Cogprints
Login | Create Account

Controlling chaos in a chaotic neural network

He, Dr G. and Cao, Prof. Z. and Zhu, Prof. P. and Ogura, Prof. H. (2003) Controlling chaos in a chaotic neural network. [Journal (Paginated)] (In Press)

Full text available as:

[img]
Preview
PDF
174Kb

Abstract

The chaotic neural network constructed with chaotic neuron shows the associative memory function, but its memory searching process cannot be stabilized in a stored state because of the chaotic motion of the network. In this paper, a pinning control method focused on the chaotic neural network is proposed. The computer simulation proves that the chaos in the chaotic neural network can be controlled with this method and the states of the network can converge in one of its stored patterns if the control strength and the pinning density are chosen suitable. It is found that in general the threshold of the control strength of a controlled network is smaller at higher pinned density and the chaos of the chaotic neural network can be controlled more easily if the pinning control is added to the variant neurons between the initial pattern and the target pattern.

Item Type:Journal (Paginated)
Keywords:Chaotic dynamic; Chaotic neural network; Controlling chaos; Pinning control method
Subjects:Computer Science > Dynamical Systems
Computer Science > Neural Nets
Computer Science > Artificial Intelligence
ID Code:3001
Deposited By:He, Dr Guoguang
Deposited On:06 Apr 2004
Last Modified:12 Sep 2007 17:47

References in Article

Select the SEEK icon to attempt to find the referenced article. If it does not appear to be in cogprints you will be forwarded to the paracite service. Poorly formated references will probably not work.

1. Aihara, K., Takabe, T., & Toyoda, M. (1990). Chaotic Neural Networks. Phys. Lett. A, 144, 333-340.

2. Adachi, M., & Aihara, K. (1997). Associative Dynamics in a Chaotic Neural Network.. Neural Networks, 10, 83-98.

3. Tokuda, I., Nagashima, T. & Aihara, K. (1997). Global Bifurcation Structure of Chaotic Neural Networks and Its Application to Traveling Salesman Problem. Neural Networks, 10, 1673-1690.

4. Freeman, W. J. (1987). Simulation of chaotic EEG patterns with a dynamic model of the olfactory system. Biological Cybernetics, 56, 139-150.

5. Degn, H., Holden, A. V. & Olsen L. F. (Eds.),(1987). Chaos in biological systems. New York: Plenum.

6. Tsuda, I. (1991). Chaotic itinerancy as a dynamical basis of hermeneutics in brain and mind. World Futures, 32, 167-184.

7. Kobori, E. R., Ikoda, K. & Nakayama, K. (1996). Model of dynamic associative memory. IEEE International Conference on Neural Networks Conference Proceedings, 2, 804-809.

8. Ott, E., Grebogi, C. & Yorke, J. A. (1990). Controlling Chaos. Phys. Rev. Lett., 64, 1196-1199.

9. Pecora, L. M. & Carroll, T. L. (1990). Synchronization in Chaotic Systems. Phys. Rev. Lett., 64, 821-824.

10. Hunt, E R. (1991). Stabling High-Period Orbits in a Chaotic System: the Diode Resonator. Phys. Rev. Lett., 67, 1953-1955.

11. Pyragas, K. (1992). Continuous Control of Chaos by Self-Controlling Feedback. Phys. Lett. A, 170, 421-428.

12. Hu G., & Qu Z. (1994). Controlling Spatiotemporal Chaos in Coupled Map Lattice Systems. Phys. Rev. Lett., 72, 68-77.

13. Adachi, M. (1995). Controlling a Simple Chaotic Neural Network using response to perturbation. Proc. NOLTA’95, 989-992.

14. Mizutani, S., Sato, T., Uchiyama, T. & Sonehara, N. (1995). Controlling Chaos in Neural Networks, Proc. ICNN, Perth 6, 3038-3043.

15. Shimada, I., & Nagashima, T. (1979). A numerical approach to ergodic problem of dissipative dynamical systems. Progress of Theoretical Physics, 61, 1605-1616

Metadata

Repository Staff Only: item control page

Cogprints is powered by EPrints 3 which is developed by the School of Electronics and Computer Science at the University of Southampton. More information and software credits.