Dynamic modeling and optimal control of a twin rotor MIMO system

Author

Ahmad, S.M. ; Chipperfield, A.J. ; Tokhi, M.O.

Author_Institution

Dept. of Autom Control & Syst. Eng., Sheffield Univ., UK

fYear

2000

fDate

2000

Firstpage

391

Lastpage

398

Abstract

A dynamic model for the characterising of a one-degree-of-freedom (DOF) twin rotor MIMO system (TRMS) in hover is extracted using a black-box system identification technique. The behaviour of the TRMS in certain aspects resembles that of a helicopter. Hence, it is an interesting identification and control problem. Identification for a 1-DOF rigid-body, discrete-time linear model is presented. The extracted model is employed in the design of a feedback LQG compensator. This has a good tracking capability, but requires high control effort and has inadequate authority over residual vibration of the system. These problems are resolved by further augmenting the system with a command path prefilter. The combined feedforward and feedback compensator satisfies the performance objectives and obeys the actuator constraint

Keywords

MIMO systems; aircraft control; compensation; feedback; feedforward; helicopters; identification; linear quadratic Gaussian control; optimal control; actuator; black-box system identification; command path prefilter; dynamic model; feedback LQG compensator; feedforward compensator; helicopter; hovering; one-degree-of-freedom rigid-body discrete-time linear model; optimal control; residual vibration; tracking; twin rotor MIMO system; Aerospace control; Aircraft; Control systems; Helicopters; Laboratories; MIMO; Optimal control; Rotors; Transmission line measurements; Unmanned aerial vehicles;

fLanguage

English

Publisher

ieee

Conference_Titel

National Aerospace and Electronics Conference, 2000. NAECON 2000. Proceedings of the IEEE 2000

Conference_Location

Dayton, OH

Print_ISBN

0-7803-6262-4

Type

conf

DOI

10.1109/NAECON.2000.894937

Filename

894937