Boundedness and global exponential stability for generalized Cohen–Grossberg neural networks with variable delay. (English) Zbl 1090.92004
Summary: A generalized Halanay inequality is established, and the boundedness of generalized Cohen-Grossberg neural networks [M. A. Cohen and S. Grossberg, IEEE Trans. Syst. Man Cybern. 13, 815–826 (1983; Zbl 0553.92009)] is investigated. By applying the generalized Halanay inequality and Lyapunov functional methods, new sufficient conditions are obtained ensuring the global exponential stability of solutions of generalized Cohen-Grossberg neural networks with variable delay. Three examples are also given for illustration.
MSC:
| 92B20 | Neural networks for/in biological studies, artificial life and related topics |
| 68T05 | Learning and adaptive systems in artificial intelligence |
| 34K20 | Stability theory of functional-differential equations |
| 34D23 | Global stability of solutions to ordinary differential equations |
| 34K60 | Qualitative investigation and simulation of models involving functional-differential equations |
Keywords:
Cohen-Grossberg neural networks; Global exponential stability; Halanay inequality; Dini derivativeCitations:
Zbl 0553.92009References:
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