Modeling of gain dynamics in erbium-doped fiber amplifiers

Sun, Yan; Luo, Chien Ming; Zyskind, J.L.; Saleh, A.A.M.; Srivastava, Ashutosh; Sulhoff, J.W.

doi:10.1109/leos.1996.571930

Cited by 7 publications

(23 citation statements)

References 1 publication

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“…Habbab et al [6] arrived at a linear approximation for the small signal gain in single-channel amplifiers. More recently, Sun et al [1] at Bell Laboratories have succeeded in reducing the system of coupled differential equations into a single ordinary differential equation (ODE).…”

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confidence: 99%

Doped-fiber amplifier dynamics: a system perspective

Bononi

Rusch

1998

J. Lightwave Technol.

114

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Abstract-Sun et al.[1] succeeded in reducing the set of coupled first-order nonlinear partial differential equations determining the wavelength-dependent, time-varying amplifier gain into a single ordinary differential equation (ODE). In this paper, we further simplify the ODE bringing into greater evidence the physical meaning of the amplification process, and greatly enhancing the utility of the ODE as an analysis and design tool. We find that the gain dynamics of a doped-fiber amplifier are completely specified by its total number of excited ions r, whose time behavior is described by a simple first-order differential equation. We exploit this new understanding of amplifier gain dynamics: 1) to develop an equivalent circuit model for amplifier gain dynamics, 2) to identify that channel addition causes much faster transients than channel dropping in wavelength division multiplexing networks, and 3) to demonstrate that gain excursions can be significant in multichannel packet switching applications, which unlike timemultiplexed signals are characterized by bursts and lulls in communications. We are also able to revisit the most significant previously published results on both steady-state and dynamic analysis of doped-fiber amplifiers with a much more concise and more intuitive derivation.Index Terms-Doped-amplifier gain dynamics, EDFA, packet switching.

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confidence: 99%

Doped-fiber amplifier dynamics: a system perspective

Bononi

Rusch

1998

J. Lightwave Technol.

114

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“…This model has been verified experimetally and provides a good description of transients on time scales of fractions of microseconds [1]- [4].…”

Section: Simulation Modelmentioning

confidence: 78%

“…The EDFA transient time response to input power change was calculated numerically solving a system of differential equations by using a fast Runge-Kutta method [1], calculated in 10 points per individual cell. The calculated output power on slots carrying a cell was arranged in a histogram comprising 500 bins of width 0.04 dBm, uniformly tiling the range between 1 and 21 dBm.…”

Section: Simulation Modelmentioning

confidence: 99%

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Large power swings in doped-fiber amplifiers with highly variable data

Bononi

Tancevski²,

Rusch

1999

IEEE Photon. Technol. Lett.

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“…For the PG amplifier where the amplifier fiber length is about 10 cm, the propagation time is about 0.5 ns, which may be safely ignored for the input pulse duration of several nanometers. It is also noteworthy that the effect of propagation is in many cases ignorable so that many published modeling/simulation do not even include the time derivative in the power propagation from the beginning [10], [28], [29], [30], [31]. We also developed a full partial differential equation solver using the upwind and downwind combo method where the forward signal and pump is solved on upwind scheme whereas the backward signal and pump is solved on downwind scheme.…”

Section: Summary Of Numerical Simulator Developmentmentioning

confidence: 99%

Large core highly doped fiber amplifiers.

Dansson¹,

Moore²,

Soh³

et al. 2012

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We have demonstrated amplification of nanosecond optical pulses to the millijoule level using ytterbium-doped phosphate glass fibers. Fibers with 35 um and 49 um diameter cores produced up to 700 uJ and 2.25 mJ pulses, respectively, with pulse durations less than 10 ns. By tapering the diameter of the fiber from single-mode to multi-mode, we were able to produce output with a nearly lowest-order-mode spatial profile in 35 um-core fibers that were inherently multimode. We report on progress in five areas of amplifier development: (1) pulse energy, (2) fundamental mode propagation in multi-mode fibers, (3) phosphate glass fiber processing, (4) highly doped gain fiber modeling, and (5) amplification of single-frequency pulses at 2 um wavelength. 4 ACKNOWLEDGMENTS

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Modeling of gain dynamics in erbium-doped fiber amplifiers

Cited by 7 publications

References 1 publication

Doped-fiber amplifier dynamics: a system perspective

Doped-fiber amplifier dynamics: a system perspective

Large power swings in doped-fiber amplifiers with highly variable data

Large core highly doped fiber amplifiers.

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