利用热光学波导透镜实现大规模光学开关

IF 15.7 Q1 OPTICS PhotoniX Pub Date : 2024-04-18 DOI:10.1186/s43074-024-00131-w
Tao Chen, Zhangqi Dang, Zeyu Deng, Shijie Ke, Zhenming Ding, Ziyang Zhang
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引用次数: 0

摘要

在电信和数据通信领域,人们希望将光开关作为电气开关的升级产品,以降低功耗和费用,同时提高带宽和网络透明度。紧凑型集成光开关因其可扩展性、可批量生产性和抗机械干扰的坚固性而备受青睐。其基本单元主要依靠微波谐振器或马赫-泽恩德干涉仪来实现二进制 "条形 "和 "交叉 "开关。这种单模结构通常与波长/偏振有关,对相位误差敏感,而且容易产生损耗。此外,当它们级联成一个网络时,控制单元的数量会随着端口数的增加而迅速增长,从而导致电子布线和驱动电路集成的高度复杂性。在此,我们提出了一种利用热光学波导透镜的新型开关方法。从本质上讲,这种多模波导通过一对加热器电极形成一个平方律介质,并通过稳健的 1 × 1 成像在芯片内聚焦光线。演示的 1 × 24 基本开关有 32 个电极,每次只偏压两个电极以获得所选输出。通过两级级联,开关扩展到 576 个端口,一条路径只需四个电极。这些芯片在低成本实验室中以晶圆规模制造,无需借助代工厂。然而,其性能却超越了低插入损耗、低波长依赖性和低偏振依赖性等技术水平。这项工作为构建大规模光开关提供了一条独创的、可供选择的实用途径,可广泛应用于电信、数据通信和光子计算领域。
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Large-scale optical switches by thermo-optic waveguide lens
Optical switches are desired in telecom and datacom as an upgrade to electrical ones for lower power consumption and expenses while improving bandwidth and network transparency. Compact, integrated optical switches are attractive thanks to their scalability, readiness for mass production, and robustness against mechanical disturbances. The basic unit relies mostly on a microring resonator or a Mach–Zehnder interferometer for binary “bar” and “cross” switching. Such single-mode structures are often wavelength / polarization dependent, sensitive to phase errors and loss-prone. Furthermore, when they are cascaded to a network, the number of control units grows quickly with the port count, causing high complexity in electronic wiring and drive circuit integration. Herein, we propose a new switching method by thermo-optic waveguide lens. Essentially, this multimode waveguide forms a square law medium by a pair of heater electrodes and focuses light within a chip by robust 1 × 1 imaging. A 1 × 24 basic switch is demonstrated with 32 electrodes and only two are biased at a time for a chosen output. By two-level cascading, the switch expands to 576 ports and only four electrodes are needed for one path. The chips are fabricated on wafer scale in a low-budget laboratory without resorting to foundries. Yet, the performance goes beyond state of the art for low insertion loss, low wavelength dependence and low polarization dependence. This work provides an original, alternative, and practical route to construct large-scale optical switches, enabling broad applications in telecom, datacom and photonic computing.
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来源期刊
CiteScore
25.70
自引率
0.00%
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0
审稿时长
13 weeks
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