Title :
Stochastic resonance in discrete time nonlinear AR(1) models
Author :
Zozor, Steeve ; Amblard, Pierre-Olivier
Author_Institution :
Lab. des Images et des Signaux, CNRS, Saint Martin d´´Heres, France
fDate :
1/1/1999 12:00:00 AM
Abstract :
This paper deals with stochastic resonance. This nonlinear physical phenomenon generally occurs in bistable systems excited by random input noise plus a sinusoid. Through its internal dynamics, such a system forces cooperation between the input noise and the input sine: provided the existence of fine tuning between the power noise and the dynamics, the system reacts periodically at the frequency of the sine. Of particular interest is the fact that the local output signal-to-noise ratio presents a maximum when plotted against the input noise power; the system resounds stochastically. Continuous-time systems have already been studied. We study the ability of intrinsically discrete-time systems [general nonlinear AR(1) models] to produce stochastic resonance. It is then suggested that such discrete systems can be used in signal processing
Keywords :
autoregressive processes; discrete time systems; nonlinear systems; random noise; resonance; signal processing; SNR; bistable systems; correlation density function; digital signal processing; discrete time nonlinear AR(1) models; discrete-time systems; fine tuning; input sine; internal dynamics; local output signal-to-noise ratio; nonlinear physical phenomenon; power noise; random input noise; sine frequency; sinusoid; stochastic resonance; Frequency; Ice; Nonlinear dynamical systems; Power system modeling; Signal detection; Signal processing; Signal to noise ratio; Stochastic resonance; Strontium; Tuning;
Journal_Title :
Signal Processing, IEEE Transactions on
