Juan C. García Infante, J. Jesús Medel Juárez, Juan C. Sánchez García
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DOI: 10.4236/jilsa.2010.21002   PDF    HTML     5,233 Downloads   9,724 Views   Citations

Abstract

The paper describes the operation principles of the evolutive neuro fuzzy filtering (ENFF) properties, which based on back propagation fuzzy neural net, this filter adaptively choose and emit a decision according with the reference signal changes of an external reference process, in order to actualize the best correct new conditions updating a process. This neural net fuzzy filter mechanism selects the best parameter values into the knowledge base (KB), to update the filter weights giving a good enough answers in accordance with the reference signal in natural sense. The filter architecture includes a decision making stage using an inference into its structure to deduce the filter decisions in accordance with the previous and actual filter answer in order to updates the new decision with respect to the new reference system con-ditions. The filtering process states require that bound into its own time limit as real time system, considering the Ny-quist and Shannon criteria. The characterization of the membership functions builds the knowledge base in probabilis-tic sense with respect to the rules set inference to describe the reference system and deduce the new filter decision, per-forming the ENFF answers. Moreover, the paper describes schematically the neural net architecture and the deci-sion-making stages in order to integrate them into the filter architecture as intelligent system. The results expressed in formal sense use the concepts into the paper references with a simulation of the ENFF into a Kalman filter structure using the Matlab© tool.

Keywords

Digital Filters, Neuro Fuzzy Systems, Evolutive Systems, Real Time

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Conflicts of Interest

The authors declare no conflicts of interest.

References

[1]	C. Piotr, “Evolution fuzzy rule based system with parameterized consequences,” International Journal of Applied Mathematics and Computer Science, Vol. 16, No. 3, pp. 373–385, 2006.
[2]	F. Yamakawa, “Fuzzy neurons and fuzzy neural networ- ks,” 1989.
[3]	S. Abdul, “Fuzzy logic and its uses,” http://www.doc.ic. ac.uk.
[4]	H. S. Ali, “Fundamentals of adaptive filters,” Complex Systems, 2003.
[5]	R. Ash, “Real analysis and probability,” Ed. Academic Press, USA, 1970.
[6]	S. Haykin, “Adaptive filtering,” Prentice Hall, 2001.
[7]	G. Huang, K. Zhu, and C. Siew, “Real-time learning capability of neural networks,” IEEE Transactions on Neural Networks, Vol. 17, pp. 863–878, 2006.
[8]	B. Rajen and M. Gopal, “Neuro-fuzzy decision trees,” International Journal of Neural Filters, Vol. 16, pp. 63–68, 2006.
[9]	J. García, J. Medel, and J. Sánchez, “Real-time neuro- fuzzy digital filtering: Approach,” Computer and Simulation in Modern Science, WSEAS press selected papers, Vol. 1, 2008.
[10]	J. Medel and P. Guevara, “Caracterización de filtros digi- tales en tiempo-real para computadoras digitales,” Com- putacióny Sistemas, Vol. 7, No. 3, 2004.
[11]	J. Medel, J. García, and J. Sánchez, “Real-time neuro- fuzzy digital filtering: Basic concepts,” WSEAS Transactions on Systems and Control, Vol. 8, No. 16, 2008.
[12]	J. García, J.Medel, and L. Guevara, “RTFDF description for ARMA systems,” WSEAS International Conferences, Canada, 2007.
[13]	D. Marcek, “Stock price forecasting: Statistical, classical and fuzzy neural networks,” Modeling Decisions for Artificial Intelligence, Springer Verlag, pp. 41–48, 2004.
[14]	M. Margaliot and G. Langholz, “New approaches to fuz- zy modeling and control design and analysis,” World Sci- entific, 2000.
[15]	G. Morales, “Introducción a la lógica difusa,” Cinvestav- IPN, 2002.
[16]	T. Amble, “Logic programming and knowledge enginee- ring,” Addison Wesley, 1987.
[17]	J. Smith and A. Eiben, “Introduction to evolutionary com- puting,” Springer, 2003.
[18]	T. Takagi and M. Sugeno, “Fuzzy identification of systems and its applications to modelling and control,” IEEE Transactions and Systems, Man, and Cybernetics, Vol. 15, pp. 116–132, 1986.
[19]	G. Huang, K. Zhu, and C. Siew, “Real-time learning capability of neural networks,” IEEE Transactions on Neural Networks, Vol. 17, pp. 863–878, 2006.
[20]	L. Zadeh, “Fuzzy sets,” Information and Control, Vol. 8, pp. 338–353, 1965.
[21]	K. M. Passino, “Fuzzy control,” Addison Wesley, 1998.
[22]	M. Shannon, “A mathematical theory of communication,” Bell Systems Technical Journal, Vol. 27, pp. 379–423, 623–656, 1948.
[23]	E. Mamdani, “Applications of fuzzy algorithms for control of simple dynamic plant,” Proceedings IEEE, Vol. 121, pp. 1585–1588, 1974.
[24]	M. Montejo, “Lógica difusay control difuso,” 2006, http: //www.redeya.com.