Optical-label-based all-optical packet switching routers

Farouk E. El-Khamy, Hossam M. H. Shalaby, Mohamed E. Nasr, Hussein T. Mouftah
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引用次数: 3

Abstract

Current developments in optical components technologies enable wavelengths to be very narrowly spaced, transforming the optical fiber into a multi-terabit capacity medium. A new generation of "all-optical" cross-connects started to appear in the market leading to a number of advantages such as increased switching capacity, decreased overall network costs, scalability and transparency resulting in the capability to support any protocol. An additional advantage is the ability to configure the switching fabric and the wavelength converters in real-time. All-optical switches are made possible by a number of technologies that allow the managing and switching photonic signals without converting them into electronic signals. Only a couple of technologies appear ready to make the transition form the laboratory to the network, where they must support the basic feature set of a carrier-grade, scalable optical switches. Arguably, the leading technology for developing an economically viable, scalable all-optical , OOO switch is the 3D micro-electromechanical system (MEMS). 3D MEMS uses control mechanisms to tilt mirrors in multiple directions (3 dimensional). For the control of optical cross-connects, the MP Lambdas approach was proposed by IETF, according to which the MPLS traffic engineering control plane is used in optical cross connects. In this paper, evolution of architectures for optical cross-connects all optical switch are discussed with different switch fabrics such as micro-electro-mechanical all optical switch fabric and arrayed-wavelength-grating routers (AWGRs). The paper includes also an illustration of the major function of the multi protocol label switching MPLS optical router and the use of MP lambda switch to control the all optical switch.
基于光标签的全光分组交换路由器
目前光学元件技术的发展使波长间隔非常窄,将光纤转变为多太比特容量的介质。新一代“全光”交叉连接开始出现在市场上,带来了许多优势,例如增加了交换容量,降低了整体网络成本,可扩展性和透明度,从而能够支持任何协议。另一个优点是能够实时配置交换结构和波长转换器。全光开关是由许多技术实现的,这些技术允许管理和切换光子信号而不将其转换为电子信号。只有几种技术似乎已经准备好从实验室过渡到网络,它们必须支持电信级可扩展光交换机的基本功能集。可以说,开发经济可行,可扩展的全光,OOO开关的领先技术是3D微机电系统(MEMS)。3D MEMS使用控制机制在多个方向(三维)倾斜镜子。对于光交叉连接的控制,IETF提出了MP Lambdas方法,在光交叉连接中使用MPLS流量工程控制平面。本文讨论了不同交换结构下光交叉连接全光交换机的结构演变,如微机全光交换结构和阵列波长光栅路由器(awgr)。本文还介绍了多协议标签交换MPLS光路由器的主要功能,以及MP lambda交换机对全光交换机的控制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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