Abstract
Transversal FIR adaptive filters have been widely used in echo and noise cancelers systems, in equalization of communication channels, in speech coders and predictive deconvolution systems in seismic exploration etc., almost all of these systems implemented in a digital way. This is because with the advance of digital technology it became possible to implement sophisticated and efficient adaptive filter algorithms. However, even with the great advance of the digital technology, the transversal FIR adaptive filters still present several limitations when required to handle in real time frequencies higher than those in the audio range, or when a relative large number of taps are required. To avoid the limitations of digital FIR adaptive filters, several different structures have been proposed. Among them, the analog filters appears to be e desirable alternative to transversal FIR digital adaptive filters because they have the ability to handle very high frequencies, and their size and power requirements are potentially much smaller than their digital counterparts. This paper propose a continuous time transversal adaptive filter structure whose coefficients are estimated in a continuous time way by using an artificial Hopfield Neural Network. Simulation results using the proposed structure in cancellation, prediction and equalization configurations are given to show the desirable features of the proposed structure.
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References
S. Haykin, “Adaptive Filter Theory,” Prentice Hall, Englewood Cliffs NJ, 1991.
D. Messershmitt, “Echo Cancellation in Speech and Data Transmission,” IEEE J. Of Selected Areas in Communications, vol. SAC-2, No. 2, pp. 283–297, March 1992.
M. Nakano-Miyatake, H. Perez-Meana, L. Nino-de-Rivera F. Casco-Sanchez and J. Sanchez-Garcia, “A Time Varying Step Size Normalized LMS Algorithm for Adaptive Echo Canceler Structures,” IEICE Trans. on Fundamentals, vol. E-78, No. 2, pp. 254–258, Feb. 1995.
D. Falconer and L. Ljung, “Application of Fast Kaiman to Adaptive Equalization,” IEEE Trans. On Communications, vol. COM-26, No.10, PP. 1439–1446, Oct. 1978.
S. Kinjo and H. Ochi, “A New Robust Block Adaptive Filter for Colored Signal Input,” IEICE Trans. on Fundamentals, vol. E78, No.3, pp. 437–439, March 1995.
H. Pérez-Meana and F. Amano, “Acoustic Echo Cancellation Using Multirate Techniques,” IEICE Trans., vol. E74, No. 11, pp. 3559–3568, No. 1991.
F. Amano, H. Perez-Meana, A. De Luca and G. Duchen, “A Multirate Acoustic Echo Canceler Structure,” IEEE Trans. on Communications, vol. 43, No. 7, pp. 2172–2176, July 1995.
H. Perez-Meana and S. Tsujii, “A System Identification Using Orthogonal Functions,” IEEE Trans. on Signal Processing, vol. 39, No. 3, March 1991.
A. Martinez-Gonzalez, L. Ortiz-Balbuena, H. Perez-Meana, L. Niño-de-Rivera and J. Ramirez-Angulo, “Analog Propose of Adaptive Filter Using All Pass Functions and LMS Approach,” Proc. of ISITA'94, pp. 1351–1355, Nov. 1994.
S. Karni and G. Zeng, “The Analysis of the Continuous-Time LMS Algorithm,” IEEE Trans on ASSP, vol ASSP-37, No 4, pp 595–597, April 1989.
W. Wu, R. Chen and S. Chang, “An Analog Architecture for Estimation of ARMA Models,” IEEE Trans. on Signal Processing, vol. 41, pp.2946–2953, Sept. 1993.
L. Ortiz-Balbuena, A. Martinez-Gonzalez, H. Perez-Meana, L. Nino-de-Rivera and J. Ramirez-Angulo, “A Continuous Time Adaptive Filter Structure,” Proc of ICASSP'95 vol. II, pp. 1061–1064, 1995.
M. Nakano-Miyatake, H. Perez-Meana, L. Ortiz-Balbuena, L Niño-de-Rivera, and J. Sanchez, “A continuous Time RLS adaptive Filter Structure Using Hopfield Neural Networks,” Proc. of ISITA'96, vol. II, pp. 614–617, Sept. 1996.
M. Nakano-Miyatake, H. Perez-Meana, J. Sanchez, L. Nino-de-Rivera and L. Ortiz, “A Decision Feedback Equalizer structure Using Hopfield Neural Networks,” Proc. of ICSPAT'96, pp. 555–559, Oct. 1996.
B. Kosko, “Neural Networks for Signal Processing,” Prentice Hall, Englewood Cliff, NJ, 1992.
J. Hertz, A. Krogh, R. Palmer, “Introduction to The Theory of Neural Computation,” Addison Wesley, Reading, Mass, 1991.
M. Nakano-Miyatake, H. Perez-Meana, J. Sanchez-Garcia, L. Ni~no-de-Rivera and L. Ortiz-Balbuena, “A Continuous Time Equalizer Structure Using Hopfield Neural Networks,” Proc of IASTED International Conference on Signal and Image Processing, pp. 168–172, Nov. 1996.
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© 1997 Springer-Verlag Berlin Heidelberg
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Perez-Meana, H., Nakano-Miyatake, M. (1997). A continuous time structure for filtering and prediction using Hopfield Neural Networks. In: Mira, J., Moreno-Díaz, R., Cabestany, J. (eds) Biological and Artificial Computation: From Neuroscience to Technology. IWANN 1997. Lecture Notes in Computer Science, vol 1240. Springer, Berlin, Heidelberg. https://doi.org/10.1007/BFb0032584
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DOI: https://doi.org/10.1007/BFb0032584
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