Evaluation of entrainment of a nonlinear neural oscillator to white noise

29 October 2003

journal article
research article
Published by American Physical Society (APS) in Physical Review E

Vol. 68 (4) , 041915
https://doi.org/10.1103/physreve.68.041915

Abstract

The Lyapunov exponent for a one-dimensional neural oscillator model, the theta neuron, is computed for white noise forcing, using the steady-state solution to the associated Fokker-Planck equation. The latter is mildly singular, due to the nature of the multiplicative input. In agreement with previous results with similar models, the exponent is negative for all forcing amplitudes, but here it is shown to be small, relative to that for periodic drive, in a range of forcing strengths. Thus the synchronization of an ensemble of independent neurons receiving common but random input can be slow. Moreover, this implies that aperiodic input may be suboptimal, in some contexts, for preserving the reliability of fine spike timing, a potentially important component of the neural "code."

Keywords

This publication has 21 references indexed in Scilit:

Reliability of Spike Timing Is a General Property of Spiking Model Neurons
Neural Computation, 2003
Precision and reliability of periodically and quasiperiodically driven integrate-and-fire neurons
Physical Review E, 2002
The Reliability of the Stochastic Active Rotator
Neural Computation, 2002
Effects of noise coherence on stochastic resonance enhancement in a bithreshold system
Physical Review E, 2001
Synchronization of randomly driven nonlinear oscillators
Physical Review E, 1998
Influence of low and high frequency inputs on spike timing in visual cortical neurons
Cerebral Cortex, 1997
Reproducibility and Variability in Neural Spike Trains
Science, 1997
Type I Membranes, Phase Resetting Curves, and Synchrony
Neural Computation, 1996
Reliability of Spike Timing in Neocortical Neurons
Science, 1995
Stochastic resonance in an autonomous system with a nonuniform limit cycle
Physical Review E, 1994