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http://dx.doi.org/10.7746/jkros.2016.11.4.256

Controlled Flight of Tailless Insect-Like Flapping-Wing Flying-Robot  

Phan, Hoang Vu (Advanced Tech. Fusion, Konkuk University)
Kang, Taesam (Aerospace Information Engineering, Konkuk University)
Park, HoonCheol (Division of Interdisciplinary Studies, Konkuk University)
Publication Information
The Journal of Korea Robotics Society / v.11, no.4, 2016 , pp. 256-261 More about this Journal
Abstract
An insect-like flapping-wing flying-robot should be able to produce flight forces and control moments at the same time only by flapping wings, because there is no control surface at tail just like an insect. In this paper, design principles for the flapping mechanism and control moment generator are briefly explained, characteristics measured force and moment generations of the robot are presented, and finally controlled flight of the flying robot is demonstrated. The present insect-like robot comprises a lightweight flapping mechanism that can produce a flapping angle larger than $180^{\circ}$ and a control moment generator that produces pitch, roll, and yaw moments by adjusting location of the trailing edges at the wing roots. The measured force and moment data show that the control input angles less than $9^{\circ}$ would not significantly reduce the vertical force generation. It is also observed that the pitch, roll, and yaw control moments are produced only by the corresponding control input. The simple PID control theory is used for the controlled flight of the flying robot, controlling pitch, roll, and yaw motions. The flying robot successfully demonstrated controlled flight for about 40 seconds.
Keywords
Insect-like; flapping-wing; control moment generation; PID control; controlled flight;
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  • Reference
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