Title :
Robust control design based on sliding mode control for hover flight of a mini tail-sitter Unmanned Aerial Vehicle
Author :
Guerrero, J.A. ; Lozano, R. ; Romero, G. ; Lara-Alabazares, D. ; Wong, K.C.
Author_Institution :
HEUDIASYC, Univ. de Compiegne, Compiegne, France
Abstract :
In this paper, the modeling and robust control design of a vertical flight attitude control for a mini tail-sitter with variable pitch propeller is discussed. Tail-sitters vertical take-off and landing - unmanned aerial vehicles (VTOL-UAVs) have the operational flexibility of a typical helicopter while having the cruise performance of a fixed wing airplanes. The VTOL-UAVs configuration used in this paper is highly unstable in its natural flight state in vertical mode. First of all, a simplified attitude dynamic model that includes interval parametric uncertainty is obtained; then a control law based in the sliding mode control (SMC) technique is applied to stabilize the decoupled attitude control systems. The results are supported by simulation tests.
Keywords :
aircraft control; attitude control; control system synthesis; helicopters; remotely operated vehicles; variable structure systems; attitude dynamic model; fixed wing airplanes; helicopter; hover flight; mini tail-sitter unmanned aerial vehicle; robust control design; sliding mode control; variable pitch propeller; vertical flight attitude control; Airplanes; Attitude control; Helicopters; Propellers; Robust control; Sliding mode control; Testing; Uncertainty; Unmanned aerial vehicles; Vehicle dynamics; UAV control; parametric uncertainty; robust control; sliding mode control;
Conference_Titel :
Industrial Electronics, 2009. IECON '09. 35th Annual Conference of IEEE
Conference_Location :
Porto
Print_ISBN :
978-1-4244-4648-3
Electronic_ISBN :
1553-572X
DOI :
10.1109/IECON.2009.5415267
