Reinforcement and Curriculum Learning for Off-Road Navigation of an UGV with a 3D LiDAR

被引:3
|
作者
Sanchez, Manuel [1 ]
Morales, Jesus [1 ]
Martinez, Jorge L. [1 ]
机构
[1] Univ Malaga, Inst Mechatron Engn & Cyber Phys Syst, Malaga 29071, Spain
来源
SENSORS | 2023年 / 23卷 / 06期
关键词
reinforcement learning; off-road navigation; curriculum learning; 3D LiDAR; unmanned ground vehicles; traversability; robotic simulations; AUTONOMOUS NAVIGATION;
D O I
10.3390/s23063239
中图分类号
O65 [分析化学];
学科分类号
070302 ; 081704 ;
摘要
This paper presents the use of deep Reinforcement Learning (RL) for autonomous navigation of an Unmanned Ground Vehicle (UGV) with an onboard three-dimensional (3D) Light Detection and Ranging (LiDAR) sensor in off-road environments. For training, both the robotic simulator Gazebo and the Curriculum Learning paradigm are applied. Furthermore, an Actor-Critic Neural Network (NN) scheme is chosen with a suitable state and a custom reward function. To employ the 3D LiDAR data as part of the input state of the NNs, a virtual two-dimensional (2D) traversability scanner is developed. The resulting Actor NN has been successfully tested in both real and simulated experiments and favorably compared with a previous reactive navigation approach on the same UGV.
引用
收藏
页数:18
相关论文
共 50 条
  • [41] Active Learning for Testing and Evaluation in Field Robotics: A Case Study in Autonomous, Off-Road Navigation
    Gregory, Jason M.
    Sahu, Daniel
    Lancaster, Eli
    Sanchez, Felix
    Rocks, Trevor
    Kaukeinen, Brian
    Fink, Jonathan
    Gupta, Satyandra K.
    [J]. 2022 IEEE INTERNATIONAL CONFERENCE ON ROBOTICS AND AUTOMATION, ICRA 2022, 2022, : 8217 - 8223
  • [42] Combination of Recurrent Neural Network and Deep Learning for Robot Navigation Task in Off-Road Environment
    Alamiyan-Harandi, Farinaz
    Derhami, Vali
    Jamshidi, Fatemeh
    [J]. ROBOTICA, 2020, 38 (08) : 1450 - 1462
  • [43] Learning Inverse Kinodynamics for Accurate High-Speed Off-Road Navigation on Unstructured Terrain
    Xiao, Xuesu
    Biswas, Joydeep
    Stone, Peter
    [J]. IEEE ROBOTICS AND AUTOMATION LETTERS, 2021, 6 (03): : 6054 - 6060
  • [44] A Reinforcement Learning Enhanced Fuzzy Control for Real-Time Off-Road Traction System
    Vantsevich, Vladimir
    Gorsich, David
    Lozynskyy, Andriy
    Demkiv, Lyubomyr
    Klos, Sviatoslav
    [J]. ADVANCES IN DYNAMICS OF VEHICLES ON ROADS AND TRACKS, IAVSD 2019, 2020, : 1178 - 1188
  • [45] Lidar-based Traversable Region Detection in Off-road Environment
    Liu, Tong
    Liu, Dongyu
    Yang, Yi
    Chen, Zhaowei
    [J]. PROCEEDINGS OF THE 38TH CHINESE CONTROL CONFERENCE (CCC), 2019, : 4548 - 4553
  • [46] LIDAR and stereo combination for traversability assessment of off-road robotic vehicles
    Reina, Giulio
    Milella, Annalisa
    Worst, Rainer
    [J]. ROBOTICA, 2016, 34 (12) : 2823 - 2841
  • [47] LiDAR-based Terrain Recognition in Off-road Mobile Robot
    Wang, Xinao
    Walters, Joseph G.
    [J]. PROCEEDINGS OF THE 33RD INTERNATIONAL TECHNICAL MEETING OF THE SATELLITE DIVISION OF THE INSTITUTE OF NAVIGATION (ION GNSS+ 2020), 2020, : 2590 - 2604
  • [48] Off-Road Lidar Simulation with Data-Driven Terrain Primitives
    Tallavajhula, Abhijeet
    Mericli, Cetin
    Kelly, Alonzo
    [J]. 2018 IEEE INTERNATIONAL CONFERENCE ON ROBOTICS AND AUTOMATION (ICRA), 2018, : 7470 - 7477
  • [49] A tightly coupled LIDAR-IMU SLAM in off-road environment
    Zhang, Zhehua
    Liu, Haiou
    Qi, Jianyong
    Ji, Kaijin
    Xiong, Guangming
    Gong, Jianwei
    [J]. 2019 IEEE INTERNATIONAL CONFERENCE OF VEHICULAR ELECTRONICS AND SAFETY (ICVES 19), 2019,
  • [50] A Multirange Architecture for Collision-Free Off-Road Robot Navigation
    Sermanet, Pierre
    Hadsell, Raia
    Scoffier, Marco
    Grimes, Matt
    Ben, Jan
    Erkan, Ayse
    [J]. JOURNAL OF FIELD ROBOTICS, 2009, 26 (01) : 52 - 87
12345