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引用次数: 0
摘要
空分复用技术(SDM)已成为未来大容量光传输系统容量扩展的关键技术。基于大规模多输入/多输出(MIMO)数字信号处理的SDM系统,利用在空间信道之间具有固有强串扰的介质,如耦合多芯光纤,特别有希望实现前所未有的传输容量。为了减轻这些大规模并行系统固有的复杂性,需要开发一种能够有效处理高符号速率传输的SDM-MIMO信号处理方案。在这种情况下,我们提出了一种部分冻结(PF) 4D×D多输入/多输出自适应均衡器(MIMO AEQ),专门为鲁棒高符号速率SDM-MIMO信号接收量身定制。这种方法的设计目的是为了对抗高符号率传输的主要障碍——电智商缺陷,同时增强对信道动态的跟踪能力,降低计算复杂性。详细介绍了PF 4D×D MIMO AEQ的工作原理,并通过仿真和实验验证了其性能。我们的结果强调了它的有效性,证明了2.6 (0.65×4) Tb/s/λ的净传输在动态波动的四芯电缆传输线上使用100-Gbaud 16QAM信号。
Coupled-Core Transmission at 100-Gbaud with Low-Complexity, Fast-Tracking 4D × D MIMO Equalizer
Space division multiplexing (SDM) has emerged as a pivotal technology for scaling the capacity of future high-capacity optical transmission systems. Large-scale multiple-input/multiple-output (MIMO) digital signal processing-based SDM systems that utilize media with inherent strong crosstalk between spatial channels, such as coupled-core multicore fibers, are particularly promising for achieving unprecedented transmission capacities. To alleviate the inherent complexity of these massively parallel systems, an SDM-MIMO signal processing scheme needs to be developed that can efficiently handle high-symbol-rate transmissions. In this context, we present a partially frozen (PF) 4D×D multiple-input/multiple-output adaptive equalizer (MIMO AEQ), tailored specifically for robust high-symbol-rate SDM-MIMO signal reception. This approach is designed to combat electrical IQ impairments—a predominant obstacle in high-symbol-rate transmission—while simultaneously enhancing tracking ability to channel dynamics and reducing computational complexity. We detail the operational principles of the PF 4D×D MIMO AEQ and validate its performance through simulations and experiments. Our results underscore its validity, demonstrating a net transmission of 2.6 (0.65×4) Tb/s/λ over a dynamically fluctuating four-coupled-core cabled transmission line using 100-Gbaud 16QAM signals.
期刊介绍:
The Journal of Lightwave Technology is comprised of original contributions, both regular papers and letters, covering work in all aspects of optical guided-wave science, technology, and engineering. Manuscripts are solicited which report original theoretical and/or experimental results which advance the technological base of guided-wave technology. Tutorial and review papers are by invitation only. Topics of interest include the following: fiber and cable technologies, active and passive guided-wave componentry (light sources, detectors, repeaters, switches, fiber sensors, etc.); integrated optics and optoelectronics; and systems, subsystems, new applications and unique field trials. System oriented manuscripts should be concerned with systems which perform a function not previously available, out-perform previously established systems, or represent enhancements in the state of the art in general.
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