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An experimental study on long transient oscillations in cooperative CNN rings

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Mauro Forti; Barnabás Garay; Miklos Koller; Luca Pancioni
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Abstract:

The paper considers a class of one-dimensional circular standard cellular neural network (CNN) arrays with a typical three-segment piecewise linear activation and two-sid...Show More

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Abstract:

The paper considers a class of one-dimensional circular standard cellular neural network (CNN) arrays with a typical three-segment piecewise linear activation and two-sided cooperative (positive) interactions (a cooperative CNN ring). Numerical simulations show that in a wide range of interconnection parameters, and for a wide set of initial conditions, the solutions of a cooperative CNN ring display unexpectedly long oscillations, lasting even hundreds of cycles, before they eventually converge toward an equilibrium point. The goal of this paper is to confirm the presence of such long-transient oscillations through laboratory experiments on a simple discrete-component prototype of a cooperative CNN ring with 16 cells and to analyze some of their salient features. Analytical results are also provided to support the numerical and experimental findings.
Published in: 2012 13th International Workshop on Cellular Nanoscale Networks and their Applications
Date of Conference: 29-31 August 2012
Date Added to IEEE Xplore: 18 October 2012
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ISSN Information:

DOI: 10.1109/CNNA.2012.6331410
Conference Location: Turin, Italy
References is not available for this document.
Contents

I. Introduction

In this paper we investigate some fundamental dynamical properties of a class of one-dimensional circular standard cellular neural network (CNN) arrays with a typical three-segment piecewise linear (PL) activation and two-sided interactions (a CNN ring).

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