生。主要研究方向为智能车的视觉感知和轨迹跟踪控制。E-mail:1549495207@qq.com;胡兴,男,1997年出生。主要研究方向为车辆的智能测距、车辆的运动规划。E-mail:1757940901@qq.com
基金资助:
国家自然科学基金(51975109)、中央高校基本科研业务费(N2103018)和流程工业综合自动化国家重点实验室开放课题基金(2021-KF-11-02) 资助项目。

Research on Distance Measurement Using Vehicle Four-point Calibration Based on YOLO Neural Network

LIANG Zhongchao^1,2, HUANG Zhuo¹, HU Xing¹, CHEN Jie¹

1. School of Mechanical Engineering and Automation, Northeastern University, Shenyang 110819;
2. State Key Laboratory of Synthetical Automation of Process Industry, Northeastern University, Shenyang 110819

Received:2022-11-01 Revised:2023-02-25 Online:2023-05-20 Published:2023-07-19

摘要/Abstract

摘要： 精准且快速的车距测量是车辆实现自动驾驶和避障控制中不可或缺的数据依据之一,同时也是智能车辆安全行驶的必要环节之一。基于相机成像原理和Yolo only look once (YOLO)深度神经网络,提出一种快速且有效的单目相机测距方法,即四点标定测距算法。这种方法将深度神经网络和测距算法结合,能够实现快速识别目标车辆并计算与本车的相对距离信息。在车辆目标识别方面,基于Common objects in context(COCO)数据集和YOLO网络模型下的训练权重,完成对与车辆检测框的提取。在相对距离信息获取方面,基于相机小孔成像原理建立动态的纵、横向相机测距模型;同时,建立YOLO网络检测框中像素坐标系与实际测距中世界坐标系的解析方程,提出一种快速四点标定测距法。最后,进行四点标定测距法和内参数标定测距法的实车对比试验,试验结果表明,相较于内参数标定测距方法,提出的四点标定测距法能够省去繁琐的内参数标定步骤,同时测量误差在25 m范围内降低了1%左右,保持了较高的测距精度。

关键词: 车距测量, 神经网络, 自动驾驶

Abstract: Accurate and fast vehicle distance measurement is the indispensable data basic for vehicles to achieve autonomous driving and obstacle avoidance control, and it is also a necessary component for safe driving of intelligent vehicles. Based on the camera imaging principle and the Yolo only look once(YOLO) deep neural network, a fast and effective monocular camera ranging method is proposed, i.e., four-point calibration distance measurement algorithm. This algorithm combines the deep neural network and the ranging algorithm to quickly identify the target vehicle and calculate with the self-vehicle. In terms of the vehicle identification, the detection box is collected through the Common objects in context(COCO) data set and the YOLO network model. To obtain the information of the relative distance, the dynamic vertical and horizontal camera ranging model are established according to the principle of camera pinhole imaging. Meanwhile, the analytic equations of pixel coordinate system in YOLO network detection box and the world coordinate system in actual ranging are established, and the fast four-point calibration distance measurement method is proposed. Finally, the proposed four-point calibration distance measurement method is compared with the internal parameter calibration ranging method in the experiments. The experimental results show that the measurement error is reduced by about 1% within the range of 25 m, and the complex internal parameter calibration steps can be omitted.

Key words: vehicle distance measurement, neural networks, autonomous driving

中图分类号:

TG156

梁忠超, 黄茁, 胡兴, 陈杰. 基于YOLO网络的车辆四点标定测距研究[J]. 机械工程学报, 2023, 59(10): 226-235.

LIANG Zhongchao, HUANG Zhuo, HU Xing, CHEN Jie. Research on Distance Measurement Using Vehicle Four-point Calibration Based on YOLO Neural Network[J]. Journal of Mechanical Engineering, 2023, 59(10): 226-235.

