Physical Layer Performance of Multi-Band Optical Line Systems Using Raman Amplification

M. Cantono; A. Ferrari; D. Pilori; E. Virgillito; J. L. Augé; V. Curri

doi:10.1364/JOCN.11.00A103

Journal of Optical Communications and Networking
Vol. 11,
Issue 1,
pp. A103-A110
(2019)
•https://doi.org/10.1364/JOCN.11.00A103

Physical Layer Performance of Multi-Band Optical Line Systems Using Raman Amplification

M. Cantono, A. Ferrari, D. Pilori, E. Virgillito, J. L. Augé, and V. Curri

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M. Cantono, A. Ferrari, D. Pilori, E. Virgillito, J. L. Augé, and V. Curri, "Physical Layer Performance of Multi-Band Optical Line Systems Using Raman Amplification," J. Opt. Commun. Netw. 11, A103-A110 (2019)

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About this Article
History
- Original Manuscript: July 31, 2018
- Revised Manuscript: September 24, 2018
- Manuscript Accepted: October 2, 2018
- Published: November 8, 2018
Virtual Issues
Journal of Optical Communications and Networking OFC 2018 (2019)

Abstract

Network operators are aiming to overcome the envisioned data traffic crunch by relying on already installed fiber cables. Multiband optical line systems (LSs) will thus be the solution, starting from the extension to C+L band transmission. Such a bandwidth extension also speeds up network disaggregation to avoid an increase in costs. Thus, LS controllers need quality-of-transmission estimator (QoT-E) modules capable of quickly estimating the merit of lightpaths, and so analytical models for the transmission layer are mandatory. We review the generalized Gaussian noise (GGN) model for wideband prediction of nonlinear interference generation and validate its accuracy by comparing C+L simulative results to model predictions. Results are obtained for the case of amplification using a hybrid Raman and erbium-doped fiber amplifier, and display excellent conservative accuracy. We also present an experimental validation performed on commercial equipment that confirms how the GGN model is the most feasible solution for QoT-E modules in multiband LS controllers, enabling a frequency-resolved minimization of system margins.

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M. Cantono	https://orcid.org/0000-0001-8619-4480
A. Ferrari	https://orcid.org/0000-0001-9483-3975
D. Pilori	https://orcid.org/0000-0003-4499-8573
V. Curri	https://orcid.org/0000-0003-0691-0067

Parameter	Value
Span length	$L_{s} = 80 km$
Maximum number of spans	$N_{s} = 10$
Chromatic dispersion	$D = 16.7 ps / nm / km$
Nonlinear coefficient	$γ = 1.3 1 / W / km$
Polarization averaged Raman coefficient	$C_{r} = 0.39 1 / W / km$
Polynomial coefficients of $α (f)$ around	$α_{0} = 0.19 dB / km$
$f_{0} = 193.6 THz$	$α_{1} = 5.97 \times 10^{- 5} dB / km / THz$
$f_{0} = 193.6 THz$	$α_{2} = 8.3 \times 10^{- 4} dB / km / {THz}^{2}$

Frequency (THz)	Power (mW)
201.07	250
202.43	300
203.11	150
203.80	150
204.50	150

Parameter	Value
Span length	$L_{s} = 80 km$
Maximum number of spans	$N_{s} = 10$
Chromatic dispersion	$D = 16.7 ps / nm / km$
Nonlinear coefficient	$γ = 1.3 1 / W / km$
Polarization averaged Raman coefficient	$C_{r} = 0.39 1 / W / km$
Polynomial coefficients of $α (f)$ around	$α_{0} = 0.19 dB / km$
$f_{0} = 193.6 THz$	$α_{1} = 5.97 \times 10^{- 5} dB / km / THz$
$f_{0} = 193.6 THz$	$α_{2} = 8.3 \times 10^{- 4} dB / km / {THz}^{2}$

Frequency (THz)	Power (mW)
201.07	250
202.43	300
203.11	150
203.80	150
204.50	150

Physical Layer Performance of Multi-Band Optical Line Systems Using Raman Amplification

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Abstract

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Figures (9)

Tables (2)

Equations (5)

Journal of Optical Communications and Networking