Title :
Optimal control study for the Space Station solar dynamic power module
Author :
Papadopoulos, Pantelis M. ; Laub, A. ; Kenney, C.S. ; Pandey, P. ; Ianculescu, G. ; Ly, J.
Author_Institution :
ECE Dept., California Univ., Santa Barbara, CA, USA
Abstract :
The authors present the design of an optimal control system for the Space Station Freedom solar dynamic fine pointing and tracking (SDFPT) module. A very large state model of six rigid modes and 272 flexible modes is used in conjunction with classical LQG optimal control to produce a full-order controller which satisfies the requirements. The results obtained are compared with those of a classically designed PID (proportional plus integral plus derivative) controller that was implemented for a six-rigid-body-mode forty-flexible-mode model. A major difficulty with designing LQG controllers for large models is solving the Ricati equation that arises from the optimal formulation. A Riccati solver based on a Pade approximation to the matrix sign function is used. A symmetric version of this algorithm is derived for the special class of Hamiltonian matrices, thereby yielding, for large problems, a nearly twofold speed increase over a previous algorithm
Keywords :
aerospace control; control system synthesis; matrix algebra; optimal control; solar power; space vehicle power plants; Hamiltonian matrices; LQG optimal control; Pade approximation; Ricati equation; Space Station Freedom; aerospace control; design; fine pointing; large state model; solar dynamic power module; tracking; Integral equations; Optimal control; PD control; Pi control; Power system modeling; Proportional control; Riccati equations; Space stations; Symmetric matrices; Three-term control;
Conference_Titel :
Decision and Control, 1991., Proceedings of the 30th IEEE Conference on
Conference_Location :
Brighton
Print_ISBN :
0-7803-0450-0
DOI :
10.1109/CDC.1991.261542
