Title :
Certainty-Equivalence Feedback Design With Polynomial-Type Feedbacks Which Guarantee ISS
Author :
Ebenbauer, Christian ; Raff, Tobias ; Allgöwer, Frank
Author_Institution :
Lab. for Inf. & Decision Syst., MIT, Cambridge, MA
fDate :
4/1/2007 12:00:00 AM
Abstract :
The purpose of this note is to establish a certainty-equivalence feedback design for inverse optimally controlled affine systems. In particular, it is shown that a class of polynomial-type state feedbacks in conjunction with a globally asymptotically convergent observer leads to a globally asymptotically stable closed-loop. A key step in the proposed certainty-equivalence feedback design procedure is the identification of a new class of polynomial-type inverse optimal feedbacks which guarantees input-to-state stability (ISS) with respect to measurement errors. As a consequence, the proposed certainty-equivalence feedback design has the important feature that the state feedback is allowed to contain polynomial nonlinearities of arbitrarily high degree in the unmeasured states. This feature is illustrated on an example
Keywords :
asymptotic stability; closed loop systems; equivalence classes; nonlinear control systems; observers; optimal control; state feedback; certainty-equivalence feedback design; global asymptotic convergent observer; global asymptotic stable closed-loop; input-to-state stability; inverse optimally controlled affine systems; polynomial nonlinearities; polynomial-type inverse optimal feedbacks; polynomial-type state feedbacks; Asymptotic stability; Automatic control; Control systems; Control theory; Measurement errors; Optimal control; Output feedback; Polynomials; Robust control; State feedback; Certainty-equivalence design; input-to-state stability (ISS); inverse optimality; polynomial feedback; separation principle;
Journal_Title :
Automatic Control, IEEE Transactions on
DOI :
10.1109/TAC.2007.894538
