Spacecraft alignment estimation

Author

Bierman, Gerald J. ; Shuster, Malcolm D.

fYear

1988

fDate

7-9 Dec 1988

Firstpage

856

Abstract

A numerically well-behaved factorized methodology is developed for estimating spacecraft sensor alignments from prelaunch and inflight data without the need to compute the spacecraft attitude or angular velocity. Such a methodology permits the estimation of sensor alignments (or other biases) in a framework free of unknown dynamical variables. In actual mission implementation such an algorithm is usually better behaved than one that must compute sensor alignments simultaneously with the spacecraft attitude, for example by means of a Kalman filter. In particular, such a methodology is less sensitive to data dropouts of long duration, and the derived measurement used in the attitude-independent algorithm usually makes data checking and editing of outliers much simpler than would be the case in the filter

Keywords

aerospace computing; attitude control; calibration; space vehicles; aerospace computing; angular velocity; inflight alignment calibration; spacecraft attitude; spacecraft sensor alignments; Angular velocity; Cities and towns; Coordinate measuring machines; Filters; Laboratories; Noise measurement; Physics computing; Position measurement; Rotation measurement; Space vehicles;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control, 1988., Proceedings of the 27th IEEE Conference on

Conference_Location

Austin, TX

Type

conf

DOI

10.1109/CDC.1988.194432

Filename

194432