Litcius/Paper detail

Multi-Band ESCL Transmission Supported by Bismuth-Doped and Raman Fiber Amplification

Aleksandr Donodin, Elliot London, Bruno Correia, Emanuele Virgillito, Mingming Tan, Pratim Hazarika, Ian Phillips, Paul Harper, Sergei K. Turitsyn, Vittorio Curri, W. Forysiak

2023Journal of Lightwave Technology14 citationsDOI

Abstract

Ultra-wideband transmission utilizesbandwidths beyond the standard C-band to enable significant network capacity upgrades. Upgrading the standard C-band to a C+L-band transmission scenario is already feasible, and exploratory transmission is being performed in the S-, E-, and O-bands to investigate quality of transmission (QoT) impairments in these spectral regions. In this article, experimental transmission through a SCL- and partial E-band spectral region is performed, with use of a hybrid amplifier that exploits discrete Raman amplification for the SCL-bands, and a bismuth-doped fiber amplifier (BDFA) for the E-band. Through this transmission bandwidth, we demonstrate that 36 Tbit/s transmission is possible, with 150 coherent channels over 70 km of standard, single-mode fiber. This result is compared to a wideband physical layer model that considers a realistic full spectral load transmission scenario, where the E-band is occupied by 74 channels, providing a total of 221 channels. This comparison demonstrates that, for both scenarios in this experiment, the greatest impairment is present within the S-band, and the addition of the E-band to a SCL-band scenario has a negligible impact upon the QoT within the C- and L-bands.

Topics & Concepts

BismuthRaman amplificationMaterials scienceDopingRaman spectroscopyOptical fiberOptoelectronicsTransmission (telecommunications)OpticsRaman scatteringTelecommunicationsPhysicsComputer scienceMetallurgyOptical Network TechnologiesAdvanced Optical Network TechnologiesPhotonic and Optical Devices