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Autonomous Motion Conference Paper 2010

Fast, robust quadruped locomotion over challenging terrain

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Autonomous Motion
Stefan Schaal
  • Director
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Autonomous Motion
Mrinal Kalakrishnan
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Autonomous Motion
Peter Pastor

We present a control architecture for fast quadruped locomotion over rough terrain. We approach the problem by decomposing it into many sub-systems, in which we apply state-of-the-art learning, planning, optimization and control techniques to achieve robust, fast locomotion. Unique features of our control strategy include: (1) a system that learns optimal foothold choices from expert demonstration using terrain templates, (2) a body trajectory optimizer based on the Zero-Moment Point (ZMP) stability criterion, and (3) a floating-base inverse dynamics controller that, in conjunction with force control, allows for robust, compliant locomotion over unperceived obstacles. We evaluate the performance of our controller by testing it on the LittleDog quadruped robot, over a wide variety of rough terrain of varying difficulty levels. We demonstrate the generalization ability of this controller by presenting test results from an independent external test team on terrains that have never been shown to us.

Author(s): Kalakrishnan, M. and Buchli, J. and Pastor, P. and Mistry, M. and Schaal, S.
Book Title: Robotics and Automation (ICRA), 2010 IEEE International Conference on
Pages: 2665-2670
Year: 2010
Month: May
Day: 3-7
Bibtex Type: Conference Paper (inproceedings)
URL: http://www-clmc.usc.edu/publications/K/kalakrishnan-ICRA2010.pdf
Cross Ref: p10419
Electronic Archiving: grant_archive
ISBN: 1050-4729
Note: clmc

BibTex 

@inproceedings{Kalakrishnan_RAIIC_2010,
  title = {Fast, robust quadruped locomotion over challenging terrain},
  booktitle = {Robotics and Automation (ICRA), 2010 IEEE International Conference on},
  abstract = {We present a control architecture for fast quadruped locomotion over rough terrain. We approach the problem by decomposing it into many sub-systems, in which we apply state-of-the-art learning, planning, optimization and control techniques to achieve robust, fast locomotion. Unique features of our control strategy include: (1) a system that learns optimal foothold choices from expert demonstration using terrain templates, (2) a body trajectory optimizer based on the Zero-Moment Point (ZMP) stability criterion, and (3) a floating-base inverse dynamics controller that, in conjunction with force control, allows for robust, compliant locomotion over unperceived obstacles. We evaluate the performance of our controller by testing it on the LittleDog quadruped robot, over a wide variety of rough terrain of varying difficulty levels. We demonstrate the generalization ability of this controller by presenting test results from an independent external test team on terrains that have never been shown to us.},
  pages = {2665-2670},
  month = may,
  year = {2010},
  note = {clmc},
  slug = {kalakrishnan_raiic_2010},
  author = {Kalakrishnan, M. and Buchli, J. and Pastor, P. and Mistry, M. and Schaal, S.},
  crossref = {p10419},
  url = {http://www-clmc.usc.edu/publications/K/kalakrishnan-ICRA2010.pdf},
  month_numeric = {5}
}