用于高密度空分复用(H-DSDM)系统的高余弦多芯光纤

2022 IEEE International Conference on Design & Test of Integrated Micro & Nano-Systems (DTS) Pub Date : 2022-06-06 DOI:10.1109/DTS55284.2022.9809851

Alaaeddine Rjeb, Hussein E. Seleem, A. Ragheb, H. Fathallah, M. Esmail, M. Machhout, S. Alshebeili

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引用次数: 0

摘要

在多核少模光纤(MC-FMFs)上的空分复用(SDM)被认为是下一代光通信系统中实现高数据速率的最新技术之一。在本文中，我们提出并设计了新型(mc - fmf)，我们将其称为凸起余弦多芯纤维mc - rfc和沟槽凸起余弦多芯纤维mc - trcf。设计的mcf具有7个核心，每个核心支持7个正交空间模式，有效模面积大(最小AeJ J =96μm2)，差分模延迟(DMD)低(最大DMD =33 ps\\\\\\\\km)。对每条设计光纤的芯间串扰及其相关的相对芯多重系数(RCMF)进行了评估、讨论，并与最近报道的芯间多重系数进行了比较。所设计的光纤是下一代中短途互连密集sdm系统的有希望的候选者。

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Raised Cosine Multicore Fibers For High-Density Space Division Multiplexing (H-DSDM) Systems

Space division multiplexing (SDM) over multicore few mode fibers (MC-FMFs) is considered among the latest technological drive towards high data rates in next generation optical communication systems. In this paper, we propose and design novel (MC-FMFs) that we refer to as raised cosine multicore fibers MC-RCFs and Trenched-raised cosine multicore Fibers (MC-TRCFs). the designed MCFs has seven cores each of which supports seven orthogonal spatial modes with large effective mode area (min AeJ J =96μm2) and with low differential mode delay (DMD) (max DMD =33 ps\\\\\\\\km). The intercore crosstalk of each designed fiber and their associated relative core multiplicity factor (RCMF) are assessed, discussed and compared with recently reported MCFs. The designed fibers are promising candidates for next generation short and medium haul interconnect dense-SDM systems.

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2022 IEEE International Conference on Design & Test of Integrated Micro & Nano-Systems (DTS)

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