Title :
Decoupling trajectory tracking for gliding reentry vehicles
Author :
Zixuan Liang ; Zhang Ren ; Xingyue Shao
Author_Institution :
Sci. & Technol. on Aircraft Control Lab., Beihang Univ., Beijing, China
Abstract :
A decoupling trajectory tracking method for gliding reentry vehicles is presented to improve the reliability of the guidance system. Function relations between state variables and control variables are analyzed. To reduce the coupling between control channels, the multiple-input multiple-output (MIMO) tracking system is separated into a series of two single-input single-output (SISO) subsystems. Tracking laws for both velocity and altitude are designed based on the sliding mode control (SMC). The decoupling approach is verified by the Monte Carlo simulations, and compared with the linear quadratic regulator (LQR) approach in some specific conditions. Simulation results indicate that the decoupling approach owns a fast convergence speed and a strong anti-interference ability in the trajectory tracking.
Keywords :
MIMO systems; Monte Carlo methods; aircraft control; linear quadratic control; trajectory control; variable structure systems; LQR approach; MIMO tracking system; Monte Carlo simulations; SISO subsystems; SMC; antiinterference ability; control variables; convergence speed; decoupling trajectory tracking method; function relations; gliding reentry vehicles; guidance system reliability; linear quadratic regulator approach; multiple-input multiple-output tracking system; single-input single-output subsystems; sliding mode control; state variables; Aerodynamics; Earth; MIMO; Mathematical model; Trajectory; Uncertainty; Vehicles; Hypersonic; decoupling control; reentry vehicle; sliding mode control (SMC); trajectory tracking;
Journal_Title :
Automatica Sinica, IEEE/CAA Journal of
DOI :
10.1109/JAS.2015.7032913
