Multi-timescale SDRE control for an unmanned helicopter

Author

Guo, Runxia ; Wu, Aiguo ; Chen, Jiusheng

Volume

1

fYear

2010

fDate

27-29 March 2010

Firstpage

516

Lastpage

520

Abstract

This paper proposes an improved state-dependent Riccati equation (SDRE) attitude control approach which is applied to an unmanned helicopter (UMH) through a multi-timescale structure. To deal with inherent unstable internal dynamics, the flapping and rotational dynamics of the helicopter are organized into a two-timescale nonlinear model. To overcome the problem that a number of terms can´t be accounted in the SDRE design, we employ a nonlinear feedforward compensator that is designed to match the vehicle response to the model used in the SDRE design. To overcome the feedforward compensator´s disadvantage of being directly affected by parametric disturbances, we improve the design method and add a proportion+ integral (PI) controller. SDRE is solved by “θ - D” method. The simulation results show satisfactory tracking performance of the designed control system.

Keywords

MIMO systems; attitude control; feedforward; helicopters; mobile robots; nonlinear control systems; remotely operated vehicles; robot dynamics; PI controller; attitude control; flapping dynamics; multitimescale SDRE control; nonlinear feedforward compensator; rotational dynamics; state-dependent Riccati equation; two-timescale nonlinear model; unmanned helicopter; Aerodynamics; Automatic control; Automation; Design methodology; Helicopters; MIMO; Nonlinear equations; Riccati equations; Stability; Vehicle dynamics; improved feedforward compensator; multi-timescale model; nonlinear control; state-dependent Riccati equation (SDRE); unmanned helicopter (UMH);

fLanguage

English

Publisher

ieee

Conference_Titel

Advanced Computer Control (ICACC), 2010 2nd International Conference on

Conference_Location

Shenyang

Print_ISBN

978-1-4244-5845-5

Type

conf

DOI

10.1109/ICACC.2010.5487158

Filename

5487158