An Indoor Flying Platform with Collision Robustness and Self-Recovery

• Presented at: 2010 IEEE International Conference on Robotics and Automation (ICRA 2010), Anchorage, Alaska, US, May 3-8, 2010
• Published in: Proceedings of the IEEE International Conference on Robotics and Automation (ICRA)
• IEEE, 2010

This paper presents a new paradigm in the design of indoor flying robots that replaces collision avoidance with collision robustness. Indoor flying robots must operate within constrained and cluttered environments where even nature’s most sophisticated flyers such as insects cannot avoid all obsta- cles and should thus be able to withstand collisions and recover from them autonomously. A prototype platform specifically designed to withstand collisions and recover without human intervention is presented. An optimization algorithm used for its dimensioning is proposed followed by new construction techniques focusing on shock absorption. Finally, the platform is tested both in-flight and during collisions to characterize its collision robustness and self- recovery capability.

Note: airburr

Keywords: aerospace robotics ; collision avoidance ; mobile robots ; self-adjusting systems ; aerodynamics ; collision robustness ; indoor flying robot ; self-recovery capability ; shock absorption

Reference

• LIS-CONF-2010-001
• doi:10.1109/ROBOT.2010.5509338
• View record in Web of Science

• URL: http://icra2010.grasp.upenn.edu/

Record created on 2010-01-04, modified on 2012-03-20