Title :
Tip-over prevention: Adaptive control development and experimentation
Author :
Kelley, Leah ; Talke, Kurt ; Longhini, Patrick ; Catron, Garret
Abstract :
Skid-steered, tracked, tele-operated robots are used to perform high-risk critical missions such as bomb disposal under conditions deemed too risky to send a human. Often the robots carry heavy payloads that raise their centers of mass, increasing the risk of tip-over. Since it is often not feasible to send a human to right a toppled robot, tip-over is equivalent to mission failure. Hence, an autonomous behavior to prevent robot tip-over is desired. In this research, a simplified model of mobile robot dynamics permits separation of pitch and roll stabilization. Adaptive control is used to stabilize the appropriate angle based on the normalized tip-over measure. Experimental validation of this control is successfully demonstrated on an iRobot Packbot and a Segway RMP 440.
Keywords :
adaptive control; mobile robots; robot dynamics; stability; Segway RMP 440; adaptive control development; autonomous behavior; iRobot packbot; mobile robot dynamics; normalized tip-over measure; pitch stabilization; roll stabilization; skid-steered robots; teleoperated robots; tip-over prevention; tracked robots; Adaptation models; Adaptive control; Force; Friction; Robot kinematics; Robot sensing systems;
Conference_Titel :
Robotics and Automation (ICRA), 2015 IEEE International Conference on
Conference_Location :
Seattle, WA
DOI :
10.1109/ICRA.2015.7139802
