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Towards applicable ballistic walking.

R Q van der Linde1

  • 1Delft University of Technology, Man-Machine Systems and Control Group, Faculty of Design, Engineering and Production, The Netherlands. R.Q.vanderLinde@wbmt.tudelft.nl

Technology and Health Care : Official Journal of the European Society for Engineering and Medicine
|February 9, 2000
PubMed
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Passive bipedal walking with phasic muscle contraction.

Biological cyberneticsยท1999
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Ballistic walking, a self-organizing locomotion, is enhanced with variable parameters for energy input and disturbance control. This research aims to make ballistic walking more robust and applicable in robotics and rehabilitation.

Area of Science:

  • Biomechanics
  • Robotics
  • Control Theory

Background:

  • Ballistic walking offers advantages like self-organization, energy efficiency, and natural movement.
  • A key limitation is the lack of explicit actuation, hindering control and robustness.
  • Existing ballistic walking models often lack mechanisms for active energy input or disturbance rejection.

Purpose of the Study:

  • To extend ballistic walking by incorporating variable intrinsic system parameters.
  • To enable energy input and disturbance control within the ballistic walking framework.
  • To develop a robust and applicable model for ballistic walking in robotics and rehabilitation.

Main Methods:

  • Utilized a limit cycle approach to synthesize walking cycles.
  • Designed controllers for managing cycle dynamics.

Related Experiment Videos

  • Integrated variable intrinsic system parameters for energy input and control.
  • Conducted experiments with a bipedal robot and simulations.
  • Main Results:

    • Demonstrated the synthesis of walking cycles using the limit cycle approach.
    • Successfully designed controllers for managing walking dynamics.
    • Showcased the effectiveness of variable parameters for energy input and disturbance control.
    • Validated the enhanced ballistic walking model through simulations and robotic experiments.

    Conclusions:

    • The integration of variable intrinsic parameters significantly enhances ballistic walking.
    • The developed approach leads to more robust and applicable ballistic locomotion.
    • This research paves the way for advanced robotic applications and improved rehabilitation strategies.