Title :
Robust impulse-to-peak synthesis: application to the control of an aerospace launcher
Author :
Arzelier, D. ; Peaucelle, D.
Author_Institution :
Lab. d´´Autom. et d´´Anal. des Syst., CNRS, Toulouse
Abstract :
A robust synthesis problem via state-feedback involving impulse-to-peak performances is investigated. Even when considering models without uncertainty, the impulse-to-peak performance cannot be computed exactly and a somewhat conservative bound may be computed by LMI optimization. Our goal is first to tighten the bounds obtained in the previous reference using the quadratic stability framework when the state-space matrices are known to belong to a polytope of matrices. In a second stage, the robust state-feedback synthesis problem is tackled in the same setup for LTI discrete-time polytopic systems. These results are then applied to control the attitude of a space launcher during the atmospheric flight
Keywords :
attitude control; computational geometry; discrete time systems; linear matrix inequalities; optimisation; robust control; state feedback; state-space methods; LMI optimization; aerospace launcher; atmospheric flight; attitude control; discrete time polytopic systems; polytopes; quadratic stability framework; robust impulse to peak synthesis; state feedback; state space matrices; Aerodynamics; Aerospace control; Attitude control; Context modeling; Control system synthesis; Hydrogen; Robust control; Robust stability; Robustness; State feedback;
Conference_Titel :
Computer Aided Control Systems Design, 2004 IEEE International Symposium on
Conference_Location :
Taipei
Print_ISBN :
0-7803-8636-1
DOI :
10.1109/CACSD.2004.1393878
