Volume 48 Issue 12
Dec.  2022
Turn off MathJax
Article Contents
Abstract
References
Related Articles
MA Aiqiang, YAO Wanqiang, LIN Xiaohu, et al. Coal mine roadway environment-oriented LiDAR and IMU fusion positioning and mapping method[J]. Journal of Mine Automation,2022,48(12):49-56. DOI: 10.13272/j.issn.1671-251x.2022070007
Citation: MA Aiqiang, YAO Wanqiang, LIN Xiaohu, et al. Coal mine roadway environment-oriented LiDAR and IMU fusion positioning and mapping method[J]. Journal of Mine Automation,2022,48(12):49-56. DOI: 10.13272/j.issn.1671-251x.2022070007
shu

Coal mine roadway environment-oriented LiDAR and IMU fusion positioning and mapping method

  • 1.

    College of Geomatics, Xi'an University of Science and Technology, Xi'an 710054, China

  • 2.

    Shaanxi Binchang Mining Group Co., Ltd., Xianyang 712000, China

More Information
  • Received Date: July 03, 2022
  • Revised Date: November 25, 2022
  • Available Online: August 08, 2022
    Graphical Abstract
    • Abstract
  • The failure of autonomous navigation, positioning and mapping of the mobile robot is caused by the shotcrete surface and symmetrical roadway in coal mine. In order to solve this problem, a real-time positioning and mapping method based on LiDAR and IMU fusion is proposed for the roadway environment in the coal mine. Firstly, the original point cloud is segmented. The IMU pre-integration pose is used to remove the nonlinear motion distortion of the original point cloud. The line and surface feature extraction is carried out on the obtained point cloud. Secondly, the line and surface features of adjacent frames are matched. The initial pose value obtained by IMU pre-integration is fused in the hierarchical pose estimation process. The calculation iteration times are reduced, the matching precision of feature points is improved, and the pose of the current frame is solved. Finally, the local map factor, IMU factor and key frame factor are inserted into the factor graph to optimize and constrain the pose. The key frame is matched with the local map, and the map construction is realized through an octree structure. In order to verify the positioning performance and mapping effect of the proposed method, the experimental platforms of Autolabor, VLP-16 LiDAR and Ellipse-N IMU are built. The qualitative and quantitative comparison between the proposed method and LeGO-LOAM and LIO-SAM methods is carried out. The results show the following points. ① In the coal mine roadway environment, the average and median of the absolute positioning error in the three axes direction of the real-time positioning and mapping method based on LiDAR and IMU fusion are less than 32 cm. The position and attitude estimation precision in the X-axis is the highest, with a cumulative error of 1.65 m and a position deviation of 2.97 m. The overall mapping effect is good, and the mapping track does not drift. The point cloud map constructed has excellent performance in integrity and geometric structure authenticity. The map can directly reflect the actual situation of the roadway environment, and has good robustness. This is because hierarchical pose estimation is performed after point cloud matching. The multi-factor optimization can effectively reduce the global cumulative error, which plays an important role in improving track precision and map consistency. ② In the corridor environment, the three-axis error of the real-time positioning and mapping method based on LiDAR and IMU fusion for the coal mine roadway environment is less than 1.01 m. The average error is 5~15 cm, with small error range and high precision. The accumulated position deviation is only 1.67 m. Integrity and environment matching have good performance. This is because by adding keyframe factors and inserting factor graphs to optimize the related variables of the newly added nodes, the drift of pose estimation is reduced. The positioning and mapping precision is relatively high.
    • FullText(HTML)
    • References (22)
  • [1]
    文虎,刘洋,郑学召,等. 矿山救援机器人群设计[J]. 工矿自动化,2019,45(9):34-39. DOI: 10.13272/j.issn.1671-251x.17476

    WEN Hu,LIU Yang,ZHENG Xuezhao,et al. Design of mine rescue robot group[J]. Industry and Mine Automation,2019,45(9):34-39. DOI: 10.13272/j.issn.1671-251x.17476
    [2]
    翟国栋,任聪,王帅,等. 多尺度特征融合的煤矿救援机器人目标检测模型[J]. 工矿自动化,2020,46(11):54-58. DOI: 10.13272/j.issn.1671-251x.2020050033

