Title :
Real-time obstacle avoidance using central flow divergence, and peripheral flow
Author :
Coombs, David ; Herman, Martin ; Hong, Tsai-Hong ; Nashman, Marilyn
Author_Institution :
Intelligent Syst. Div., Nat. Inst. of Stand. & Technol., Gaithersburg, MD, USA
fDate :
2/1/1998 12:00:00 AM
Abstract :
The lure of using motion vision as a fundamental element in the perception of space drives this effort to use flow features as the sole cues for robot mobility. Real-time estimates of image flow and flow divergence provide the robot´s sense of space. The robot steers down a conceptual corridor, comparing left and right peripheral flows. Large central flow divergence warns the robot of impending collisions at “dead ends”. When this occurs, the robot turns around and resumes wandering. Behavior is generated by directly using flow-based information in the 2D image sequence. Active mechanical gaze stabilization simplifies the visual interpretation problems by reducing camera rotation. By combining corridor following and dead-end deflection, the robot has wandered around the lab at 30 cm/s for as long as 20 min without collision. The ability to support this behavior in real-time with current equipment promises expanded capabilities as computational power increases in the future
Keywords :
active vision; digital control; feedback; mobile robots; motion estimation; object recognition; path planning; real-time systems; recursive estimation; robot vision; 2D image sequence; active gaze stabilization; active vision; central flow divergence; digital control; feedback; image flow; mobile robot; motion planning; object recognition; obstacle avoidance; peripheral flow; real-time systems; recursive estimation; robot vision; Cameras; Image sequences; Layout; Mobile robots; Orbital robotics; Resumes; Robot kinematics; Robot sensing systems; Robot vision systems; Robustness;
Journal_Title :
Robotics and Automation, IEEE Transactions on
