• DocumentCode
    1602788
  • Title

    Co-evolutionary perception-based reinforcement learning for sensor allocation in autonomous vehicles

  • Author

    Berenji, Hamid R. ; Vengerov, David ; Ametha, Jayesh

  • Author_Institution
    Intelligent Inference Syst. Corp., Sunnyvale, CA, USA
  • Volume
    1
  • fYear
    2003
  • Firstpage
    125
  • Abstract
    In this paper we study the problem of sensor allocation in Unmanned Aerial Vehicles (UAVs). Each UAV uses perception-based rules for generalizing decision strategy across similar states and reinforcement learning for adapting these rules to the uncertain, dynamic environment. A big challenge for reinforcement learning algorithms in this problem is that UAVs need to learn two complementary policies: how to allocate their individual sensors to appearing targets and how to distribute themselves as a team in space to match the density and importance of targets underneath. We address this problem using a co-evolutionary approach, where the policies are learned separately, but they use a common reward function. The applicability of our approach to the UAV domain is verified using a high-fidelity robotic simulator. Based on our results, we believe that the co-evolutionary reinforcement learning approach to reducing dimensionality of the action space presented in this paper is general enough to be applicable to many other multi-objective optimization problems, particularly those that involve a tradeoff between individual optimality and team-level optimality.
  • Keywords
    aerospace robotics; fuzzy logic; knowledge based systems; learning (artificial intelligence); mathematical programming; remotely operated vehicles; state-space methods; target tracking; uncertainty handling; appearing targets; autonomous vehicles; coevolutionary perception-based reinforcement learning; common reward function; complementary policies; computational theory of perceptions; decision strategy; fuzzy label; high-fidelity robotic simulator; mathematical programming formulation; multilevel learning; rule-based systems; sensor allocation; state space; team-level optimality; uncertain dynamic environment; unmanned aerial vehicles; Intelligent sensors; Intelligent systems; Intelligent vehicles; Learning; Mobile robots; Remotely operated vehicles; Sensor phenomena and characterization; Target tracking; Unmanned aerial vehicles; Vehicle dynamics;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Fuzzy Systems, 2003. FUZZ '03. The 12th IEEE International Conference on
  • Print_ISBN
    0-7803-7810-5
  • Type

    conf

  • DOI
    10.1109/FUZZ.2003.1209349
  • Filename
    1209349