TY - JOUR
T1 - Amplitude and phase effects on the synchronization of delay-coupled oscillators
AU - D'Huys, Ottilde
AU - FISCHER Bert, Ingo
AU - Danckaert, Jan
AU - Vicente, Roberto
PY - 2010
Y1 - 2010
N2 - We consider the behavior of Stuart-Landau oscillators as generic limit-cycle oscillators when they are interacting with delay. We investigate the role of amplitude and phase instabilities in producing symmetry-breaking/restoring transitions. Using analytical and numerical methods we compare the dynamics of one oscillator with delayed feedback, two oscillators mutually coupled with delay, and two delay-coupled elements with self-feedback. Taking only the phase dynamics into account, no chaotic dynamics is observed, and the stability of the identical synchronization solution is the same in each of the three studied networks of delay-coupled elements. When allowing for a variable oscillation amplitude, the delay can induce amplitude instabilities. We provide analytical proof that, in case of two mutually coupled elements, the onset of an amplitude instability always results in antiphase oscillations, leading to a leader-laggard behavior in the chaotic regime. Adding self-feedback with the same strength and delay as the coupling stabilizes the system in the transverse direction and, thus, promotes the onset of identically synchronized behavior. (C) 2010 American Institute of Physics. [doi:10.1063/1.3518363]
AB - We consider the behavior of Stuart-Landau oscillators as generic limit-cycle oscillators when they are interacting with delay. We investigate the role of amplitude and phase instabilities in producing symmetry-breaking/restoring transitions. Using analytical and numerical methods we compare the dynamics of one oscillator with delayed feedback, two oscillators mutually coupled with delay, and two delay-coupled elements with self-feedback. Taking only the phase dynamics into account, no chaotic dynamics is observed, and the stability of the identical synchronization solution is the same in each of the three studied networks of delay-coupled elements. When allowing for a variable oscillation amplitude, the delay can induce amplitude instabilities. We provide analytical proof that, in case of two mutually coupled elements, the onset of an amplitude instability always results in antiphase oscillations, leading to a leader-laggard behavior in the chaotic regime. Adding self-feedback with the same strength and delay as the coupling stabilizes the system in the transverse direction and, thus, promotes the onset of identically synchronized behavior. (C) 2010 American Institute of Physics. [doi:10.1063/1.3518363]
KW - LIMIT-CYCLE OSCILLATORS; SEMICONDUCTOR-LASERS
KW - OPTICAL FEEDBACK; SYMMETRY-BREAKING;
KW - POL OSCILLATORS; TIME-DELAY
KW - DYNAMICS; SYSTEMS; COHERENCE; ARRAYS
M3 - Article
VL - 20
JO - Chaos
JF - Chaos
SN - 1054-1500
M1 - 043127
ER -