Litcius/Paper detail

High-fidelity sub-petabit-per-second self-homodyne fronthaul using broadband electro-optic combs

Chenbo Zhang, Yixiao Zhu, Jingjing Lin, Bibo He, Rongwei Liu, Yicheng Xu, Nuo Chen, Xuanjian He, Jinming Tao, Zhike Zhang, Tao Chu, Lilin Yi, Qunbi Zhuge, Weiwei Hu, Zhangyuan Chen, Weisheng Hu, Xiaopeng Xie

2024Nature Communications23 citationsDOIOpen Access PDF

Abstract

With the exponential growth in data density and user ends of wireless networks, fronthaul is tasked with supporting aggregate bandwidths exceeding thousands of gigahertz while accommodating high-order modulation formats. However, it must address the bandwidth and noise limitations imposed by optical links and devices in a cost-efficient manner. Here we demonstrate a high-fidelity fronthaul system enabled by self-homodyne digital-analog radio-over-fiber superchannels, using a broadband electro-optic comb and uncoupled multicore fiber. This self-homodyne superchannel architecture not only offers capacity boosting but also supports carrier-recovery-free reception. Our approach achieves a record-breaking 15,000 GHz aggregated wireless bandwidth, corresponding to a 0.879 Pb/s common public radio interface (CPRI) equivalent data rate. Higher-order formats up to 1,048,576 quadrature-amplitude-modulated (QAM) are showcased at a 100 Tb/s class data rate. Furthermore, we employ a packaged on-chip electro-optic comb as the sole optical source to reduce the cost, supporting a data rate of 100.5 Tb/s with the 1024-QAM format. These demonstrations propel fronthaul into the era of Pb/s-level capacity and exhibit the promising potential of integrated-photonics implementation, pushing the boundaries to new heights in terms of capacity, fidelity, and cost. Here the authors propose a self-homodyne fronthaul architecture, utilizing DA-RoF super channels and multicore fiber, paving the way for the Pb/s era in fronthaul transmission, enabling ultra-highspeed Internet access. The remarkable data speeds reaching 0.879 Pb/s and the 256-QAM format make it possible for 150,000 5G channels to be accessed simultaneously.

Topics & Concepts

BroadbandElectronic engineeringComputer scienceBandwidth (computing)Direct-conversion receiverPhotonicsRadio over fiberQuadrature amplitude modulationHomodyne detectionOptical fiberEngineeringTelecommunicationsElectrical engineeringChannel (broadcasting)PhysicsBit error rateOpticsAdvanced Fiber Laser TechnologiesAdvanced Photonic Communication SystemsPhotonic and Optical Devices
High-fidelity sub-petabit-per-second self-homodyne fronthaul using broadband electro-optic combs | Litcius