Self-convergence of weighted least-squares with applications to stochastic adaptive control

Author

Guo, Lei

Author_Institution

Inst. of Syst. Sci., Acad. Sinica, Beijing, China

Volume

41

Issue

1

fYear

1996

fDate

1/1/1996 12:00:00 AM

Firstpage

79

Lastpage

89

Abstract

A recursive least-squares algorithm with slowly decreasing weights for linear stochastic systems is found to have self-convergence property, i.e., it converges to a certain random vector almost surely irrespective of the control law design. Such algorithms enjoy almost the same nice asymptotic properties as the standard least-squares. This universal convergence result combined with a method of random regularization then easily can be applied to construct a self-convergent and uniformly controllable estimated model and thus may enable us to form a general framework for adaptive control of possibly nonminimum phase autoregressive-moving average with exogenous input (ARMAX) systems. As an application, we give a simple solution to the well-known stochastic adaptive pole-placement and linear-quadratic-Gaussian (LQG) control problems in the paper

Keywords

adaptive control; autoregressive moving average processes; convergence of numerical methods; least squares approximations; linear quadratic Gaussian control; linear systems; parameter estimation; pole assignment; stochastic systems; ARMAX systems; LQG control; linear stochastic systems; linear-quadratic-Gaussian control; pole-placement; random vector; recursive least-squares algorithm; self-convergence; stochastic adaptive control; Adaptive control; Algorithm design and analysis; Control system analysis; Control systems; Phase estimation; Signal analysis; Stability; Stochastic processes; Stochastic systems; Vectors;

fLanguage

English

Journal_Title

Automatic Control, IEEE Transactions on

Publisher

ieee

ISSN

0018-9286

Type

jour

DOI

10.1109/9.481609

Filename

481609