(240g) Modular Design of Discrete-Time Nonlinear Observers for State and Disturbance Estimation | AIChE

(240g) Modular Design of Discrete-Time Nonlinear Observers for State and Disturbance Estimation

Authors 

Kravaris, C. - Presenter, University of Patras
Savoglidis, G. - Presenter, University of Patras


Technical limitations and/or high cost of sensors result in the non-availability of all state variables for direct on-line measurement, and this creates the need for on-line state estimation. Furthermore, the operation of a process or plant is subject to time-varying disturbances, associated with changes in key process parameters or improper operation of sensing instruments. For this reason, in addition to monitoring the state variables, there is a definite practical need for detection and estimation of disturbances.

The problem of combined state and disturbance estimation can be conceptually formulated as a state estimation problem for an extended system. In the case of linear systems, the well-known Luenberger observer offers a comprehensive solution. More specifically, in industrial applications of combined state and disturbance estimation, the Luenberger observer is designed and implemented in a modular configuration, consisting of an observer for the disturbance-free part of the system and, on top of it, a disturbance estimator and a state-estimate corrector ([1]).

The purpose of the present work is to develop a systematic discrete-time nonlinear observer design method for state and disturbance estimation, so that the resulting observer possesses the modular configuration that is sought for in practice. The discrete-time nonlinear observer design problem will first be formulated in non-modular form within the general framework of exact observer linearization and in particular, following the invariant-manifold formulation, originally proposed in [2] and further developed in [3],[4]. The modular observer will then be defined and characterized in terms of appropriate invariance conditions. Necessary and sufficient conditions for exact linearization with eigenvalue assignment will be derived, leading to a step-by-step design procedure for the modular observer.

The theoretical developments and results of the present paper leading to the discrete-time modular observer design are exactly parallel to the continuous-time modular observer of [5].

The theoretical results will be applied to a bioreactor case study, where biomass is continuously measured, and the observer must estimate the substrate concentration as well as the external disturbance affecting the measuring device.

References:

[1] B. Friedland, Control System Design. An Introduction to State-Space Methods. New York: McGraw-Hill, 1986.

[2] N. Kazantzis and C. Kravaris, ?Discrete-time nonlinear observer design using functional equations,? Systems Control Lett., Vol. 42, No.2, pp. 81-94, 2001.

[3] MQ. Xiao, N. Kazantzis, C. Kravaris and A. J. Krener, ?Nonlinear discrete-time observer design with linearizable error dynamics,? IEEE Trans. Automat. Contr., Vol. 48, No.4, pp. 622-626, 2003.

[4] MQ. Xiao, ?A direct method for the construction of nonlinear discrete-time observer with linearizable error dynamics,? IEEE Trans. Automat. Contr., Vol. 51, No.1, pp. 128-135, 2006.

[5] C. Kravaris and G. Savoglidis, ?Modular design of nonlinear observers for state and disturbance estimation,? Systems Control Lett., in press. See also Proc. 45th IEEE CDC, San Diego, CA, 2006, pp. 4621-4626.

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