Parallel evolutionary optimized pitching motion control for F-16 aircraft

Author

Lee, Kang-Hee ; Kim, Jong-Hwan

Author_Institution

Dept. of EECS, Korea Adv. Inst. of Sci. & Technol., Daejon, South Korea

Volume

2

fYear

2003

fDate

8-12 Dec. 2003

Firstpage

1199

Abstract

The stability augmentation system (SAS) is designed to improve the stability while parallel evolutionary optimization based on Lagrangian II (PEvolian II) is successfully applied to satisfy several constraints and to minimize the rising time. A controller to stabilize F-16 aircraft flying with a steady state around the altitude of 25,000 ft is described. The nonlinear pitching motion model of F-16 is linearized in the range of the flight envelope of velocity vs. altitude. Then applying feedback linearization stabilizes the statically unstable system. As the gain-scheduling method is introduced at various operating points within the flight envelope, the optimized controller is designed all over the envelope. parallel evolutionary optimization based on Lagrangian II is used to optimize the proportional and integral gains of the controller, satisfying complex nonlinear constraints.

Keywords

PI control; aircraft control; constraint theory; control nonlinearities; evolutionary computation; feedback; minimisation; motion control; F-16 aircraft; Lagrangian II; constraints satisfaction; control nonlinearities; gain-scheduling method; optimized controller design; parallel evolutionary optimized pitching motion control; rising time minimization; stability augmentation system; Aerospace control; Aircraft; Constraint optimization; Design optimization; Lagrangian functions; Motion control; Pi control; Proportional control; Stability; Synthetic aperture sonar;

fLanguage

English

Publisher

ieee

Conference_Titel

Evolutionary Computation, 2003. CEC '03. The 2003 Congress on

Print_ISBN

0-7803-7804-0

Type

conf

DOI

10.1109/CEC.2003.1299805

Filename

1299805