Litcius/Paper detail

S-, C- and L-band transmission over a 157 nm bandwidth using doped fiber and distributed Raman amplification

Benjamin J. Puttnam, Ruben S. Luís, Georg Rademacher, Manuel Mendez-Astudillio, Yoshinari Awaji, Hideaki Furukawa

2022Optics Express97 citationsDOIOpen Access PDF

Abstract

We investigate optical transmission of an ultra-wideband signal in a standard single mode fiber. Using a near continuous optical bandwidth exceeding 157 nm across the S-, C- and L-bands, we combine doped-fiber amplifiers covering S, C and L-bands with distributed Raman amplification to enable high-quality transmission of polarization division multiplexed (PDM)-256-quadrature-amplitude modulation (QAM) signals over a 54 km standard single-mode fiber. We receive 793 × 24.5 GBd signals from 1466.34 nm to 1623.57 nm and measure a data rate estimated from the generalized mutual information (GMI) of 256.4 Tb/s and an LDPC decoded throughput of 244.3 Tb/s. The measured data rates exceed the highest previously measured in a single mode fiber, showing the potential for S-band transmission to enhance achievable data rates in optical fibers.

Topics & Concepts

Raman amplificationMaterials scienceBandwidth (computing)OpticsMultiplexingOptical amplifierWavelength-division multiplexingSingle-mode optical fiberTransmission (telecommunications)Optical fiberOptoelectronicsAmplifierRaman spectroscopyData transmissionOptical communicationPolarization (electrochemistry)Multi-mode optical fiberModulation (music)Signal processingGigabitPhase modulationAmplified spontaneous emissionRaman scatteringOrthogonal frequency-division multiplexingSIGNAL (programming language)Transmission systemFiber-optic communicationErbium doped fiber amplifierPolarization-maintaining optical fiberChannel spacingOptical Network TechnologiesAdvanced Photonic Communication SystemsAdvanced Fiber Optic Sensors