Universal strategy study of applying passive metasurfaces to an intra-DC wireless-optical interconnection

IF 4 2区 计算机科学 Q1 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE Journal of Optical Communications and Networking Pub Date : 2024-09-11 DOI:10.1364/JOCN.521214
Weijie Qiu;Weigang Hou;Jianou Huang;Xiangyu He;Pengxing Guo;Lei Guo
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Abstract

Free-space optical (FSO) communication can reduce the routing complexity of data center networks (DCNs), not only ensuring high-capacity optical switching, but also owning similar flexibility to the wireless connectivity. Presently, mainstream wireless-optical switching units (WOSUs) have adopted serial beam control for unicasting. As a two-dimensional planar structure composed of meta-atoms with special electromagnetic properties arranged in a certain way, a passive metasurface (PMF) has strong parallel beam regulating capability. In this paper, we propose a wireless-optical intra-DC interconnection scheme based on PMFs. Through a real PMF chip, by adjusting the polarization of an incident beam, the power distribution between normal and abnormal reflected beams can be controlled. When both reflected beams are assigned with power, we obtain a pair of beams reflected in parallel, thus simultaneously communicating with two racks. In fact, we can perform 1-to- $N$ ( $N \ge 2$ ) multicast by using cascaded PMFs, and 1-to- $N$ means that each source rack can communicate with $N$ destination racks, i.e., a wide communication coverage range. However, the cascaded PMFs may result in huge chip costs and high accumulated power loss. In this paper, we only demonstrate the 1-to-2 communication ability of our PMFs, so the communication coverage may be still limited. Hence, by introducing electrostatic drive to control the PMF rotation, each source rack can achieve a wider communication coverage range than before. As a result, all racks within the coverage range have the ability to establish communication links with the source rack. To this end, we also design a neural network to mimic the PMF rotation, further improving the communication capability between racks. We then propose a DCN-topology reconfiguration algorithm supporting the coexistence of unicasting and multicasting, in order to make real-time decisions on the matching between FSO ports with minimized latency. Finally, we established a proof-of-concept prototype system to demonstrate the parallel beam control of our PMF. The test results show that the angle error is less than 0.1°, satisfying the accuracy requirements of WOSUs, and our PMF always has a good polarization response with the insertion loss of less than 2 dB under various azimuth angles or rotation planes.
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将无源元表面应用于直流内部无线-光学互连的通用策略研究
自由空间光(FSO)通信可降低数据中心网络(DCN)的路由复杂性,不仅能确保大容量光交换,还具有与无线连接类似的灵活性。目前,主流的无线光交换单元(WOSU)采用串行光束控制进行单播。无源元表面(PMF)作为一种由具有特殊电磁特性的元原子按一定方式排列而成的二维平面结构,具有很强的并行光束调节能力。本文提出了一种基于 PMF 的无线-光学直流内部互连方案。通过真正的 PMF 芯片,通过调整入射光束的偏振,可以控制正常反射光束和异常反射光束之间的功率分配。当两束反射光束都被分配了功率时,我们就会得到一对平行反射的光束,从而同时与两个机架进行通信。事实上,我们可以通过级联 PMF 实现 1 对 N($N \ge 2$)的组播,1 对 N 意味着每个源机架可以与 $N$ 目的机架通信,即通信覆盖范围很广。然而,级联 PMF 可能会导致巨大的芯片成本和高累积功率损耗。在本文中,我们仅展示了 PMF 的 1 对 2 通信能力,因此通信覆盖范围可能仍然有限。因此,通过引入静电驱动来控制 PMF 旋转,每个信号源机架可以实现比以前更广的通信覆盖范围。因此,覆盖范围内的所有机架都能与源机架建立通信联系。为此,我们还设计了一个模拟 PMF 旋转的神经网络,进一步提高了机架之间的通信能力。然后,我们提出了一种支持单播和多播共存的 DCN 拓扑重新配置算法,以便以最小的延迟实时决定 FSO 端口之间的匹配。最后,我们建立了一个概念验证原型系统,以演示我们的 PMF 的并行波束控制。测试结果表明,角度误差小于 0.1°,满足了 WOSU 的精度要求,而且我们的 PMF 在各种方位角或旋转平面下始终具有良好的极化响应,插入损耗小于 2 dB。
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来源期刊
CiteScore
9.40
自引率
16.00%
发文量
104
审稿时长
4 months
期刊介绍: The scope of the Journal includes advances in the state-of-the-art of optical networking science, technology, and engineering. Both theoretical contributions (including new techniques, concepts, analyses, and economic studies) and practical contributions (including optical networking experiments, prototypes, and new applications) are encouraged. Subareas of interest include the architecture and design of optical networks, optical network survivability and security, software-defined optical networking, elastic optical networks, data and control plane advances, network management related innovation, and optical access networks. Enabling technologies and their applications are suitable topics only if the results are shown to directly impact optical networking beyond simple point-to-point networks.
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