Stochastic resonance and bifurcation of order parameter in a coupled system of underdamped Duffing oscillators
Ruonan Liu, Yanmei Kang, Yuxuan Fu, Guanrong Chen

TL;DR
This paper studies how noise and coupling influence resonance and bifurcation in a system of underdamped Duffing oscillators, revealing conditions for optimal signal amplification and the role of the order parameter.
Contribution
It introduces a comprehensive analysis of stochastic resonance and bifurcation in coupled underdamped Duffing oscillators, including new insights into resonance behaviors and the influence of damping and noise.
Findings
Both mono-peak and double-peak resonance can occur.
Noise significantly enhances resonance peaks compared to single oscillators.
Resonance peaks are maximized at critical noise intensity or coupling strength.
Abstract
The long-term mean-field dynamics of coupled underdamped Duffing oscillators driven by an external periodic signal with Gaussian noise is investigated. A Boltzmann-type H-theorem is proved for the associated nonlinear Fokker-Planck equation to ensure that the system can always be relaxed to one of the stationary states as time is long enough. Based on a general framework of the linear response theory, the linear dynamical susceptibility of the system order parameter is explicitly deduced. With the spectral amplification factor as a quantifying index, calculation by the method of moments discloses that both mono-peak and double-peak resonance might appear, and that noise can greatly signify the peak of the resonance curve of the coupled underdamped system as compared with a single-element bistable system. Then, with the input signals taken from laboratory experiments, further…
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