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A mobile robot with autonomous climbing and descending of stairs

Published online by Cambridge University Press:  01 March 2009

Pinhas Ben-Tzvi*
Affiliation:
Department of Mechanical and Industrial Engineering, University of Toronto, Canada
Shingo Ito
Affiliation:
Department of Mechanical and Industrial Engineering, University of Toronto, Canada
Andrew A. Goldenberg
Affiliation:
Department of Mechanical and Industrial Engineering, University of Toronto, Canada
*
*Corresponding author. Email: [email protected]

Summary

Mobile robots are used to operate in urban environments, for surveillance, reconnaissance, and inspection, as well as for military operations and in hazardous environments. Some are intended for exploration of only natural terrains, but others also for artificial environments, including stairways. This paper presents a mobile robot design that achieves autonomous climbing and descending of stairs. The robot uses sensors and embedded intelligence to achieve the task. The robot is a reconfigurable tracked mobile robot that has the ability to traverse obstacles by changing its track configuration. Algorithms have been further developed for conditions under which the mobile robot would halt its motion during the climbing process when at risk of flipping over. Technical problems related to the implementation of some of the robot functional attributes are presented, and proposed solutions are validated and experimentally tested. The experiments illustrate the effectiveness of the proposed approach to autonomous climbing and descending of stairs.

Type
Article
Copyright
Copyright © Cambridge University Press 2008

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References

1.Goldenberg, A. A. and Lin, J., “Variable Configuration Articulated Tracked Vehicle,” US Patent Application # 11/196,486, August 4, 2005. Engineering Services Inc. http://www.esit.comGoogle Scholar
2.Liu, J., Wang, Y., Ma, S. and Li, B., “Analysis of Stair-Climbing Ability for a Tracked Reconfigurable Modular Robot,” Proceedings of the 2005 IEEE Int. Workshop on Safety and Rescue Robotics, Kobe, Japan (2005) pp. 3641.Google Scholar
3.Gaston, J., Raahemifar, K. and Hiscocks, P., “A cooperative network of reconfigurable stair-climbing robots,” IEEE Int. Symp on Circuits and Systems (2006) pp. 2553–2556.Google Scholar
4.Stoeter, S. A. and Papanikolopoulos, N., “Autonomous stair-climbing with miniature jumping robots,” IEEE Trans. Syst. Man Cybern.—Part B: Cybern. 35 (2), 313325 (2005).Google Scholar
5.Duan, X., Huang, Q., Rahman, N., Li, J. and Li, Jingtao, “MOBIT, A small Wheel–Track–Leg Mobile Robot,” Proceedings of the 6th Congress on Intelligent Control and Automation, Kos Greece (2006) pp. 91599163.Google Scholar
6.Gweon, D. G. and Kim, H. D., “Development of a mobile robot controlled by three motors for a hostile environment,” Mechatronics 2 (1), 4364 (1992).CrossRefGoogle Scholar
7.Lee, W., Kang, S., Kim, M. and Shin, K., “Rough Terrain Negotiable Mobile Platform with Passively Adaptive Double-Tracks and its Application to Rescue Missions,” International Conference on Robotics and Automation, Barcelona, Spain. (2005) pp. 15911596.Google Scholar
8.Yamauchi, B., “PackBot: A Versatile Platform for Military Robotics,” Proceedings of SPIE–Unmanned Ground Vehicle Technology VI, Orlando, FL (2004) pp. 228–237.Google Scholar
9.Frost, T., Norman, C., Pratt, S. and Yamauchi, B., “Derived Performance Metrics and Measurements Compared to Field Experience for the PackBot,” Proceedings of the 2002 PerMIS Workshop, Gaithersburg, MD, USA (2002) pp. 201208.Google Scholar
10.Xiong, Y. and Matthies, L., “Vision-Guided Autonomous Stair Climbing,” International Conference on Robotics and Automation, San Francisco, CA, USA (2000) pp. 18421847.Google Scholar
11.Martens, J. D. and Newman, W. S., “Stabilization of a Mobile Robot Climbing Stairs,” IEEE International Conference on Robotics and Automation, San Diego, CA, USA. (1994) pp. 25012507.Google Scholar
12.Logosol Homepage, Logosol Inc., http://www.logosolinc.com, October 2007.Google Scholar
13.Lin, J., “Studies on Movement Conditions of Tracked Vehicles with Variable Configuration,” Engeneering Services Inc., October 2004, internal report.Google Scholar
14.Lin, J., “Supplement 1—on “Movement Conditions of Tracked Vehicles,” Engineering Serviced Inc., October 20, 2004, internal report.Google Scholar
15.Lin, J., “Determining the Technology Parameters of LMA-2 Vehicle Based on Static Mechanics Analysis,” Eng. Services Inc., May 2004, internal report.Google Scholar
16.Davis, J. R., “Center of Gravity: How to calculate where it is,” http://www.msgroup.org/TIP106.html, October 2007.Google Scholar
17.MATLAB Signal Processing Toolbox, User's Guide Version 5, MATLAB Help for “pburg” function (Burg Method), The MathWorks.Google Scholar