Title :
Design, model and attitude control of a model-scaled gyroplane
Author :
Qing Lin ; Zhihao Cai ; Yingxun Wang
Author_Institution :
Sch. of Autom. Sci. & Electr. Eng., Beihang Univ., Beijing, China
Abstract :
Autogyro or gyroplane as the first rotorcraft and a type of classical V/STOL aerial vehicle has become a hot point in academia and industry. Progresses have been achieved in many research areas such as aerodynamics, structure, flight dynamics, modeling identification. But a sparse contemporary research on autogyro emphasizes the control of autogyro/gyroplane. Our motivation is to design an autopilot for an unmanned gyroplane. First, the unmanned gyroplane was designed based on an advanced radio-controlled gyroplane and the PX4 open-source flight management unit. Then, dynamics model was obtained through the CFD and aerodynamic estimation method. A fly-to-trim method was used to trim the aircraft and stability characteristics were analyzed at different speeds. Finally, the attitude controller was designed with incremental nonlinear dynamic inversion method.
Keywords :
aerodynamics; aircraft control; attitude control; autonomous aerial vehicles; computational fluid dynamics; control system synthesis; helicopters; nonlinear dynamical systems; stability; vehicle dynamics; CFD; PX4 open-source flight management unit; V/STOL aerial vehicle; advanced radio-controlled gyroplane; aerodynamic estimation method; attitude controller; autogyro; autopilot design; computational fluid dynamics; dynamics model; fly-to-trim method; incremental nonlinear dynamic inversion method; model-scaled gyroplane; rotorcraft; stability characteristics; unmanned gyroplane; vertical/short takeoff and landing aircraft; Aerodynamics; Aerospace electronics; Atmospheric modeling; Rotors; Stability analysis; Vectors; Vehicle dynamics;
Conference_Titel :
Guidance, Navigation and Control Conference (CGNCC), 2014 IEEE Chinese
Conference_Location :
Yantai
Print_ISBN :
978-1-4799-4700-3
DOI :
10.1109/CGNCC.2014.7007385
