Title :
On noise induced resonances in neurodynamic models
Author_Institution :
Div. of Comput. Sci., Memphis Univ., TN, USA
Abstract :
This work aims at studying dynamical models of neural networks, which exhibit transitions between quasistable states of various complexities. We use the biologically motivated KIII model, which is a high-dimensional dynamical system with extremely fragmented boundaries between limit cycles, tori, fixed points, and chaotic attractors. We study the role of additive noise in the development of itinerant trajectories. Noise broadens the region of the dominance of chaotic attractors. This result is especially useful in the application of KIII and makes it possible to select parameter regions where KIII can operate as a robust dynamic system and associative memory device.
Keywords :
brain models; cellular biophysics; chaos; content-addressable storage; neural nets; noise; time-varying systems; additive noise; associative memory device; chaotic attractors; high-dimensional dynamical system; itinerant trajectories; neural networks; neurodynamic models; noise induced resonance; Additive noise; Biological information theory; Biological neural networks; Biological system modeling; Chaos; Chromium; Limit-cycles; Neurodynamics; Stochastic resonance; Strontium;
Conference_Titel :
Neural Networks, 2004. Proceedings. 2004 IEEE International Joint Conference on
Print_ISBN :
0-7803-8359-1
DOI :
10.1109/IJCNN.2004.1381153
