Associating machine-learning and analytical models for quality of transmission estimation: combining the best of both worlds

Emmanuel Seve; Jelena Pesic; Yvan Pointurier; Yvan Pointurier

doi:10.1364/JOCN.411979

Journal of Optical Communications and Networking
Vol. 13,
Issue 6,
pp. C21-C30
(2021)
•https://doi.org/10.1364/JOCN.411979

Associating machine-learning and analytical models for quality of transmission estimation: combining the best of both worlds

Emmanuel Seve, Jelena Pesic, and Yvan Pointurier

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Emmanuel Seve, Jelena Pesic, and Yvan Pointurier, "Associating machine-learning and analytical models for quality of transmission estimation: combining the best of both worlds," J. Opt. Commun. Netw. 13, C21-C30 (2021)

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Abstract

By associating machine learning and an analytical model (i.e., the Gaussian noise model), we reduce uncertainties on the output power profile and the noise figure of each amplifier in an optical network. We leverage the signal-to-noise ratio (SNR) of all the light paths of an optical network, monitored in all the coherent receivers. The learning process is based on a gradient-descent algorithm where all the uncertain input parameters of the analytical model are iteratively modified from their estimated values to match with the SNR of light paths in a European optical network. The design margin is then reduced to 0.1 dB for new traffic demands.

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Equations (6)

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QoT Param.	Actual Values	Estimated Values
A	${A_{a}} = U [0.75, 1.25]$	${A_{e}} = {A_{a}} + U [- Δ, Δ]$
B	${B_{a}} = 1 d B$ ^a or ${B_{a}} + = 1 d B$ ^b	${B_{e}} = {B_{a}} + U [0, Δ]$
C	${C_{a}} = 21$	${C_{e}} = {C_{a}} + U [0, Δ]$
NF	${{N F}_{a}} = U [5.5, 6.5] d B$	${{N F}_{e}} = 5 d B$

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Journal of Optical Communications and Networking