论文信息 - The Embedded On-Board Controller and Ground Monitoring System of a Flapping-Wing Aerial Vehicle

The Embedded On-Board Controller and Ground Monitoring System of a Flapping-Wing Aerial Vehicle

A flapping-wing aerial vehicle (FAV), which imitates the flapping flying of birds and can actively adapt to complex aerodynamic environments. Thus, it has better adaptive capacity compared with traditional aircraft. To fabricate a prototype with excellent performance, the design of on-board avionics and ground monitoring and control system (GCS) is very important, except for good structure and mechanisms. In this paper, we developed the embedded on-board controller and ground monitoring system. The former has high power density and light weight. It collects and processes the multiple sensor data, including the inertial measurement units (IMU) and GPS on real time. Then, the system state, including the position, attitude, linear and angular velocities are generated using an extended Kalman filter. Correspondingly, the flight attitude and direction of the robotic bird are adjusted by the combined motion of the wing and tail driving mechanism. To obtain the inspection data supplied by the flying robotic bird, and monitor its flying status (especially the health and sate status) on real time, a ground operation platform was also developed. The ZigBee wireless communication module was used to establish the link between the on-board controller and the ground platform. Finally, various experiments were conducted. The results showed that the developed on-board controller and ground monitor worked very well.

Wenfu Xu | Juntao Liu | Erzhen Pan | Lianrui Chen

[1] Hoon Cheol Park,et al. Stable vertical takeoff of an insect-mimicking flapping-wing system without guide implementing inherent pitching stability , 2012 .

[2] J. D. Delaurier,et al. THE DEVELOPMENT AND TESTING OF A FULL-SCALE PILOTED ORNITHOPTER , 1999 .

[3] Fumitoshi Matsuno,et al. Development of the Snake-like Rescue Robot. , 2004 .

[4] Fu-Yuen Hsiao,et al. Autopilots for Ultra Lightweight Robotic Birds: Automatic Altitude Control and System Integration of a Sub-10 g Weight Flapping-Wing Micro Air Vehicle , 2012, IEEE Control Systems.

[5] Radhika Nagpal,et al. Flight of the robobees. , 2013, Scientific American.

[6] Kevin Y. Ma,et al. Controlled Flight of a Biologically Inspired, Insect-Scale Robot , 2013, Science.

[7] Satyandra K. Gupta,et al. A Review of Bird-Inspired Flapping Wing Miniature Air Vehicle Designs , 2010 .

[8] Wenfu Xu,et al. A Kind of Large-Sized Flapping Wing Robotic Bird: Design and Experiments , 2017, ICIRA.

[9] Asli Sebatli,et al. Allocation of temporary disaster response facilities under demand uncertainty: An earthquake case study , 2016 .

[10] J. V. Caetano,et al. Tethered vs. free flight force determination of the DelFly II Flapping Wing Micro Air Vehicle , 2014, 2014 International Conference on Unmanned Aircraft Systems (ICUAS).