Complexity reduction in MPC for stochastic max-plus-linear systems by variability expansion

Author

van den Boom, T.J.J. ; De Schutter, B. ; Heidergott, B.

Author_Institution

Fac. of Inf. Technol. & Syst., Delft Univ. of Technol., Netherlands

Volume

3

fYear

2002

fDate

10-13 Dec. 2002

Firstpage

3567

Abstract

Model predictive control (MPC) is a popular controller design technique in the process industry. Conventional MPC uses linear or nonlinear discrete-time models. Previously, we have extended MPC to a class of discrete event systems that can be described by a model that is "linear" in the max-plus algebra. In our previous work we have considered MPC for the perturbations-free case and for the case with noise and/or modeling errors in a bounded or stochastic setting. In this paper we consider a method to reduce the computational complexity of the resulting optimization problem, based on variability expansion. We show that the computational load is reduced if we decrease the level of \´randomness\´ in the system.

Keywords

computational complexity; discrete event systems; optimisation; predictive control; stochastic systems; MPC; complexity reduction; discrete event systems; max-plus algebra; model predictive control; optimization problem; stochastic max-plus-linear systems; variability expansion; Algebra; Computational complexity; Discrete event systems; Electrical equipment industry; Industrial control; Optimization methods; Predictive control; Predictive models; Stochastic resonance; Stochastic systems;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control, 2002, Proceedings of the 41st IEEE Conference on

ISSN

0191-2216

Print_ISBN

0-7803-7516-5

Type

conf

DOI

10.1109/CDC.2002.1184430

Filename

1184430