Learning autonomous behaviours for non-holonomic vehicles

被引:0
|
作者
Martinez-Marin, Tomas [1 ]
机构
[1] Univ Alicante, Dept Phys Syst Eng & Signal Theory, Alicante, Spain
来源
COMPUTATIONAL AND AMBIENT INTELLIGENCE | 2007年 / 4507卷
关键词
reinforcement learning; optimal motion planning; cell-to-cell mapping;
D O I
暂无
中图分类号
TP18 [人工智能理论];
学科分类号
081104 ; 0812 ; 0835 ; 1405 ;
摘要
In this paper we propose a generic approach to acquire navigation skills for nonholonomic vehicles in unknown environments. The algorithm uses reinforcement learning to update both the vehicle model and the optimal behaviour at the same time. After the training phase, the vehicle is able to explore the environment through a wall-following behaviour. The vehicle can also reach any goal position by the virtual wall concept. The method does not require function interpolation to obtain a good approximation to the optimal behaviour. The learning time was only a few minutes to acquire the wall-following behaviour. Both simulation and experimental results are reported to show the satisfactory performance of the method.
引用
收藏
页码:839 / 846
页数:8
相关论文
共 50 条
  • [1] Learning Visual Docking for Non-Holonomic Autonomous Vehicles
    Martinez-Marin, Tomas
    Duckett, Tom
    [J]. 2008 IEEE INTELLIGENT VEHICLES SYMPOSIUM, VOLS 1-3, 2008, : 1002 - +
  • [2] Hybrid Path Planning for Non-Holonomic Autonomous Vehicles: an Experimental Evaluation
    Esposto, Francesco
    Goos, Jorrit
    Teerhuis, Arjan
    Alirezaei, Mohsen
    [J]. 2017 5TH IEEE INTERNATIONAL CONFERENCE ON MODELS AND TECHNOLOGIES FOR INTELLIGENT TRANSPORTATION SYSTEMS (MT-ITS), 2017, : 25 - 30
  • [3] Elliptical trajectories for non-holonomic vehicles
    Bampi, F.
    Scalzo, A.
    Zaccaria, R.
    Zordan, C.
    [J]. 2007 IEEE INTELLIGENT VEHICLES SYMPOSIUM, VOLS 1-3, 2007, : 345 - +
  • [4] An internal model approach to autonomous leader/follower trailing for non-holonomic vehicles
    Chen, Xingping
    Serrani, Andrea
    [J]. INTERNATIONAL JOURNAL OF ROBUST AND NONLINEAR CONTROL, 2006, 16 (14) : 641 - 670
  • [5] Simple fuzzy navigation of autonomous robotic vehicles in a factory floor and issue of non-holonomic constraints
    Kolemishevska-Gugulovska, T
    Icev, ZA
    Stankovski, MJ
    [J]. Soft Computing with Industrial Applications, Vol 17, 2004, 17 : 525 - 530
  • [6] Non-holonomic control II : Non-holonomic quantum devices
    Brion, E
    Akulim, VM
    Comparat, D
    Dumer, I
    Gershkovich, V
    Harel, G
    Kurizki, G
    Mazets, I
    Pillet, P
    [J]. Quantum Informatics 2004, 2004, 5833 : 70 - 79
  • [7] Learning optimal trajectories for non-holonomic systems
    Oriolo, G
    Panzieri, S
    Ulivi, G
    [J]. INTERNATIONAL JOURNAL OF CONTROL, 2000, 73 (10) : 980 - 991
  • [8] Efficient Mixed-Integer Nonlinear Programming for Optimal Motion Planning of Non-holonomic Autonomous Vehicles
    Huang, Qing
    Hu, Jibin
    Zhou, Yanxia
    Chen, Yongdan
    Wei, Chao
    [J]. 2021 7TH INTERNATIONAL CONFERENCE ON ROBOTICS AND ARTIFICIAL INTELLIGENCE, ICRAI 2021, 2021, : 52 - 58
  • [9] Cooperative Pose Control of Non-Holonomic Vehicles Using Synchronization
    Kloock, Maximilian
    Alrifaee, Bassam
    [J]. 2023 IEEE 26TH INTERNATIONAL CONFERENCE ON INTELLIGENT TRANSPORTATION SYSTEMS, ITSC, 2023, : 93 - 99
  • [10] A lightweight formation control methodology for a swarm of non-holonomic vehicles
    Elkaim, Gabriel H.
    Kelbley, Robert J.
    [J]. 2006 IEEE AEROSPACE CONFERENCE, VOLS 1-9, 2006, : 931 - +
12345