Wavelength Resource Sharing in Bidirectional Optical Mobile Fronthaul

Zhu, Meifang; Li, Fan; Lü, Feng; Yu, Jianjun; Su, Charles; Gu, Gordon; Chang, Gee‐Kung

doi:10.1109/jlt.2015.2428226

Cited by 19 publications

(3 citation statements)

References 7 publications

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“…Technical aspects that remain to be solved are the stability of the LO and the necessity for DSP, rendering these systems as rather challenging to port from the realm of metrocore networks to optical fronthaul applications. Table I puts into perspective the proposed EML+TIA based receiver with state-of-the-art works on RoF transmission [7][8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23][24][25][26]. There is an increased interest in A-RoF, with many works targeting transmission through IFoF and RFoF principles, using either IM/DD or coherent detection.…”

Section: Radio-over-fiber Transmissionmentioning

confidence: 99%

Simplified Coherent Receiver for Analogue Radio Transmission Over High Optical Budgets

Milovančev

Vokić

Karinou

et al. 2021

J. Lightwave Technol.

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The bandwidth and latency demands driven by 5G wireless networks are putting a focus on analog radio-over-fiber techniques as a promising candidate for broadband optical fronthauling. In contrast to intensity modulation / direct detection systems, as they are commonly adopted for mobile fronthaul links due to their simplicity, we are exploring a migration option towards coherent radio-over-fiber transmission. A simplified coherent homodyne receiver based on an electroabsorption modulated laser is co-integrated at the die-level with a transimpedance amplifier and evaluated for analogue coherent radio-over-fiber transmission. This low-complexity homodyne receiver can unlock channel selectivity and high receiver sensitivity inherent to coherent detection, but without the need for digital signal processing. We will demonstrate a sensitivity that allows for an optical budget of 42 dB, and thus eases the fixed-mobile convergence in power-splitting fiber plants. We further show filterless radio signal reception in presence of modulated adjacent channels. Signal integrity is confirmed through transmission of orthogonally frequency multiplexed radio signals with 16-point quadrature amplitude modulated formats, with an error vector magnitude below the corresponding antenna limit.

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Section: Radio-over-fiber Transmissionmentioning

confidence: 99%

Simplified Coherent Receiver for Analogue Radio Transmission Over High Optical Budgets

Milovančev

Vokić

Karinou

et al. 2021

J. Lightwave Technol.

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“…This solution connects 18 cascaded RRHs with one pair of fiber along with the utilization of mature DWDM, OAM (operations, admini-stration, and maintenance) and FEC (forward error correction) to fulfill the requirements of LTE. A high-capacity optical FH network architecture is implemented in [74] based on wavelength sharing in which several cell sites share a single DWDM channel rather than several channels. On a single wavelength, four 20 MHz LTE, 16-QAM signals at a spacing of 100 MHz can be multiplexed to increase the spectral efficiency in the FH network.…”

Section: Optical-based Fronthaul Linkmentioning

confidence: 99%

A Study of Fronthaul Networks in CRANs - Requirements and Recent Advancements

Waqar¹,

Kim²,

Cho³

2018

KSII TIIS

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One of the most innovative paradigms for the next-generation of wireless cellular networks is the cloud-radio access networks (C-RANs). In C-RANs, base station functions are distributed between the remote radio heads (RHHs) and base band unit (BBU) pool, and a communication link is defined between them which is referred as the fronthaul. This leveraging link is expected to reduce the CAPEX (capital expenditure) and OPEX (operating expense) of envisioned cellular architectures as well as improves the spectral and energy efficiencies, provides the high scalability, and efficient mobility management capabilities. The fronthaul link carries the baseband signals between the RRHs and BBU pool using the digital radio over fiber (RoF) based common public radio interface (CPRI). CPRI based optical links imposed stringent synchronization, latency and throughput requirements on the fronthaul. As a result, fronthaul becomes a hinder in commercial deployments of C-RANs and is seen as one of a major bottleneck for backbone networks. The optimization of fronthaul is still a challenging issue and requires further exploration at industrial and academic levels. This paper comprehensively summarized the current challenges and requirements of fronthaul networks, and discusses the recently proposed system architectures, virtualization techniques, key transport technologies and compression schemes to carry the time-sensitive traffic in fronthaul networks.

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“…To the best of our knowledge, the FDM DSP-A approach has been mainly investigated for DS purposes only [6,8,9], i.e., for information flows from the base-band units (BBUs), typically placed in COs, to the AS that delivers the radio signals to the mobile terminals, whereas little attention was placed in the upstream (US) direction [10,11]. Moreover, literature in this area mostly presents experimental analysis, with little emphasis on the link optimization.…”

Section: Introductionmentioning

confidence: 99%