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高速相干光正交频分复用系统实现方案研究 被引量:1

Implementation for high-speed coherent optical orthogonal frequency division multiplexing system
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摘要 相干光正交频分复用系统(Coherent optical orthogonal frequency division multiplexing,CO-OFDM)作为未来高速光通信的重要解决方案,是近年来光传输领域的研究热点。高速CO-OFDM系统需要较高带宽的模数/数模转换器(DAC/ADC),目前技术水平难以达到。改进了正交频带复用技术(Orthogonalband multiplexing,OBM)的光域实现方案;结合偏振复用技术和偏振分集接收,提出了基于OBM的100 Gb/s高速CO-OFDM系统;并对系统传输性能进行数字仿真。结果表明:基于OBM技术的MIMO CO-OFDM系统可有效降低对DAC/ADC的处理速度要求,在不需任何在线色散补偿和偏振控制器件条件下,通过单模光纤传输800 km,系统Q值保持在13 dB以上。 Coherent optical orthogonal-frequency-division-multiplexing (CO-OFDM) has drawn more atten- tion in optical transmissions as an attractive modulation format for the forthcoming 100 Gb/s Ethernet. However, CO-OFDM system requires high-speed digital-to-analog converters (DAC) and analog-to-digital converters (ADC), which may not be available today. To resolve ADC/DAC bandwidth bottleneck, with thehelp of orthogonal-band-multiplexing (OBM) and polarization division multiplexing (PDM), 100 Gb/s COOFDM system based on OBM is presented. With this scheme, simulation is done to validate the feasibility of the system model and algorithm. The result shows that the performance of MIMO CO-OFDM system based on OBM is maintained above 13 dB at 0 GHz channel spacing for 800 km standard single mode fiber (SSMF) transmission without any inline dispersion compensation and polarization controller (PC) and the DAC/ADC do not need to operate at extremely high sampling rate.
作者 郝耀鸿 李玉权 王荣 黄卫卫
机构地区 军事体育进修学院 解放军理工大学通信工程学院
出处 《量子电子学报》 CAS CSCD 北大核心 2012年第2期242-246,共5页 Chinese Journal of Quantum Electronics
基金 国家自然科学基金(60871075)
关键词 光通信 正交频分复用 长距离传输 偏振复用 optical communications orthogonal frequency division multiplexing long-haul transmission polarization division multiplexing
分类号 TN929.5 [电子电信—通信与信息系统]
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量子电子学报
2012年 第2期

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