Non-Boltzmann dynamics in networks of spiking neurons

Author

Crair, Michael C. ; Bialek, William

Author_Institution

Dept. of Phys., California Univ., Berkeley, CA, USA

fYear

1991

fDate

18-21 Nov 1991

Firstpage

2508

Abstract

Networks of spiking neurons in which spikes are fired as a Poisson process are studied. The state of a cell is determined by the instantaneous firing rate, and in the limit of high firing rates the model reduces to that studied by Hopfield. The inclusion of spiking results in several features including a noise-induced asymmetry between on and off states, and probability currents which destroy the usual description of network dynamics in terms of energy surfaces. Taking account of spikes also allows calibration of network parameters such as synaptic weights against experiments on real synapses. Realistic forms of the post-synaptic response alter the network dynamics, which suggests a dynamical learning mechanism

Keywords

neural nets; random processes; Hopfield neural net; Poisson process; instantaneous firing rate; noise-induced asymmetry; nonBoltzmann dynamics; probability currents; spiking neuron networks; synaptic weights; Biological cells; Biological information theory; Biological system modeling; Computer networks; Intelligent networks; Learning systems; Mirrors; Neural networks; Neurons; Physics;

fLanguage

English

Publisher

ieee

Conference_Titel

Neural Networks, 1991. 1991 IEEE International Joint Conference on

Print_ISBN

0-7803-0227-3

Type

conf

DOI

10.1109/IJCNN.1991.170766

Filename

170766