摘要
Beyond providing user access to the core network,the radio access network(RAN) is expected to support precise positioning and sensing for emerging applications such as virtual reality(VR) and drone fleets.To achieve this,fronthaul-the link connecting the central units/distributed units(CUs/DUs) to wireless remote units(RUs) in centralized RAN-must realize both high-capacity transmission and low-timing-jitter clock synchronization between RUs.However,existing solutions fall short of supporting these functions within one simple,cost-effective network.In this work,we propose a solution that simultaneously achieves picosecond-level timing jitter clock distribution and Tb/s data transmission with simp lified DSP,using an electro-optic(EO) comb cloning technique to enable multifunctionality in fronthaul systems.Through the delivery of pilot comb lines,a 1 ps(integrated from 1 Hz to 40 MHz) low-timing-jitter 100 MHz clock is distributed by the beating of adjacent pilot comb lines and subsequent frequency dividing,realizing frequency synchronization between the CUs/DUs and RUs.Moreover,the delivery of pilot comb lines also facilitates self-homodyne structures through EO comb cloning,and supports wavelength division multiplexing(WDM) transmission with a line capacity of 2.88 Tb/s and a net capacity of 2.5 Tb/s.Thanks to the clock-synchronized and self-homodyne structure,DSP is streamlined,with digital timing recovery,carrier phase estimation,and frequency offset estimation all omitted.This work lays the technical foundation for implementing a 6G WDM fronthaul architecture that integrates ultra-wide wireless bandwidth with precise positioning and sensing.
基金
Natural Science Foundation of Beijing Municipality(JQ24027).
