2004
DOI: 10.1103/physrevlett.93.224101
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Synchronization by Nonlinear Frequency Pulling

Abstract: We analyze a model for the synchronization of nonlinear oscillators due to reactive coupling and nonlinear frequency pulling motivated by the physics of arrays of nanoscale oscillators. We study the model for the mean field case of all-to-all coupling, deriving results for the onset of synchronization as the coupling or nonlinearity increase, and the fully locked state when all the oscillators evolve with the same frequency.PACS numbers: 85.85.+j, 05.45.Xt, 62.25.+g In the last decade we have witnessed exci… Show more

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Cited by 137 publications
(144 citation statements)
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“…The collective response of coupled arrays might be useful for signal enhancement and noise reduction [21,22], as well as for sophisticated mechanical signal processing applications. Such arrays have already exhibited interesting nonlinear dynamics, ranging from the formation of extended patterns [8,38], as one commonly observes in analogous continuous systems such as Faraday waves, to that of intrinsically localized modes [39,[58][59][60].…”
Section: Why Study Nonlinear Nems and Mems?mentioning
confidence: 99%
“…The collective response of coupled arrays might be useful for signal enhancement and noise reduction [21,22], as well as for sophisticated mechanical signal processing applications. Such arrays have already exhibited interesting nonlinear dynamics, ranging from the formation of extended patterns [8,38], as one commonly observes in analogous continuous systems such as Faraday waves, to that of intrinsically localized modes [39,[58][59][60].…”
Section: Why Study Nonlinear Nems and Mems?mentioning
confidence: 99%
“…When used in the linear regime, non-linearity limits the dynamic range of a device [3]. One can also exploit non-linearity with for instance frequency mixing [4], synchronization [5], amplification using bifurcation points [6], suppression of amplifier noise in oscillator circuits [7][8][9], and mass (homodyne) detection [10]. Moreover, the non-linear component proves to be essential to complex, useful and efficient designs, with for instance the diode in conventional electronics and the Josephson junction in superconducting circuitry [11].…”
Section: Introductionmentioning
confidence: 99%
“…The most commonly discussed cases are non-linear actuation with an electrostatic drive [19,20], and non-linear constituents (with i.e. an x 2 term in the damping [1,5,9]). Clever designs making use of these non-linearities enable parametric amplification [21,22], and parametric drive [23].…”
Section: Introductionmentioning
confidence: 99%
“…Figure 3d shows that the value of α 3 is proportional to the power of the tuning laser for both softening (red) and hardening (blue) situations, as expected from theoretical analysis. The rich and completely controllable optomechanical nonlinearity in cavity optomechanics, demonstrated here for the first time, can be harnessed to explore nonlinear phenomena in nanomechanical oscillators 29 , including parametric amplification 32 , synchronization 33 and stochastic dynamics 34,35 .…”
Section: Resultsmentioning
confidence: 94%