    ZHAI Guodong,REN Cong,WANG Shuai,et al. Object detection model of coal mine rescue robot based on multi-scale feature fusion[J]. Industry and Mine Automation,2020,46(11):54-58. DOI: 10.13272/j.issn.1671-251x.2020050033
    [3]
    孙金礼,陈杰. 煤矿井下巷道贯通测量精度分析及技术方法[J]. 煤炭科学技术,2010,38(6):112-114,66. DOI: 10.13199/j.cst.2010.06.72.sunjl.025

    SUN Jinli,CHEN Jie. Analysis and technical method of linkage survey accruacy for underground mine roadway[J]. Coal Science and Technology,2010,38(6):112-114,66. DOI: 10.13199/j.cst.2010.06.72.sunjl.025
    [4]
    胡建胜. 煤矿全站仪导线测量误差分析及技术措施研究[J]. 能源技术与管理,2018,43(4):170-172. DOI: 10.3969/j.issn.1672-9943.2018.04.070

    HU Jiansheng. Study on error analysis and technical measures of total station traverse measurement in coal mine[J]. Energy Technology and Management,2018,43(4):170-172. DOI: 10.3969/j.issn.1672-9943.2018.04.070
    [5]
    LI D,YAO Yuan,SHAO Zhenfeng,et al. From digital earth to smart earth[J]. Chinese Science Bulletin,2014,59(8):722-733. DOI: 10.1007/s11434-013-0100-x
    [6]
    蒋萍. LiDAR/IMU组合导航定位算法研究[D]. 南昌: 南昌大学, 2021.

    JIANG Ping. Research on LiDAR/IMU integrated navigation and positioning algorithm[D]. Nanchang: Nanchang University, 2021.
    [7]
    CHEN Chi,YANG Bisheng,TIAN Mao,et al. Automatic registration of vehicle-borne mobile mapping laser point cloud and sequent panoramas[J]. Acta Geodaetica et Cartographica Sinica,2018,47(2):215.
    [8]
    陈先中,刘荣杰,张森,等. 煤矿地下毫米波雷达点云成像与环境地图导航研究进展[J]. 煤炭学报,2020,45(6):2182-2192. DOI: 10.13225/j.cnki.jccs.zn20.0316

    CHEN Xianzhong,LIU Rongjie,ZHANG Sen,et al. Development of millimeter wave radar imaging and SLAM in underground coal mine environment[J]. Journal of China Coal Society,2020,45(6):2182-2192. DOI: 10.13225/j.cnki.jccs.zn20.0316
    [9]
    DEBEUNNE C,VIVET D. A review of visual-LiDAR fusion based simultaneous localization and mapping[J]. Sensors(Basel,Switzerland),2020,20(7):2068.
    [10]
    CADENA C,CARLONE L,CARRILLO H,et al. Past,present,and future of simultaneous localization and mapping:toward the robust-perception age[J]. IEEE Transactions on Robotics,2016,32(6):1309-1332. DOI: 10.1109/TRO.2016.2624754
    [11]
    种一帆,冀杰,宫铭钱,等. 半直接法与IMU融合的双目视觉里程计[J]. 西南师范大学学报(自然科学版),2021,46(2):112-120.

    CHONG Yifan,JI Jie,GONG Mingqian,et al. A stereo visual odometry aided by IMU based on semi-direct method[J]. Journal of Southwest China Normal University(Natural Science Edition),2021,46(2):112-120.
    [12]
    ZHANG Ji,SINGH S. Low-drift and real-time lidar odometry and mapping[J]. Autonomous Robots,2017,41(2):401-416. DOI: 10.1007/s10514-016-9548-2
    [13]
    周治国,曹江微,邸顺帆. 3D激光雷达SLAM算法综述[J]. 仪器仪表学报,2021,42(9):13-27. DOI: 10.19650/j.cnki.cjsi.J2107897

