Abstract | ||
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The approximation of a humanoid robot by an inverted pendulum is one of the most frequently used models to generate a stable walking pattern using a planned zero moment point (ZMP) trajectory. However, on account of the difference between the multibody model of the humanoid robot and the simple inverted pendulum model, the ZMP error might be bigger than the polygon of support and the robot falls down. To overcome this limitation, we propose to improve the accuracy of the inverted pendulum model using system identification techniques. The candidate model is a quadratic in the state space representation. To identify this system, we propose an identification method that is the result of the comprehensive application of system identification to dynamic systems. Based on the quadratic system, we also propose controlling algorithms for on-line and off-line walking pattern generation for humanoid robots. The efficiency of the quadratic system and the walking pattern generation methods has been successfully shown using dynamical simulation and conducting real experiments on the cybernetic human HRP-4C. (C) Koninklijke Brill NV, Leiden and The Robotics Society of Japan, 2011 |
Year | DOI | Venue |
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2011 | 10.1163/016918610X551773 | ADVANCED ROBOTICS |
Keywords | Field | DocType |
Humanoid robot,zero moment point control,system identification,optimization,nonlinear system control | Inverted pendulum,Control theory,State-space representation,Control engineering,Zero moment point,Artificial intelligence,Engineering,System identification,Robot,Robotics,Dynamical system,Humanoid robot | Journal |
Volume | Issue | ISSN |
25 | SP3-4 | 0169-1864 |
Citations | PageRank | References |
5 | 0.60 | 10 |
Authors | ||
4 |
Name | Order | Citations | PageRank |
---|---|---|---|
Wael Suleiman | 1 | 55 | 9.46 |
Fumio KANEHIRO | 2 | 2304 | 204.18 |
Kanako Miura | 3 | 208 | 14.99 |
Eiichi Yoshida | 4 | 522 | 59.13 |