参考文献

[1] 王慧然,王其东,陈无畏,等. 基于车辆行驶安全边界的换道控制[J]. 机械工程学报,2020,56(18):43-153. WANG Huiran,WANG Qidong,CHEN Wuwei,et al. Lane-changing control based on vehicle safety boundary[J]. Journal of Mechanical Engineering,2020,56(18):143-153.
[2] 王明强,王震坡,张雷. 基于碰撞风险评估的智能汽车局部路径规划方法研究[J]. 机械工程学报,2021,57(10):28-41. WANG Mingqiang,WANG Zhenpo,ZHANG Lei. Research on local path planning method of smart car based on collision risk assessment[J]. Journal of Mechanical Engineering,2021,57(10):28-41.
[3] 汪,殷国栋,耿可可,等. 基于不同紧急工况辨识的车辆主动避撞自适应控制[J]. 机械工程学报,2020,56(4):115-124. WANG Gong,YIN Guodong,GENG Keke,et al. Vehicle active collision avoidance adaptive control based on identification of different emergency conditions[J] Journal of Mechanical Engineering,2020,56(4):115-124.
[4] 薛培林,吴愿,殷国栋,等. 基于信息融合的城市自主车辆实时目标识别[J]. 机械工程学报,2020,56(12):165-173. XUE Peilin,WU Yuan,YIN Guodong,et al. Real-time target recognition of urban autonomous vehicles based on information fusion[J]. Journal of Mechanical Engineering,2020,56(12):165-173.
[5] 江燕华,熊光明,姜岩,等. 基于CarSim和Matlab的智能车辆视觉里程计仿真平台设计[J]. 机械工程学报,2012,48(22):113-120. JIANG Yanhua,XIONG Guangming,JIANG Yan,et al. Intelligent vehicle visual odometer simulation platform design based on CarSim and Matlab[J]. Journal of Mechanical Engineering,2012,48(22):113-120.
[6] 罗敏,刘洞波,文浩轩,等. 基于背景差分法和帧间差分法的车辆运动目标检测[J]. 湖南工程学院学报(自然科学版),2019,29(4):58-61. LUO Min,LIU Dongbo,WEN Haoxuan,et al. Vehicle moving target detection based on background difference method and frame difference method[J]. Journal of Hunan Institute of Engineering (Natural Science Edition),2019,29(4):58-61.
[7] 陈志韬. 基于深度学习的图像目标识别研究[D]. 哈尔滨:哈尔滨工程大学,2018. CHEN Zhitao. Research on image target recognition based on deep learning[D]. Harbin:Harbin Engineering University,2018.
[8] LIU W,ANGUELOV D,ERHAN D,et al. SSD:Single shot multibox detector[C]//European Conference on Computer Vision. Springer,Cham,Switzerland,2016:21-37.
[9] REDMON J,DIVVALA S,GIRSHICK R,et al. You only look once:unified,real-time object detection[C]//Proceedings of the IEEE Conference on Computer Vision and Pattern Recognition. Las Vegas,NV,USA. 2016:779-788.
[10] 柯振宇. 基于毫米波雷达的车辆纵向碰撞预警系统设计[D]. 武汉:武汉理工大学,2014. KE Zhenyu. Design of vehicle longitudinal collision warning system based on millimeter wave radar[D]. Wuhan:Wuhan University of Technology,2014.
[11] PIRACHA M U,NGUYEN D,MANDRIDIS D,et al. Range resolved lidar for long distance ranging with sub-millimeter resolution[J]. Optics Express,2010,18(7):7184-7189.
[12] 李茂山. 超声波测距原理及实践技术[J]. 实用测试技术,1994,20(1):12-20. LI Maoshan. The principle and practical technology of ultrasonic ranging[J]. Practical Testing Technology,1994,20(1):12-20.
[13] SONG Z,LU J,ZHANG T,et al. End-to-end learning for inter-vehicle distance and relative velocity estimation in ADAS with a monocular camera[C]//2020 IEEE International Conference on Robotics and Automation (ICRA). Paris,France,2020:11081-11087.
[14] 吴涛,胡庭波. 基于单目测距的立体视觉技术[C]//中国宇航学会深空探测技术专业委员会第二届学术会议论文集,2005:356-360. WU Tao,HU Tingbo. Stereo vision technology based on monocular ranging[C]//Academic Conference of the Deep Space Exploration Technology Professional Committee of Chinese Astronautical Society,2005:356-360.
[15] 胡泽军. 基于单目视觉的前向车辆测距方法研究[D]. 杭州:浙江科技学院,2020. HU Zejun. Research on forward vehicle ranging method based on monocular vision[D]. Hangzhou:Zhejiang University of science and technology,2020.
[16] XU D,ZHANG D,LIU X,et al. A calibration and 3-D measurement method for an active vision system with symmetric yawing cameras[J],IEEE Transactions on Instrumentation and Measurement,2021,70:1-13.
[17] HAN J, HEO O, PARK M,et al. Vehicle distance estimation using a mono-camera for FCW/AEB systems[J]. International Journal of Automotive Technology,2016,17(3):483-491.
[18] REZAEI M, TERAUCHI M, KLETTE R. Robust vehicle detection and distance estimation under challenging lighting conditions[J]. IEEE Transactions on Intelligent Transportation Systems,2015,16(5):2723-2743.
[19] LIU L C,FANG C Y,CHEN S W. A novel distance estimation method leading a forward collision avoidance assist system for vehicles on highways[J]. IEEE Transactions on Intelligent Transportation Systems,2016,18(4):937-949.
[20] REDMON J,FARHADI A. YOLOv3:An incremental improvement[C]//IEEE Trans Pattern Anal,2018:1125-1131.
[21] LIN T Y,MAIRE M,BELONGIE S,et al. Microsoft coco:Common objects in context[C]//European conference on computer vision. Springer,Cham,Switzerland,2014:740-755.
[22] 陈军,徐友春,彭永胜,等. 基于道路特征的车载相机标定动态补偿算法[J]. 机械工程学报,2010,46(20):112-117. CHEN Jun,XU Youchun,PENG Yongsheng,et al. Dynamic compensation algorithm for vehicle camera calibration based on road characteristics[J]. Journal of Mechanical Engineering,2010,46(20):112-117.
[23] 路萍萍,郭建明,刘清. 基于张正友平面标定法的摄像机标定方法实现[C/CD]//第十四届海峡两岸智能运输系统学术研讨会,2014. LU Pingping,GUO Jianming,LIU Qing. Implementation of camera calibration method based on zhang zhengyou's plane calibration method[C/CD]//the 14th Cross Strait Symposium on Intelligent Transportation Systems,2014.
[24] 卢贺. 基于机器视觉的前方车辆检测与测距研究[D]. 重庆:重庆交通大学,2018. LU He. Research on front vehicle detection and ranging based on machine vision[D]. Chongqing:Chongqing Jiaotong University,2018.

基于YOLO网络的车辆四点标定测距研究

Research on Distance Measurement Using Vehicle Four-point Calibration Based on YOLO Neural Network

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