Title :
Biomimetic measurement of optical flow and centroid for visual-servo control of hover flight
Author :
Crnko, P. ; Capson, David
Author_Institution :
Dept. of Electr. & Comptuer Eng., McMaster Univ., Hamilton, ON, Canada
Abstract :
This paper presents a novel, biomimetic design of a visual sensor and visual servo system for a micro-RUAV, based on a study of the hybrid controls approach used by Macroglossum Stel. L. for pure 2-D hover stabilization. The sensor approach determines ego-motion in the Yaw axis through use of an optic flow estimator on a peripheral ring about a foveal region centered on a target. A centroid measure of the target is used to govern remaining degrees of freedom. The biomimetic controller builds upon locomotor studies and uses a PID control to govern error corrections for each separate axis. In turn, the corrective motions of each axis are combined through a thrust matrix, which projects the desired thrust on a series of pre-learned signals in cardinal directions about the RUAV. Experimental implementation and results are discussed.
Keywords :
autonomous aerial vehicles; biomimetics; helicopters; image sequences; intelligent control; learning (artificial intelligence); motion control; servomechanisms; stability; three-term control; visual servoing; 2D hover stabilization; PID control; Yaw axis; biomimetic controller; biomimetic measurement; cardinal directions; centroid; ego-motion determination; foveal region; hover flight; hybrid control; microRUAV; optic flow estimator; optical flow; peripheral ring; prelearned signal; visual sensor; visual servo system; visual-servo control; Adaptive optics; Biomedical optical imaging; Insects; Optical feedback; Optical imaging; Optical sensors; Visualization;
Conference_Titel :
Instrumentation and Measurement Technology Conference (I2MTC), 2012 IEEE International
Conference_Location :
Graz
Print_ISBN :
978-1-4577-1773-4
DOI :
10.1109/I2MTC.2012.6229676
