Learning Process for Reducing Uncertainties on Network Parameters and Design Margins

E. Seve; J. Pesic; C. Delezoide; S. Bigo; Y. Pointurier

doi:10.1364/JOCN.10.00A298

Journal of Optical Communications and Networking
Vol. 10,
Issue 2,
pp. A298-A306
(2018)
•https://doi.org/10.1364/JOCN.10.00A298

Learning Process for Reducing Uncertainties on Network Parameters and Design Margins

E. Seve, J. Pesic, C. Delezoide, S. Bigo, and Y. Pointurier

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E. Seve, J. Pesic, C. Delezoide, S. Bigo, and Y. Pointurier, "Learning Process for Reducing Uncertainties on Network Parameters and Design Margins," J. Opt. Commun. Netw. 10, A298-A306 (2018)

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About this Article
History
- Original Manuscript: August 15, 2017
- Revised Manuscript: November 27, 2017
- Manuscript Accepted: December 7, 2017
- Published: February 1, 2018
Virtual Issues
Journal of Optical Communications and Networking OFC 2017 (2018)

Abstract

In this paper, we propose to lower the network design margins by improving the estimation of the signal-to-noise ratio (SNR) given by a quality of transmission (QoT) estimator, for new optical demands in a brownfield phase, based on a mathematical model of the physics of propagation. During the greenfield phase and the network operation, we collect and correlate information on the QoT input parameters, issued from the established initial demands and available almost for free from the network elements: amplifiers output power and the SNR at the coherent receiver side. Since we have some uncertainties on these input parameters of the QoT model, we use a machine learning algorithm to reduce them, improving the accuracy of the SNR estimation. With this learning process and for a European backbone network (28 nodes, 41 links), we could reduce the QoT inaccuracy by several dBs for new demands whatever the amount of uncertainties of the initial parameters.

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QoT Model	Cumulated Dispersion (Span Order)	Wavelength Allocation
SAMBA	Simple numerical evaluation	Computation for each wavelength allocation
EGN	No simple expression	Built-in dependence on wavelength allocation

QoT Input Parameters	Actual Values	Estimated Values
Input power	${P_{actual}}$	${P_{e}}$
	$N (μ_{p}, σ_{p})$	$N (μ_{p}, σ_{p})$
	$μ_{p} = 0 dBm$	$μ_{p} = [- 2, - 1, 0, 1, 2] dBm$
	$σ_{p} = 1 dBm$	$σ_{p} = 1 dBm$
Noise figure	${{NF}_{actual}}$	${{NF}_{e}}$
Noise figure	U [5,7] dB	5, 6, or 7 dB

QoT Model	Cumulated Dispersion (Span Order)	Wavelength Allocation
SAMBA	Simple numerical evaluation	Computation for each wavelength allocation
EGN	No simple expression	Built-in dependence on wavelength allocation

QoT Input Parameters	Actual Values	Estimated Values
Input power	${P_{actual}}$	${P_{e}}$
	$N (μ_{p}, σ_{p})$	$N (μ_{p}, σ_{p})$
	$μ_{p} = 0 dBm$	$μ_{p} = [- 2, - 1, 0, 1, 2] dBm$
	$σ_{p} = 1 dBm$	$σ_{p} = 1 dBm$
Noise figure	${{NF}_{actual}}$	${{NF}_{e}}$
Noise figure	U [5,7] dB	5, 6, or 7 dB

Learning Process for Reducing Uncertainties on Network Parameters and Design Margins

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Equations (5)

Journal of Optical Communications and Networking