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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
Published in:
Automatic Control, IEEE Transactions on
(Volume:41
,
Issue:
1
)
Date of Publication: Jan 1996
- Page(s):
- 79 - 89
- ISSN :
- 0018-9286
- INSPEC Accession Number:
- 5185810
- Digital Object Identifier :
- 10.1109/9.481609
- Product Type:
- Journals & Magazines
- Date of Current Version :
- 06 August 2002
- Issue Date :
- Jan 1996
- Sponsored by :
- IEEE Control Systems Society
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