Title :
An Active Uprighting Mechanism for Flying Robots
Author :
Klaptocz, Adam ; Daler, Ludovic ; Briod, Adrien ; Zufferey, J.C. ; Floreano, Dario
Author_Institution :
Lab. of Intell. Syst., Ecole Polytech. Fed. de Lausanne, Lausanne, Switzerland
Abstract :
Flying robots have unique advantages in the exploration of cluttered environments such as caves or collapsed buildings. Current systems, however, have difficulty in dealing with the large amount of obstacles inherent to such environments. Collisions with obstacles generally result in crashes from which the platform can no longer recover. This paper presents a method to design active uprighting mechanisms for protected rotorcraft-type flying robots that allow them to become upright and subsequently take off again after an otherwise mission-ending collision. This method is demonstrated on a tailsitter flying robot, which is capable of consistently uprighting after falling on its side using a spring-based “leg” and returning to the air to continue its mission.
Keywords :
aerospace robotics; collision avoidance; mobile robots; active uprighting mechanism; caves; cluttered environments; collapsed buildings; mission-ending collision; obstacle collisions; rotorcraft-type flying robots; spring-based leg; tailsitter flying robot; Collision avoidance; Force; Legged locomotion; Robot sensing systems; Springs; Surface morphology;
Journal_Title :
Robotics, IEEE Transactions on
DOI :
10.1109/TRO.2012.2201309
