Abstract
Nowadays, the use of advanced control strategies in biotechnology is quite low. A main reason is the lack of quality of the data, and the fact that more sophisticated control strategies must be based on a model of the dynamics of bioprocesses. The nonlinearity of the bioprocesses and the absence of cheap and reliable instrumentation require an enhanced modeling effort and identification strategies for the kinetics. The present work approaches modeling and control strategies for the enzymatic synthesis of ampicillin that is carried out inside a fed-batch bioreactor. First, a nonlinear dynamical model of this bioprocess is obtained by using a novel modeling procedure for biotechnology: the bond graph methodology. Second, a high gain observer is designed for the estimation of the imprecisely known kinetics of the synthesis process. Third, by combining an exact linearizing control law with the on-line estimation kinetics algorithm, a nonlinear adaptive control law is designed. The case study discussed shows that a nonlinear feedback control strategy applied to the ampicillin synthesis bioprocess can cope with disturbances, noisy measurements, and parametric uncertainties. Numerical simulations performed with MATLAB environment are included in order to test the behavior and the performances of the proposed estimation and control strategies.
Highlights
The design and implementation of modern control strategies in bioindustry require useful models of the biotechnological processes
The results obtained in this study show a good behavior of the adaptive controlled ampicillin synthesis bioprocess
In a Continuous Stirred Tank Bioreactor (CSTB), the substrates are fed to the bioreactor continuously and an effluent stream is continuously withdrawn such that the culture volume is constant
Summary
The design and implementation of modern control strategies in bioindustry require useful models of the biotechnological processes. There have been a lot of works on the subject of the theory and application of bond graphs for different kind of systems, such as electrical [5], mechanical, hydraulic, thermal, and chemical [6,7,8]. This method provides a uniform manner to describe the dynamical behavior for all types of physical systems. The bond graph modeling of biotechnological processes is not fully exploited yet; in recent years, only some applications in wastewater treatment bioprocesses were reported [3, 10, 11]
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