Analysis of time-delayed neural networks via rightmost eigenvalue positions

Sun Yi; Sangseok Yu; Jung H. Kim; Taher M. Abu-Lebdeh

doi:10.3844/ajeassp.2015.1.10

Analysis of time-delayed neural networks via rightmost eigenvalue positions

Sun Yi, Sangseok Yu, Jung H. Kim, Taher M. Abu-Lebdeh

Research output: Contribution to journal › Article › peer-review

Abstract

Neural networks have been frequently used in various areas. In the implementation of the networks, time delays and uncertainty are present and known to lead to complex behaviors, which are hard to predict using classical analysis methods. In this study, stability and robust stability of neural networks considering time delays and parametric uncertainty is studied. For stability analysis, the rightmost eigenvalues (or dominant characteristic roots) are obtained by using an approach based on the Lambert W function. The Lambert W function has already been embedded in various commercial software packages (e.g., MATLAB, Maple and Mathematica). In a way similar to non-delayed systems, stability is determined from the positions of the characteristic roots in the complex plane. Conditions for oscillation and robust stability are also given. Numerical examples are provided and the results are compared to existing approaches (e.g., bifurcation method) and discussed.

Original language	English
Pages (from-to)	1-10
Number of pages	10
Journal	American Journal of Engineering and Applied Sciences
Volume	8
Issue number	1
DOIs	https://doi.org/10.3844/ajeassp.2015.1.10
State	Published - Jan 26 2015
Externally published	Yes

Keywords

Eigenvalues stability
Lambert W function
Neural network
Parametric uncertainty

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10.3844/ajeassp.2015.1.10

Cite this

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title = "Analysis of time-delayed neural networks via rightmost eigenvalue positions",

abstract = "Neural networks have been frequently used in various areas. In the implementation of the networks, time delays and uncertainty are present and known to lead to complex behaviors, which are hard to predict using classical analysis methods. In this study, stability and robust stability of neural networks considering time delays and parametric uncertainty is studied. For stability analysis, the rightmost eigenvalues (or dominant characteristic roots) are obtained by using an approach based on the Lambert W function. The Lambert W function has already been embedded in various commercial software packages (e.g., MATLAB, Maple and Mathematica). In a way similar to non-delayed systems, stability is determined from the positions of the characteristic roots in the complex plane. Conditions for oscillation and robust stability are also given. Numerical examples are provided and the results are compared to existing approaches (e.g., bifurcation method) and discussed.",

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T1 - Analysis of time-delayed neural networks via rightmost eigenvalue positions

AU - Yi, Sun

AU - Yu, Sangseok

AU - Kim, Jung H.

AU - Abu-Lebdeh, Taher M.

PY - 2015/1/26

Y1 - 2015/1/26

N2 - Neural networks have been frequently used in various areas. In the implementation of the networks, time delays and uncertainty are present and known to lead to complex behaviors, which are hard to predict using classical analysis methods. In this study, stability and robust stability of neural networks considering time delays and parametric uncertainty is studied. For stability analysis, the rightmost eigenvalues (or dominant characteristic roots) are obtained by using an approach based on the Lambert W function. The Lambert W function has already been embedded in various commercial software packages (e.g., MATLAB, Maple and Mathematica). In a way similar to non-delayed systems, stability is determined from the positions of the characteristic roots in the complex plane. Conditions for oscillation and robust stability are also given. Numerical examples are provided and the results are compared to existing approaches (e.g., bifurcation method) and discussed.

AB - Neural networks have been frequently used in various areas. In the implementation of the networks, time delays and uncertainty are present and known to lead to complex behaviors, which are hard to predict using classical analysis methods. In this study, stability and robust stability of neural networks considering time delays and parametric uncertainty is studied. For stability analysis, the rightmost eigenvalues (or dominant characteristic roots) are obtained by using an approach based on the Lambert W function. The Lambert W function has already been embedded in various commercial software packages (e.g., MATLAB, Maple and Mathematica). In a way similar to non-delayed systems, stability is determined from the positions of the characteristic roots in the complex plane. Conditions for oscillation and robust stability are also given. Numerical examples are provided and the results are compared to existing approaches (e.g., bifurcation method) and discussed.

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Analysis of time-delayed neural networks via rightmost eigenvalue positions

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Keywords

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