Determination of the optimal beta gimbal angles for the solar arrays of the space station using a neural network

Author

Clancy, Daniel ; Özgüner, Ümit ; Graham, Ronald

Author_Institution

Dept. of Electr. Eng., Ohio State Univ., Columbus, OH, USA

fYear

1994

fDate

20-22 Mar 1994

Firstpage

69

Lastpage

73

Abstract

The current baseline solution for minimizing the potential of dynamic loads being imparted onto the solar arrays of the Space Station during proximity maneuvers by the Space Shuttle is to lock the position of the solar arrays throughout the approach/departure of the Space Shuttle. However, if the a priori locked position does not optimally feather the solar arrays throughout the Shuttle´s approach/departure, excessive dynamic loads could result, producing a structural failure in the solar arrays. A more robust solution would involve feathering the position of the solar arrays throughout proximity maneuvers by the Space Shuttle. The robust solution will be implemented using a neural network as an open loop predictor/controller

Keywords

neural nets; photovoltaic power systems; position control; solar cell arrays; space vehicle power plants; stability; Space Shuttle; Space Station; dynamic load potential minimization; feathering; neural network; open loop predictor/controller; optimal beta gimbal angles; proximity maneuvers; solar arrays; Control systems; Feathers; NASA; Neural networks; Open loop systems; Power supplies; Robust control; Robustness; Space shuttles; Space stations;

fLanguage

English

Publisher

ieee

Conference_Titel

System Theory, 1994., Proceedings of the 26th Southeastern Symposium on

Conference_Location

Athens, OH

ISSN

0094-2898

Print_ISBN

0-8186-5320-5

Type

conf

DOI

10.1109/SSST.1994.287908

Filename

287908