Abstract
Bandwidth-efficient 5G optical fronthaul interfaces, such as the Ethernet-based common public radio interface (eCPRI), with novel low layer split (LLS) are being actively investigated. Regarding the uplink eCPRI, the burdened wireless resource blocks (RBs) are delivered and the traffic aggregation is leveraged; therefore, the eCPRI traffic is highly dynamic depending on the time-varying mobile traffic load. This dynamic property will lower the average fiber link utilization and complicate the sizing of link bandwidth for the deployment of low-latency fronthaul. To tackle this issue, we propose a load-adaptive quantization resolution scheme that enables elastic fronthaul capacity. By adjusting the quantization resolution of the resource elements in RBs, the fronthaul link capacity, measured by the amount of bearable RBs, can be scaled to fit the mobile traffic load. Specifically, a full resolution is applied during low-load period, while for high-load case, to boost the link capacity, a stringent resolution is performed by removing the least significant quantization bits (LSQBs). Besides, to minimize the signal fidelity deterioration caused by the decline of resolution, the resolution redundancy is evaluated based on the detected wireless signal quality at central unit, and the location of LSQBs is fed back to the radio unit through the eCPRI control plane. With the enhanced link flexibility, the required fronthaul bandwidth can be significantly reduced, while the user experience is barely compromised. Based on our developed low-MAC and PHY-layer wireless system model following 3GPP specifications and the 25-Gb/λ experimental fiber transmission, the bandwidth of eCPRI user data can be saved by 40%.
Highlights
The centralized radio access network (C-RAN) architecture is considered as one of the enabling solutions to support the 5th generation (5G) and beyond 5G (B5G) mobile cellular communications [1], [2]
In the traditional C-RAN, PHY-radio frequency (PHY-RF) split (Option 8) is employed [5] for next-generation fronthaul interface (NGFI)-I, and the interface is standardized by common public radio interface (CPRI) [6]
This result well matches the signal to interference and noise ratio (SINR) distribution of Urban Micro (UMi) scenario given in 3GPP specification [34], and it will be utilized in the following analysis
Summary
The centralized radio access network (C-RAN) architecture is considered as one of the enabling solutions to support the 5th generation (5G) and beyond 5G (B5G) mobile cellular communications [1], [2]. Since CPRI delivers the time-domain signal samples which are continuous regardless of the actual mobile payload, it is bandwidth-consuming and short of flexibility Given these disadvantages, the more efficient functional splits are investigated [7]–[11]. Whereas for different split points, the performances such as latency and CoMP-wise support are varied, this technology is more about serving diverse scenarios rather than handling the traffic fluctuation [4] To fundamentally address this issue, an eCPRI-based fronthaul realizing flexible link capacity would be an efficient solution. In our previous work [27], a flexible quantization bit-width (FQB) scheme was firstly reported to promote the eCPRI bandwidth efficiency under static traffic load.
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