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Numerical investigation of a feed-forward linewidth reduction scheme using a mode-locked laser model of reduced complexity

O'Duill, Sean orcid logoORCID: 0000-0002-7690-4474, Sahni, M. Omar, Trebaol, Stéphane orcid logoORCID: 0000-0002-8104-1669, Landais, Pascal orcid logoORCID: 0000-0002-4807-0695, Bramerie, Laurent orcid logoORCID: 0000-0002-5182-1285, Murdoch, Stuart G. orcid logoORCID: 0000-0002-9169-9472, Besnard, Pascal orcid logoORCID: 0000-0003-3937-7035 and Barry, Liam P. orcid logoORCID: 0000-0001-8366-4790 (2018) Numerical investigation of a feed-forward linewidth reduction scheme using a mode-locked laser model of reduced complexity. Applied Optics, 57 (22). pp. 89-100. ISSN 0003-6935

Abstract
We provide numerical verification of a feed-forward, heterodyne-based phase noise reduction scheme using single-sideband modulation that obviates the need for optical filtering at the output. The main benefit of a feed-forward heterodyne linewidth reduction scheme is the simultaneous reduction of the linewidth of all modes of a mode-locked laser (MLL) to that of a narrow-linewidth single-wavelength laser. At the heart of our simulator is an MLL model of reduced complexity. Importantly, the main issue being treated is the jitter of MLLs and we show how to create numerical waveforms that mimic the random-walk nature of timing jitter of pulses from MLLs. Thus, the model does not need to solve stochastic differential equations that describe the MLL dynamics, and the model calculates self-consistently the line-broadening of the modes of the MLL and shows good agreement with both the optical linewidth and jitter. The linewidth broadening of the MLL modes are calculated after the phase noise reduction scheme and we confirm that the phase noise contribution from the timing jitter still remains. Finally, we use the MLL model and phase noise reduction simulator within an optical communications system simulator and show that the phase noise reduction technique could enable MLLs as optical carriers for higher-order modulation formats, such as 16-state and 64-state quadrature amplitude modulation.
Metadata
Item Type:Article (Published)
Refereed:Yes
Subjects:Engineering > Optical communication
Physical Sciences > Lasers
Physical Sciences > Optoelectronics
Physical Sciences > Photonics
DCU Faculties and Centres:DCU Faculties and Schools > Faculty of Engineering and Computing > School of Electronic Engineering
Publisher:Optical Society of America
Official URL:https://doi.org/10.1364/AO.57.000E89
Copyright Information:© 2017 Optical Society of America
Use License:This item is licensed under a Creative Commons Attribution-NonCommercial-Share Alike 3.0 License. View License
Funders:Science Foundation Ireland (SFI) (12/RC/2276), Irish Research Council (Ulysses)
ID Code:24226
Deposited On:19 Feb 2020 16:23 by Pascal Landais . Last Modified 19 Feb 2020 16:23
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