    ZHOU Zhiguo,CAO Jiangwei,DI Shunfan. Overview of 3D Lidar SLAM algorithms[J]. Chinese Journal of Scientific Instrument,2021,42(9):13-27. DOI: 10.19650/j.cnki.cjsi.J2107897
    [14]
    SHAN T X, ENGLOT B, MEYERS D, et al. LIO-SAM: tightly-coupled lidar inertial odometry via smoothing and mapping[C]. IEEE/RSJ International Conference on Intelligent Robots and Systems(IROS), Las Vegas, 2021: 5135-5142.
    [15]
    HEMANN G, SINGH S, KAESS M. Long-range GPS-denied aerial inertial navigation with LIDAR localization[C]. IEEE/RSJ International Conference on Inetlligent Robots & Systems, Daejeon, 2016: 1659-1666.
    [16]
    YE Haoyang, CHEN Yuying, LIU Ming, et al. Tightly coupled 3d lidar inertial odometry and mapping[C]. International Conference on Robotics and Automation(ICRA), Montreal, 2019: 3144-3150.
    [17]
    GENTIL C L,VIDAL-CALLLEJJA T,HUANG Shoudong. IN2LAAMA:inertial lidar localization autocalibration and mapping[J]. IEEE Transactions on Robotics,2021,37(1):275-290. DOI: 10.1109/TRO.2020.3018641
    [18]
    KULKARNI M, DHARMADHIKARI M, TRANZATTO M, et al. Autonomous teamed exploration of subterranean environments using legged and aerial robots[C]. International Conference on Robotics and Automatioan(ICRA), Philadelphia, 2022: 3306-3313.
    [19]
    FRANK N, TILMAN K, ROBERT K, et al. Mc2SLAM: real-time inertial lidar odometry using two-scan motion compensation[C]. German Conference on Pattern Recognition, Cham, 2018: 60-72.
    [20]
    REN Zhuli,WANG Liguan,BI Lin. Robust GICP-based 3D LiDAR SLAM for underground mining environment[J]. Sensors (Basel Switzerland),2019,19(13):2915. DOI: 10.3390/s19132915
    [21]
    SHAN Tixiao, ENGLOT B. LeGO-LOAM: lightweight and ground-optimized lidar odometry and mapping on variable terrain[C]. IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Madrid, 2019: 4758-4765.
    [22]
    ZHAO Yue,ZHANG Jian,FU Chiwing,et al. KD-Box:line-segment-based KD-tree for interactive exploration of large-scale time-series data[J]. IEEE Transactions on Visualization and Computer Graphics,2021,28(1):890-900.
    • Related Articles

  • Related Articles

    [1]MA Liang, GAO Liang, LIAN Boxiang, ZHANG Qi, LIN Xiaohu, JIANG Zhiyue. High-precision 3D point cloud modeling method for coal mine roadways based on known point constraints[J]. Journal of Mine Automation, 2024, 50(11): 78-83, 151. DOI: 10.13272/j.issn.1671-251x.2024080093
    [2]CUI Shaoyun, BAO Jiusheng, HU Deping, YUAN Xiaoming, ZHANG Kekun, YIN Yan, WANG Maosen, ZHU Chenzhong. Research status and development trends of SLAM technology in autonomous mining field[J]. Journal of Mine Automation, 2024, 50(10): 38-52. DOI: 10.13272/j.issn.1671-251x.2024070010
    [3]HU Qingsong, LI Jingwen, ZHANG Yuansheng, LI Shiyin, SUN Yanjing. IMU-LiDAR integrated SLAM technology for unmanned driving in mines[J]. Journal of Mine Automation, 2024, 50(10): 21-28. DOI: 10.13272/j.issn.1671-251x.18209
    [4]MA Aiqiang, YAO Wanqiang. Multi sensor adaptive fusion SLAM method for underground mobile robots in coal mines[J]. Journal of Mine Automation, 2024, 50(5): 107-117. DOI: 10.13272/j.issn.1671-251x.2024050031
    [5]REN Wei. A fully mechanized working face inspection system based on SLAM and virtual reality[J]. Journal of Mine Automation, 2023, 49(5): 59-65. DOI: 10.13272/j.issn.1671-251x.18076
    [6]LI Menggang, HU Eryi, ZHU Hua. LiDAR/IMU tightly-coupled SLAM method for coal mine mobile robot[J]. Journal of Mine Automation, 2022, 48(12): 68-78. DOI: 10.13272/j.issn.1671-251x.2022100061
    [7]ZOU Xiaoyu, HUANG Xinmiao, WANG Zhongbin, FANG Dongsheng, PAN Jie, SI Lei. 3D map construction of coal mine roadway mobile robot based on integrated factor graph optimization[J]. Journal of Mine Automation, 2022, 48(12): 57-67, 92. DOI: 10.13272/j.issn.1671-251x.2022100041
    [8]QI Yuhao, GUAN Shiyuan. Real-time 3D mapping method of fully mechanized working face based on laser SLAM[J]. Journal of Mine Automation, 2022, 48(11): 139-144. DOI: 10.13272/j.issn.1671-251x.2022060047
    [9]WANG Xuqi. Influence of shape factor of rectangular roadway on electromagnetic waves under high-order mode[J]. Journal of Mine Automation, 2019, 45(5): 68-72. DOI: 10.13272/j.issn.1671-251x.2018100062
    [10]LV Gang, LI Yu-dong, JIAO Liu-cheng. Application of Two-mode Fuzzy Controller with Self-organizing and Self-regulating Factor in PMLSM Precise Servo-system[J]. Journal of Mine Automation, 2004, 30(2): 1-4.

