可扩展光开关中的q因子退化

Qing Xu, H. Rastegarfar, Yousra Ben M'Sallem, S. Larochelle, A. Leon-Garcia, L. Rusch
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引用次数: 7

摘要

全光交换是为了克服电子交换在可扩展性、速度、占地面积和功耗方面的限制而提出的。阵列波导光栅(AWG)是一种绕过电子处理限制的关键无源光学元件。结合波长转换器和光纤延迟线的交换机架构在与awg一起使用时提供可调路由和争用解决方案。AWG被动地将单个或多个输入端口波长路由到其输出端口。每个端口的单一波长策略减少了AWG内的串扰,但大大增加了设备的尺寸。在可预见的未来,AWG设计的物理限制将端口号限制在100以下。为了将光交换机扩展到新兴的网络需求,我们可以在每个端口使用多个波长。在本文中,我们研究了一个多波长每端口架构,并量化了物理层损伤,不仅是由于AWG串扰,还有由于多波长转换引起的q因子退化,以及作为争用分辨率延迟线中再循环次数的函数。虽然以前的工作已经从累积损耗的角度解决了这个问题,但我们关注的是累积的相对强度噪声和放大的自发发射。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
OOK Q-factor degradation in scalable optical switches
All-optical switching has been proposed to overcome the limitations of electronic switches in terms of scalability, speed, footprint, and power consumption. A key passive optical component to bypass electronic processing limitations is the arrayed waveguide grating (AWG). Switch architectures combining wavelength converters and fiber delay lines provide tunable routing and contention resolution when used with AWGs. An AWG passively routes either single or multiple input port wavelengths to its output ports. A single wavelength per port strategy reduces crosstalk within the AWG, but drastically increases the dimensionality of the device. Physical constraints on AWG design limit the port number for the foreseeable future to under 100. To scale optical switches to emerging network requirements, we can use multiple wavelengths per port. In this paper we examine one multiple wavelength per port architecture and quantify the physical layer impairments due not only to the AWG crosstalk, but also Q-factor degradation due to multiple wavelength conversions, and as a function of the number of recirculations in the contention resolution delay lines. While previous work has addressed this issue in terms of accumulated loss, we focus on accumulated relative intensity noise and amplified spontaneous emission.
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