[1] Camacho, E.F. Model predictive control,
Springer Verlag, 1998.
[2] Garcia, C.E., Prett, D.M., and Morari, M.
Model predictive control: theory and practice- a
survey, Automatica, 25(3), pp.335-348, 1989.
[3] Badgwell, A.B., Qin, S.J. Review of
nonlinear model predictive control applications,
In Nonlinear predictive control theory and
practice, Kouvaritakis, B, Cannon, M (Eds.), IEE
Control Series, pp.3-32, 2001.
[4] Parker, R.S., Gatzke E.P., Mahadevan, R.,
Meadows, E.S., and Doyle, F.J. Nonlinear model
predictive control: issues and applications, In
Nonlinear predictive control theory and practice,
Kouvaritakis, B, Cannon, M (Eds.), IEE Control
Series, pp.34-57, 2001.
[5] Babuska, R., Botto, M.A., Costa, J.S.D., and
Verbruggen, H.B. Neural and fuzzy modeling on
nonlinear predictive control, a comparison study,
Computatioinal Engineering in Systems Science,
July, 1996.
[6] Nelles, O. Nonlinear system identification:
from classical approach to neuro-fuzzy
identification, Springer Verlag, 2001.
[7] Narendra, K. S., and Parthasarathy, K.,
Identification and control of dynamic systems
using neural networks. IEEE Transactions on
Neural Networks, 1, pp.4–27, 1990.
[8] Arahal, M.R., Berenguel, M., and Camacho,
E.F. Neural identification applied to predictive
control of a solar plant, Con. Eng. Prac. 6(3),
pp.333-344, 1998.
[9] Lennox, B., and Montague, G. Neural
network control of a gasoline engine with rapid
sampling, In Nonlinear predictive control theory
and practice, Kouvaritakis, B, Cannon, M (Eds.),
IEE Control Series, pp.245-255, 2001.
[10] Petrovic, I., Rac, Z., and Peric, N. Neural
network based predictive control of electrical
drives with elastic transmission and backlash,
Proc. EPE2001, Graz, Austria, 2001.
[11] Tan, Y. and Cauwenberghe, A. Non-linear
one step ahead control using neural networks:
control strategy and stability design, Automatica
32(12), pp.1701-1706, 1996.
[12] Temeng, H., Schenelle, P. and McAvoy, T.
Model predictive control of an industrial packed
bed reactor using neural networks, J. Proc.
Control 5(1), pp.19-28, 1995.
[13] Zamarrano, J.M., Vega, P. Neural predictive
control. Application to a highly nonlinear
system, Engineering Application of Artificial
Intelligence, 12(2), pp.149-158, 1999.
[14] Draeger, A., Engel, S., and Ranke, H.,
Model predictive control using neural networks,
IEEE Control System Magazine, 15, pp.61–66,
1995.
[15] Gomm, J. B., Evans, J. T., and Williams, D.,
Development and performance of a neural
network predictive controller. Control
Engineering Practice, 5(1), pp.49–60, 1997.
[16] Diyaz, G., Sen, M., Yang, K.T., McClain,
R.L., Simulation of heat exchanger performance
by artificial neural networks, Int. J. HVAC and R
Res., 5 (3), pp.195-208, 1999.
[17] Ayoubi, M., Dynamic multi-layer
perception networks: application to the nonlinear
identification and predictive control of a heat
exchanger, in: Applications of Neural Adaptive
Control Technology, World Scientific series in
Robotics and Intelligent Systems, 17, pp.205-
230, 1997.
[18] Renotie, C., Wouwer, A.V. and Remy, M.
Neural modeling and control of a heat exchanger
based on SPSA techniques, Proc. American
Control Conference, Illinois, pp.3299-3303,
2000.
[19] Bittanti, S. and Piroddi, L. Nonlinear
identification and control of a heat exchanger: a
neural network approach, Journal of the Franklin
Institute, 1996.
[20] Lim, K.W. and Ling, K.V. generalized
predictive control of a heat exchanger, IEEE
Control System Magazine, pp.9-12, 1989.
Predictive Control Of Chaotic Discrete Plants
S. Shams Abbad FARAHANI, M.A. NEKOUI
285
[21] Parte, M.P. and Camacho, E.F. Application
of a predictive sliding mode controller to a heat
exchanger, Proc. IEEE Conf. Control
Application, Glasgow, Scotland, pp.1219-1224,
2002.
[22] Skrijave, I. and Matko, D. Predictive
functional control based on fuzzy model for heat
exchanger pilot plant, IEEE Trans. Fuzzy
Systems, 8(6), pp.705-812, 2000.
[23] Nelles, O. and R. Isermann (1996). Basis
function networks for interpolation of local linear
models. In: IEEE Conference on Decision and
Control (CDC). Kobe, Japan. pp. 470–475.
[25] Liu, G.P., 2001, Nonlinear Identification
and Control: A Neural Network Approach,
Springer.
[26] Hunt, K.J., Sbarbaro, D., Zbikowski, R.,
Gawthrop, P.J., (1992). Neural networks for
control system—A survey. Automatica, 28,
pp.1083–1112.
[27] Takahashi, Y., (1993). Adaptive predictive
control of nonlinear time varying system using
neural network, in Proc. IEEE International
Symposium on Neural Networks, pp.1464–1468.
[28] Montague, G.A., Willis, M.J., Tham, M.T.,
Morris, A.J., (1991). Artificial neural network
based control. International Conference on
Control, pp.266–271.
[29] Chen, G. and Moiola, J. L. An overview of
bifurcation, chaos, and nonlinear dynamics in
nonlinear system, J. Franklin Inst., vol. 331B, pp.
819-858, 1994.
[30] Ogorzalek, M. J. Taming chaos, Part two:
control, IEEE Trans. Circuits Syst. I, vol. 40, pp.
700-706, 1993.
[31] Chen, G. and Done, X. From chaos to order:
methodologies, perspectives and applications,
World Scientific, Singapore, 1998.
[32] Fradkov, A. L. and Pogromsky, A. Y.
Introduction to control of oscillations and chaos,
World Scientific, Singapore, 1998.
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