  • Cited by

    Periodical cited type(11)

    1. 马庆禄,汪军豪,张杰,邹政. 激光雷达与惯性测量单元同步融合下的园区三维建图. 光学精密工程. 2024(03): 422-434 .
    2. 周波,唐桂彬. 基于遥感GIS信息融合的测绘机器人滑模跟踪控制系统. 计算机测量与控制. 2024(06): 125-132 .
    3. 高毅楠,姚顽强,蔺小虎,郑俊良,马柏林,冯玮,高康洲. 煤矿井下多重约束的视觉SLAM关键帧选取方法. 煤炭学报. 2024(S1): 472-482 .
    4. 倪志平,卢光云. 激光雷达实时采集数据的车辆智能定位方法研究. 激光杂志. 2024(09): 218-222 .
    5. 覃学宁,钟辉,岳志伟,何瑞冠,冷泉,李飞. 基于轨迹重构与贝叶斯推理的空中机器人灯塔距离测绘技术. 计算机测量与控制. 2024(10): 291-297 .
    6. 胡青松,李敬雯,张元生,李世银,孙彦景. 面向矿井无人驾驶的IMU与激光雷达融合SLAM技术. 工矿自动化. 2024(10): 21-28 . 本站查看
    7. 马亮,高亮,廉博翔,张琦,蔺小虎,姜之跃. 基于已知点约束的高精度煤矿巷道三维点云建模方法. 工矿自动化. 2024(11): 78-83+151 . 本站查看
    8. 马宏伟,苏浩,薛旭升,李超,郭逸风,王星,周文剑,崔闻达,喻祖坤,成佳帅. 煤矿井下移动机器人激光标靶定位方法研究. 煤炭科学技术. 2024(11): 60-73 .
    9. 景宁波,马宪民,郭卫,秦学斌. 改进动态半径的矿井激光雷达点云滤波算法. 西安科技大学学报. 2023(02): 406-413 .
    10. 高海跃,王凯,王保兵,王丹丹. 基于全局点云地图的煤矿井下无人机定位方法. 工矿自动化. 2023(08): 81-87+133 . 本站查看
    11. 王媛媛. 基于多传感信息融合的学前教育机器人导航定位研究. 自动化与仪器仪表. 2023(09): 233-236 .

    Other cited types(1)

Catalog

    Get Citation
    PDF
    XML

    Article Metrics

    Article views (354) PDF downloads (64) Cited by(12)
    Related

    苏ICP备 05016349号-2

    Supported by: Beijing Renhe Information Technology Co., Ltd.Visits:1157052    Baidu Analytics

    /

    DownLoad:  Full-Size Img  PowerPoint
    Return
    Return