| Full text | |
| Author(s): |
Morais, Cecilia F.
;
Palma, Jonathan M.
;
Peres, Pedro L. D.
;
Oliveira, Ricardo C. L. F.
;
IEEE
Total Authors: 5
|
| Document type: | Journal article |
| Source: | 2018 ANNUAL AMERICAN CONTROL CONFERENCE (ACC); v. N/A, p. 6-pg., 2018-01-01. |
| Abstract | |
Many practical problems arising in networked control systems can be suitably modeled by linear stochastic systems described in terms of discrete-time generalized Bernoulli models, that are a particular case of the so called Markov jump linear systems. Motivated by real world applications where the transition probability matrix is uncertain, this paper proposes a general framework to deal with the problem of control design for Bernoulli systems, providing synthesis conditions for H-2 and H-infinity state-feedback controllers that are sufficient in the uncertain case and also necessary (optimal) for precisely known models. The conditions can be solved in terms of LMI relaxations of increasing accuracy, allowing the user to tradeoff precision and computational cost in the search for better solutions. The networked control of a mechanical plant is presented to illustrate the applicability of the method. (AU) | |
| FAPESP's process: | 14/22881-1 - Control of switched systems, Markov jump linear systems and other classes of hybrid systems through LMIs |
| Grantee: | Cecília de Freitas Morais |
| Support Opportunities: | Scholarships in Brazil - Post-Doctoral |