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Robust Stability in Multivariable Neural Network Control using Harmonic Analysis
Authors: J. Fernandez de Canete, S. Gonzalez-Perez, P. del Saz-Orozco, I. Garcia-Moral
Abstract:
Robust stability and performance are the two most basic features of feedback control systems. The harmonic balance analysis technique enables to analyze the stability of limit cycles arising from a neural network control based system operating over nonlinear plants. In this work a robust stability analysis based on the harmonic balance is presented and applied to a neural based control of a non-linear binary distillation column with unstructured uncertainty. We develop ways to describe uncertainty in the form of neglected nonlinear dynamics and high harmonics for the plant and controller respectively. Finally, conclusions about the performance of the neural control system are discussed using the Nyquist stability margin together with the structured singular values of the uncertainty as a robustness measure.Keywords: Robust stability, neural network control, unstructured uncertainty, singular values, distillation column.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1086053
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[1] S. Toffner-Clausen, P. Abdersen and J. Stoustrup. Robust Control, Dpt. of Control Engineering. I.E: E: Aalborg University, 2001.
[2] K.A. Astrom and R.M. Murray. Feedback Systems. Princeton University Press, 2008.
[3] H. A. Latchman, O.D. Crisalle and V.R: Basker, "The Nyquist robust stability margin. A new metric for the stability of uncertain systems" Int. Journal of Robust and Nonlinear Control, vol. 7, pp. 211-226, 1997.
[4] E.J. Adam and E.D. Guestrin, "Identification and control of an experimental servo motor", ISA Transactions n. 41, pp. 225-234, 2002.
[5] J. Aracil and F. Gordillo (Eds.), Stability Issues in Fuzzy Control, Physica-Verlag, Heidelberg, 2000.
[6] M.A. Hussain, "Review of the applications of neural networks in chemical process control. Simulation and on-line implementations", Artificial Intelligence in Engineering, Vol. 13, pp. 55-68, 1999.
[7] S. Skogestad and I. Postlethwaite. Multivariable Feedback ControlÔÇö Analysis and Design. Wiley, 1996.
[8] R. Nystrom, K. Haggblom and J. Boling, 'Derivation and selection of norm-bounded uncertainty descriptions based on multiple models', International Journal of Control, n. 76, 7, pp.717-727, 2003.
[9] J.H. Taylor, "Describing function methods for high-order highly nonlinear systems.", Proc. Intl. Cong. on Appl. Systems Research and Cybernetics, Acapulco, Mexico, 1980.
[10] A.G. McFarlane. Complex Variable Methods for Linear Multivariable Feedback Systems. Taylor and Francis, London, 1982.
[11] T.K. Gustafsson and P. Makila, "Modeling of uncertain systems with application to robust process control", Journal of Process Control, n. 11, pp. 251-264, 2001.
[12] S. Boyd and C. Barratt. Linear Controller Design, Prentice Hall, 1991.
[13] M. Diehl, I. Uslu, R. Findeisen.,"Real-time optimization for large scale processes: Nonlinear predictive control of a high purity distillation column", On Line Optimization of Large Scale System:State of the Art, Springer-Verlag, 2001.
[14] J. Fernandez de Canete, J., S. Gonzalez-Perez, P. Del Saz-Orozco, "Development of tools for monitoring and control of multivariable neurocontrolled systems with application to distillation columns", Proc. EANN 2007, Tesalonica, pp. 241-251, 2007.
[15] T.K. Gustafsson and P. Makila, L1-identification toolbox for MATLAB, Abo Akademi Press, 1994.