• DocumentCode
    1895908
  • Title

    Movement imitation with nonlinear dynamical systems in humanoid robots

  • Author

    Ijspeert, Auke Jan ; Nakanishi, Jun ; Schaal, Stefan

  • Author_Institution
    Computational Learning & Motor Control Lab., Univ. of Southern California, Los Angeles, CA, USA
  • Volume
    2
  • fYear
    2002
  • fDate
    2002
  • Firstpage
    1398
  • Lastpage
    1403
  • Abstract
    Presents an approach to movement planning, on-line trajectory modification, and imitation learning by representing movement plans based on a set of nonlinear differential equations with well-defined attractor dynamics. The resultant movement plan remains an autonomous set of nonlinear differential equations that forms a control policy (CP) which is robust to strong external perturbations and that can be modified on-line by additional perceptual variables. We evaluate the system with a humanoid robot simulation and an actual humanoid robot. Experiments are presented for the imitation of three types of movements: reaching movements with one arm, drawing movements of 2-D patterns, and tennis swings. Our results demonstrate (a) that multi-joint human movements can be encoded successfully by the CPs, (b) that a learned movement policy can readily be reused to produce robust trajectories towards different targets, (c) that a policy fitted for one particular target provides a good predictor of human reaching movements towards neighboring targets, and (d) that the parameter space which encodes a policy is suitable for measuring to which extent two trajectories are qualitatively similar
  • Keywords
    learning by example; nonlinear dynamical systems; path planning; robot kinematics; robot programming; stability; attractor dynamics; attractor landscape; control policy; humanoid robots; imitation learning; learning algorithm; locally weighted regression technique; movement imitation; movement planning; movement plans; multi-joint human movements; nonlinear differential equations; nonlinear dynamical systems; online trajectory modification; Biological system modeling; Control systems; Convergence; Encoding; Humanoid robots; Humans; Laboratories; Nonlinear dynamical systems; Robustness; Trajectory;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Robotics and Automation, 2002. Proceedings. ICRA '02. IEEE International Conference on
  • Conference_Location
    Washington, DC
  • Print_ISBN
    0-7803-7272-7
  • Type

    conf

  • DOI
    10.1109/ROBOT.2002.1014739
  • Filename
    1014739