Title :
Modeling and LPV flight control of the Canard Rotor/ Wing unmanned aerial vehicle
Author :
Gai, Wendong ; Wang, Honglun ; Guo, Tengfei ; Li, Dawei
Author_Institution :
Sci. & Technol. on Aircraft Control Lab., Beijing Univ. of Aeronaut. & Astronaut., Beijing, China
Abstract :
The concept, known as the Canard Rotor/Wing (CRW) unmanned aerial vehicle (UAV) combines the hover flight characteristic of a helicopter with high subsonic cruise of a fixed-wing aircraft. The longitudinal flight dynamic model of CRW was developed, and the trim result was derived in the full flight envelope. The linear model of CRW was derived by the Jacobian linear method, and it was nonlinearly dependent on the time-varying flight speed and altitude. The tensor-product (TP) model transformation was adopted to transform the model to a convex polytopic model form. Hence, a linear parameter-varying (LPV) synthesis method was used to design the flight control system of CRW in the rotary mode. The simulation results show that the desired performance objectives are achieved in the rotary flight stage.
Keywords :
aerospace components; aircraft control; control system synthesis; helicopters; remotely operated vehicles; rotors; tensors; time-varying systems; velocity control; Canard rotor; Jacobian linear method; LPV synthesis method; convex polytopic model; flight control system; helicopter; hover flight; linear parameter varying; longitudinal flight dynamic model; subsonic cruise; tensor product transformation; time-varying altitude; time-varying flight speed; unmanned aerial vehicle; wing aircraft; Aerodynamics; Aerospace control; Aircraft; Atmospheric modeling; Force; Rotors; Vehicle dynamics; Canard Rotor/Wing UAV; linear parameter-varying systemg; tensor-product transformation;
Conference_Titel :
Artificial Intelligence, Management Science and Electronic Commerce (AIMSEC), 2011 2nd International Conference on
Conference_Location :
Deng Leng
Print_ISBN :
978-1-4577-0535-9
DOI :
10.1109/AIMSEC.2011.6011121
