Authors: Ritu Vijay, Rekha Govil

Abstract:

The design of a complete expansion that allows for compact representation of certain relevant classes of signals is a central problem in signal processing applications. Achieving such a representation means knowing the signal features for the purpose of denoising, classification, interpolation and forecasting. Multilayer Neural Networks are relatively a new class of techniques that are mathematically proven to approximate any continuous function arbitrarily well. Radial Basis Function Networks, which make use of Gaussian activation function, are also shown to be a universal approximator. In this age of ever-increasing digitization in the storage, processing, analysis and communication of information, there are numerous examples of applications where one needs to construct a continuously defined function or numerical algorithm to approximate, represent and reconstruct the given discrete data of a signal. Many a times one wishes to manipulate the data in a way that requires information not included explicitly in the data, which is done through interpolation and/or extrapolation. Tidal data are a very perfect example of time series and many statistical techniques have been applied for tidal data analysis and representation. ANN is recent addition to such techniques. In the present paper we describe the time series representation capabilities of a special type of ANN- Radial Basis Function networks and present the results of tidal data representation using RBF. Tidal data analysis & representation is one of the important requirements in marine science for forecasting.

Keywords: ANN, RBF, Tidal Data.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1056084

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References:

[1] Becker T. and Weispfenning V., "Gröbner Bases: A Computational Approach to Commutative Algebra", New York: Springer-Verlag, 1993.
[2] Proakis J.G., "Digital Communication", 3rd ed., Mcgraw-Hill, NewYork,1995.
[3] Polikar Robi, "Fundamental Concepts and overview of the wavelet theory", Sec.edition, 1994
[4] Park J. and Sandberg J.W., "Universal Approximation using radial basis functions network," Neural Computation, Vol. 3, pp. 246-257, 1991.
[5] Poggio T. and Girosi F., "Networks for approximation and learning," proc. IEEE, Vol. 78, no. 9, pp. 1481-1497, 1990.
[6] Haykin S.," Neural Networks: A comprehensive Foundation", Upper Saddle River, NJ: Prentice hall, 1994.
[7] Broomhead D.S. and D. Lowe., "Multivariate functional interpolation and adaptive networks", Complex Systems, vol 2, pp.321-355, 1988.
[8] Jin X. C, Ong S.H., and Jayasooriah, "A practical method for estimating fractal dimension", Pattern recogn. Lett., vol. 16, pp. 457-564,1995.
[9] Govil Rekha, "Neural Networks in Signal rocessing", Studies In Fuzziness and Soft Computing, Physica Verlag, vol 38 . pp 235-257, 2000.