Analysis of the BSB Model Dynamics Using Control Theory
Neural Processing Letters
Multiple almost periodic solutions in nonautonomous delayed neural networks
Neural Computation
Automatica (Journal of IFAC)
Stability and Convergence of Mechanical Systems with Unilateral Constraints
Stability and Convergence of Mechanical Systems with Unilateral Constraints
International Journal of Systems Science
Equilibrium Analysis for Improved Signal Range Model of Delayed Cellular Neural Networks
Neural Processing Letters
New genetic operators in the fly algorithm: application to medical PET image reconstruction
EvoApplicatons'10 Proceedings of the 2010 international conference on Applications of Evolutionary Computation - Volume Part I
Automatica (Journal of IFAC)
Automatica (Journal of IFAC)
CNN hyperchaotic synchronization with applications to secure communication
ISNN'12 Proceedings of the 9th international conference on Advances in Neural Networks - Volume Part II
Delay-Dependent Exponential Stability of Cellular Neural Networks with Multi-Proportional Delays
Neural Processing Letters
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Synchronization of cellular neural networks with time-varying delay is discussed in this letter. Based on Razumikhin theorem, a guaranteed cost synchronous controller is given. Unlike Lyapunov-Krasovskii analysis process, there is no constraint on the change rate of time delay. The saturated terms emerging in the Razumikhin analysis are amplified by zoned discussion and maximax synthesis rather than by Lipschitz condition and vector inequality, which will bring more conservatism. Then the controller criterion is transformed from quadratic matrix inequality form into linear matrix inequality form, with the help of a sufficient and necessary transformation condition. The minimization of the guaranteed cost is studied, and a further criterion for getting the controller is presented. Finally, the guaranteed cost synchronous control and its corresponding minimization problem are illustrated with examples of chaotic time-varying delay cellular neural networks.