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In this paper, we present a methodology for designing embedded controllers based on the so-called anytime control paradigm. A control law is split into a sequence of subroutine calls, each one fulfilling a control goal and refining the result produced by the previous one. We propose a design methodology to define a feedback controller structured in accordance with this paradigm and show how a switching policy of selecting the controller subroutines can be designed that provides stability guarantees for the closed-loop system. The cornerstone of this construction is a stochastic model describing the probability of executing, in each activation of the controller, the different subroutines. We show how this model can be constructed for realistic real-time task sets and provide an experimental validation of the approach.
Published in:
Industrial Informatics, IEEE Transactions on
(Volume:6
,
Issue:
4
)
Date of Publication: Nov. 2010
- Page(s):
- 492 - 502
- ISSN :
- 1551-3203
- INSPEC Accession Number:
- 11629718
- Digital Object Identifier :
- 10.1109/TII.2010.2055878
- Product Type:
- Journals & Magazines
- Date of Publication :
- 03 August 2010
- Date of Current Version :
- 04 November 2010
- Issue Date :
- Nov. 2010
- Sponsored by :
- IEEE Computer Society
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