Abstract
The ever-increasing proliferation of mobile users and new technologies, and the demands for ubiquitous connectivity, high data capacity, faster data speed, low latency, and reliable services have been driven the quest for the next generation, fifth generation (5G), of the wireless networks. Cloud radio access network (C-RAN) has been identified as a promising architecture for addressing 5G requirements. However, C-RAN enforces stringent requirements on the fronthaul capacity and latency. To this end, several fronthaul solutions have been proposed in the literature, ranging from transporting digitized radio signals over fiber and functional splits to an entirely analog-radio-over fiber (A-RoF) based fronthual. A-RoF is a highly appealing transport solution for fronthual of 5G and beyond owing to its high bandwidth and energy efficiency, low system complexity, small footprint, cost-effectiveness, and low latency. In this paper, a high capacity multiple-input-multiple-output (MIMO) enabled all-optical analog-millimeter-wave-over fiber (A-MMWoF) fronthaul architecture is proposed for 5G and beyond of wireless networks. The proposed architecture employs photonic MMW signals generation and mode division multiplexing (MDM) along with wavelength division multiplexing (WDM) for transporting MMW MIMO signals in the optical domain. In support of the proposed architecture design, a comprehensive state-of-the-art literature review on the recent research works in high capacity A-RoF fronthaul systems and related transport technologies is presented. In addition, the corresponding potential challenges and solutions along with potential future directions are highlighted. The proposed design is flexible and scalable for achieving high capacity, high speed, and low latency fronthaul links.
Highlights
The demand for ubiquitous connectivity, high data capacity, faster data speed, low latency, and reliable services increases day by day with the persistent growth of mobile users and new technologies
The analog-radio-over fiber (A-RoF) fronthaul will become more scalable and flexible when tailored with space division multiplexing (SDM) technology, which can be achieved by leveraging mode division multiplexing (MDM) in few mode fiber (FMF), multicore fiber (MCF), ring core fiber (RCF) or the combination of them
FUTURE WORK In this paper, a high capacity MDM based MIMO enabled photonic analog-millimeter-waveover fiber (A-MMWoF) fronthaul architecture is proposed for 5G and beyond of wireless networks
Summary
The demand for ubiquitous connectivity, high data capacity, faster data speed, low latency, and reliable services increases day by day with the persistent growth of mobile users and new technologies. MDM BASED MIMO ENABLED ALL-OPTICAL A-MMWoF FRONTHAUL ARCHITECTURE A general overview of the fronthaul architecture is shown, where BBUs in the central office are connected to the RRHs/RRUs/RAUs through optical fiber transmission links in various potential different configurations It supports both indoor and outdoor MMW communications along with macro and small cell environments. We believe that the proposed design is capable of achieving high speed, high capacity, low latency, and high flexibility and scalability
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