Characterization of nonlinear switching in a figure-of-eight fiber laser using frequency-resolved optical gating

Bollond, P.G.; Barry, Liam P.; Dudley, John M.; Leonhardt, R.; Harvey, J.D.

doi:10.1109/68.661404

Cited by 9 publications

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“…In Section II, we report the characterization of three different sources of picosecond pulses around 1550 nm: a figure-of-eight erbiumdoped fiber laser [11], a single-mode gain-switched InGaAsP semiconductor laser [12], and a dual-mode gain-switched InGaAsP semiconductor laser [13]. We also describe experiments studying pulse compression in dispersion-compensating fiber.…”

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Complete characterization of ultrashort pulse sources at 1550 nm

Dudley

Barry

Harvey

et al. 1999

IEEE J. Quantum Electron.

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Abstract-This paper reviews the use of frequency-resolved optical gating (FROG) to characterize mode-locked lasers producing ultrashort pulses suitable for high-capacity optical communications systems at wavelengths around 1550 nm. Secondharmonic generation (SHG) FROG is used to characterize pulses from a passively mode-locked erbium-doped fiber laser, and both single-mode and dual-mode gain-switched semiconductor lasers. The compression of gain-switched pulses in dispersion compensating fiber is also studied using SHG-FROG, allowing optimal compression conditions to be determined without a priori assumptions about pulse characteristics. We also describe a fiberbased FROG geometry exploiting cross-phase modulation and show that it is ideally suited to pulse characterization at optical communications wavelengths. This technique has been used to characterize picosecond pulses with energy as low as 24 pJ, giving results in excellent agreement with SHG-FROG characterization, and without any temporal ambiguity in the retrieved pulse.

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confidence: 99%