Attitude control of a 3-axis stabilized satellite using adaptive control algorithm

Author

Shankararaman, Ramakrishnan ; Lourde, R.M.

Author_Institution

Dept. of Electr. & Electron. Eng., Birla Inst. of Technol. & Sci., Pilani

fYear

2006

fDate

24-26 April 2006

Abstract

In designing the attitude determination and control system (ADCS) of a satellite, the system cannot be modeled as a dimensionless point object. A practical object has physical size and thus rotates as well as translates. Such bodies are termed rigid bodies. Its dynamics is characterized by six degrees of freedom. Three degrees of freedom represent the motion of the center of mass. The other three degrees address the rotational motion of the object. The 6-DoF must be dynamically controlled. Traditionally, attitude determination involved using both rate gyros and star trackers. Rate gyros are prone to mechanical failure. Hence it is proposed to study the feasibility of replacing rate gyros with star sensors for attitude determination. A Kalman filter provides an optimal means to estimate the state of the system. Results show that the rates can be estimated to within 10^-7 rad/s which is as good as from a gyroscope

Keywords

Kalman filters; adaptive control; aerospace computing; artificial satellites; attitude control; attitude measurement; control system synthesis; sensors; 3-axis stabilized satellite; Kalman filter; adaptive control algorithm; attitude control; attitude determination; gyroscope; mechanical failure; rotational motion; star sensor; Adaptive control; Algorithm design and analysis; Attitude control; Computer errors; Control system synthesis; Control systems; Design engineering; Position measurement; Satellites; State estimation;

fLanguage

English

Publisher

ieee

Conference_Titel

System of Systems Engineering, 2006 IEEE/SMC International Conference on

Conference_Location

Los Angeles, CA

Print_ISBN

1-4244-0188-7

Type

conf

DOI

10.1109/SYSOSE.2006.1652309

Filename

1652309