Geodesic
Stability of delayed neural networks with impulsive strength-dependent average impulsive intervals
Zhang, Huan 1 ; Zhang, Wenbing 1 ; Li, Zhi 2
1 Department of Mathematics, YangZhou University, Jiangsu, 225002, China
2 Business School, SiChuan University, SiChuan, 610044, China
Journal of nonlinear sciences and its applications, Tome 11 (2018) no. 5, p. 602-612.

Voir la notice de l'article provenant de la source International Scientific Research Publications

This paper mainly deals with the stability of delayed neural networks with time-varying impulses, in which both stabilizing and destabilizing impulses are considered. By means of the comparison principle, the average impulsive interval and the Lyapunov function approach, sufficient conditions are obtained to ensure that the considered impulsive delayed neural network is exponentially stable. Different from existing results on stability of impulsive systems with average impulsive approach, it is assumed that impulsive strengths of stabilizing and destabilizing impulses take values from two finite states, and a new definition of impulsive strength-dependent average impulsive interval is proposed to characterize the impulsive sequence. The characteristics of the proposed impulsive strength-dependent average impulsive interval is that each impulsive strength has its own average impulsive interval and therefore the proposed impulsive strength-dependent average impulsive interval is more applicable than the average impulsive interval. Simulation examples are given to show the validity and potential advantages of the developed results.
DOI : 10.22436/jnsa.011.05.02
Classification : 34K20, 34K45
Keywords: Neural networks, impulsive strength-dependent average impulsive interval, time-varying impulse, stability

Zhang, Huan  1 ; Zhang, Wenbing  1 ; Li, Zhi  2

1 Department of Mathematics, YangZhou University, Jiangsu, 225002, China
2 Business School, SiChuan University, SiChuan, 610044, China 
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Zhang, Huan ; Zhang, Wenbing ; Li, Zhi . Stability of delayed neural networks with impulsive strength-dependent average impulsive intervals. Journal of nonlinear sciences and its applications, Tome 11 (2018) no. 5, p. 602-612. doi : 10.22436/jnsa.011.05.02. http://geodesic.mathdoc.fr/articles/10.22436/jnsa.011.05.02/

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