论文信息 - Design of Robust Dynamic Inversion Control Laws using Multi-Objective Optimization

Design of Robust Dynamic Inversion Control Laws using Multi-Objective Optimization

The design of robust attitude control laws for a civil aircraft with nonlinear dynamic inversion and multiobjective optimization is discussed. Dynamic inversion is a methodology that achieves linearization and decoupled command responses of the closedloop system via inverse model equations in the feedback loop. Using a linear outer loop controller the desired dynamic behavior is imposed. For tuning the free controller parameters, multi-objective optimization is used. The required robustness is achieved via a multi-model approach, as well as local robustness measures (e.g. gain and phase margins) as optimization criteria. As a new approach, not only the linear controller gains are optimized, but also physical parameters in the inverse model that are considered uncertain in the design model. The resulting control laws are used as inner loops of an autoland system, which was assessed for JAR-AWO requirements and successfully ∞ight tested.

Hans-Dieter Joos | Gertjan Looye | H. Joos | G. Looye

[1] G. KREISSELMEIER,et al. Systematische Auslegung von Reglern durch Optimierung eines vektoriellen Gütekriteriums/Systematic controller design by optimization of a vector performance index , 1979 .

[2] Weiping Li,et al. Applied Nonlinear Control , 1991 .

[3] Frank L. Lewis,et al. Aircraft Control and Simulation , 1992 .

[4] Richard J. Adams,et al. Robust flight control design using dynamic inversion and structured singular value synthesis , 1993, IEEE Trans. Control. Syst. Technol..

[5] Dan Bugajski,et al. Dynamic inversion: an evolving methodology for flight control design , 1994 .

[6] H.-D. Joos,et al. A methodology for multi-objective design assessment and flight control synthesis tuning , 1999 .

[7] Pieter J. Mosterman,et al. Object-oriented computational model building of aircraft flight dynamics and systems , 1999 .

[8] Hilding Elmqvist,et al. Modelica hybrid modeling and efficient simulation , 1999, Proceedings of the 38th IEEE Conference on Decision and Control (Cat. No.99CH36304).

[9] Gertjan Looye,et al. Flight Testing Robust Autoland Control Laws , 2001 .

[10] Hans-Dieter Joos,et al. Application of an Optimization-based Design Process for Robust Autoland Control Laws , 2001 .