DSP-Based Link Tomography for Amplifier Gain Estimation and Anomaly Detection in C+L-Band Systems

A successful migration from current C-band based optical networks to a multiband scenario primarily depends on the development of solutions that can reliably measure physical properties of optical links over broad spectral transmission windows. Additionally, these solutions must be capable of delive...

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Veröffentlicht in:	Journal of lightwave technology 2022-06, Vol.40 (11), p.3395-3405
Hauptverfasser:	Sena, Matheus, Emmerich, Robert, Shariati, Behnam, Santos, Caio, Napoli, Antonio, Fischer, Johannes K., Freund, Ronald
Format:	Artikel
Sprache:	eng
Schlagworte:	Amplification Amplifiers Anomalies Anomaly detection C band C+L-band Digital signal processing Doped fibers Erbium Fault detection fiber nonlinearity Monitoring Narrowband Optical communication Optical fiber amplifiers Optical fiber devices Optical fiber networks Optical fibers optical performance monitoring Optical properties Optical receivers Personal protective equipment Physical properties Power Spectrum analysers Tomography
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container_title	Journal of lightwave technology
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creator	Sena, Matheus Emmerich, Robert Shariati, Behnam Santos, Caio Napoli, Antonio Fischer, Johannes K. Freund, Ronald
description	A successful migration from current C-band based optical networks to a multiband scenario primarily depends on the development of solutions that can reliably measure physical properties of optical links over broad spectral transmission windows. Additionally, these solutions must be capable of delivering wavelength-dependent and spatially-resolved indicators that can empower network operators to identify faults before they lead to severe service disruptions. Recently, the exploitation of receiver based digital signal processing as a tool for optical performance monitoring has gained tremendous popularity. One successful example is the so-called in-situ power profile estimator, which can reconstruct the per-channel longitudinal power profile along the optical fiber link solely processing the received signal samples. In this work, we propose a novel application for the in-situ power profile estimator by harnessing it on multiple wavelengths to accurately estimate the spectral gain profile of C+L-band in-line Erbium-doped fiber amplifiers deployed in a 280-km single mode fiber link. Furthermore, we show how this scheme can be efficiently used to detect amplification-related anomalies, such as gain tilt and narrowband gain compression. In our measurements, we achieved a sub-dB estimation accuracy by comparing the proposed gain extraction approach with the back-to-back characterization obtained from an optical spectrum analyzer.
doi_str_mv	10.1109/JLT.2022.3160101
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subjects	Amplification Amplifiers Anomalies Anomaly detection C band C+L-band Digital signal processing Doped fibers Erbium Fault detection fiber nonlinearity Monitoring Narrowband Optical communication Optical fiber amplifiers Optical fiber devices Optical fiber networks Optical fibers optical performance monitoring Optical properties Optical receivers Personal protective equipment Physical properties Power Spectrum analysers Tomography
title	DSP-Based Link Tomography for Amplifier Gain Estimation and Anomaly Detection in C+L-Band Systems
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