Entraining power-dropout events in an external-cavity semiconductor laser using weak modulation of the injection current

Sukow, David W.; Gauthier, Daniel J.

doi:10.1109/3.823463

Cited by 63 publications

(61 citation statements)

References 62 publications

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“…Counterintuitively, this is possible even by nonresonant perturbations [21]. The more straightforward approach is by resonant parametric perturbations [22,23,24,25,26,27,28] which in the simplest case is a weak sinusoidal signal, but can be any periodic signal. Which orbits can be stabilized by which signals in general can be investigated only if an explicit model of the system is given.…”

Section: Passivation Effects: the Aging Conceptmentioning

confidence: 99%

Self-organized pore formation and open-loop control in semiconductor etching

Claussen

Carstensen

Christophersen

et al. 2003

Chaos: An Interdisciplinary Journal of Nonlinear Science

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Electrochemical etching of semiconductors, apart from many technical applications, provides an interesting experimental setup for self-organized structure formation capable e.g. of regular, diameter-modulated, and branching pores. The underlying dynamical processes governing current transfer and structure formation are described by the CurrentBurst-Model: all dissolution processes are assumed to occur inhomogeneously in time and space as a Current Burst (CB); the properties and interactions between CB's are described by a number of material-and chemistry-dependent ingredients, like passivation and aging of surfaces in different crystallographic orientations, giving a qualitative understanding of resulting pore morphologies. These morphologies cannot be influenced only by the current, by chemical, material and other etching conditions, but also by an open-loop control, triggering the time scale given by the oxide dissolution time. With this method, under conditions where only branching pores occur, the additional signal hinders side pore formation resulting in regular pores with modulated diameter.

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Section: Passivation Effects: the Aging Conceptmentioning

confidence: 99%

Self-organized pore formation and open-loop control in semiconductor etching

Claussen

Carstensen

Christophersen

et al. 2003

Chaos: An Interdisciplinary Journal of Nonlinear Science

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“…While the LK model has been shown to adequately reproduce the main statistical features of the LFF dynamics, such as the IDI distribution with and without modulation [19,29,30], it has also been shown that the LFFs are noise sustained in the LK model [23,24] (i.e., the LFFs are a transient dynamics that dies out when the trajectory finds a stable cavity mode, in deterministic simulations of the LK model). Therefore, it is remarkable that, in spite of the fact that the inclusion of noise is required for simulating sustained LFFs, the model adequately reproduces the symbolic dynamics, and in particular, the correlations present in the sequence of dropouts, and how they vary with the modulation amplitude.…”

Section: Introductionmentioning

confidence: 99%

“…In the LFF regime, the laser output intensity displays irregular, apparently random and sudden, dropouts. In particular, the LFF dynamics has been studied in detail when the laser current is periodically modulated [26,27], not only because the LFFs can be controlled via current modulation [28], but also, from a complex systems perspective, because the interplay of nonlinearity, noise, periodic forcing and delayed feedback leads to entrainment and synchronization [29,30], providing a controllable experimental setup for studying these phenomena. In addition, because the LFF dynamics is excitable, the influence of external forcing has also attracted attention from the point of view of improving our understanding of how excitable systems respond to external signals to encode information [31][32][33][34][35].…”

Section: Introductionmentioning

confidence: 99%

“…In this paper, we use a symbolic method of time-series analysis, referred to as ordinal analysis [1], to study the transition from the LFF dynamics of the unmodulated laser, in which the dropouts are highly stochastic and reveal only weak signatures of an underlying deterministic attractor [6], to the modulated LFF dynamics, which consists of more regular dropouts, with a periodicity that is related to external forcing period [29]. For increasing modulation amplitude there is a gradual transition from mainly stochastic to mainly deterministic behavior, and our goal is to identify in this transition characteristic features which are fingerprints of the underlying topology of the phase space of the system.…”

Section: Introductionmentioning

confidence: 99%

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Experimental and numerical study of the symbolic dynamics of a modulated external-cavity semiconductor laser

Aragoneses¹,

Sorrentino²,

Perrone³

et al. 2014

Opt. Express

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Abstract:We study the symbolic dynamics of a stochastic excitable optical system with periodic forcing. Specifically, we consider a directly modulated semiconductor laser with optical feedback in the low frequency fluctuations (LFF) regime. We use a method of symbolic time-series analysis that allows us to uncover serial correlations in the sequence of intensity dropouts. By transforming the sequence of inter-dropout intervals into a sequence of symbolic patterns and analyzing the statistics of the patterns, we unveil correlations among several consecutive dropouts and we identify clear changes in the dynamics as the modulation amplitude increases. To confirm the robustness of the observations, the experiments were performed using two lasers under different feedback conditions. Simulations of the Lang-Kobayashi (LK) model, including spontaneous emission noise, are found to be in good agreement with the observations, providing an interpretation of the correlations present in the dropout sequence as due to the interplay of the underlying attractor topology, the external forcing, and the noise that sustains the dropout events.

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“…Previous studies have demonstrated that introducing strong optical feedback into a frequency-modulated (direct or intracavity EOM) diode laser can enhance the modulation bandwidth [11]- [14], induce modal instabilities [14]- [17], produce mode-locked output pulses [18]- [23], frequency-locked states [24], low-frequency fluctuations [25], [26], and quasi-periodic [24] and chaotic output power [27], depending on the system operating parameters. No single study has considered the full range of parameters over which all of these states are observed.…”

mentioning

confidence: 99%

Nonlinear dynamics of a laser diode with optical feedback systems subject to modulation

Lawrence

Kane

2002

IEEE J. Quantum Electron.

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Abstract-The nonlinear dynamic behavior of a direct frequency-modulated diode laser with strong optical feedback is examined and compared to a laser diode subject to electro-optically modulated, strong optical feedback. Direct modulation is achieved by sinusoidal modulation of the diode laser injection current. Electro-optic modulation is achieved by applying a sinusoidal voltage to an intracavity phase modulating element. The output state (characterized by the output power versus time, the intensity noise spectrum and the optical frequency spectrum) for both types of modulation is dependent on the ratio of the modulation frequency to the external cavity resonant frequency, and the modulation power. A number of distinct states are observed: conventional amplitude modulation (with FM spectra); multimode, low-noise amplitude modulation; multimode, high-noise amplitude modulation; periodic limit-cycle operation; quasi-periodicity; chaos; low-frequency fluctuations; and mode-locking. There are significant differences between the direct and electro-optic frequency-modulation cases. The onset of the dynamic instability is characterized as a noisy period-one oscillation for direct modulation and a low-frequency fluctuation for intracavity electro-optic modulation. Phase portraits produced experimentally with the use of a digital phosphor oscilloscope are shown to agree well with those constructed from output power versus time data. This represents an experimental method for examining the dynamics phase portraits in real-time.

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Entraining power-dropout events in an external-cavity semiconductor laser using weak modulation of the injection current

Cited by 63 publications

References 62 publications

Self-organized pore formation and open-loop control in semiconductor etching

Self-organized pore formation and open-loop control in semiconductor etching

Experimental and numerical study of the symbolic dynamics of a modulated external-cavity semiconductor laser

Nonlinear dynamics of a laser diode with optical feedback systems subject to modulation

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