Open Access  Subscription or Fee Access

In this paper a complete system is designed and implemented, in which the motion of a quadcopter is stably controlled based on visual feedback and measurements of inertial sensors. We focus on developing a cost effective and easy-to-setup vision system. Active markers were finely designed to improve visibility under various perspectives as well as robustness towards disturbances in the image-based pose estimation. Moreover, position- and heading controllers for the quadcopter were implemented to show the system’s capabilities. The performance of the controllers was further improved by the use of inertial sensors of the quadcopter. A closed-loop control system is successfully conducted.

Vision System, Motion Estimation, Multiple Sensing System, UAV/MAV Control.

P. Pounds, R. Mahony, J. Gresham, P. Corke, and J. Roberts, “Towards dynamically-favourable quad-rotor aerial robots,” in Australian Conference on Robotics and Automation,, 2004.

D. Gurdan, J. Stumpf, M. Achtelik, K.-M. Doth, G. Hirzinger, and D. Rus, “Energy-efficient autonomous four-rotor flying robot controlled at 1 khz,” in IEEE International Conference on Robotics and Automation, Roma, Italy, Apr. 2007, pp. 361 – 366.

C. Lu, G. D. Hager, and E. Mjolsness, “Fast and globally convergent pose estimation from video images,” IEEE Transactions on Pattern Analysis and Machine Intelligence, vol. 22, pp. 610–622, 2000.

R. Laganiere, S. Gilbert, and G. Roth, “Robust object pose estimation from feature-based stereo,” IEEE Transactions on Instrumentation and Measurement. Volume 55, Number 4. August 2006., vol. 55, pp. 1270– 1280, 2006.

E. Altug, J. P. Ostrowski, and C. J. Taylor, “Control of a quadrotor helicopter using dual cameravisual feedback,” The International Journal of Robotics Research, vol. 24, pp. 329–341, 2005.