一个原型光偏转网络的设计与实现

Proceedings of the conference on Communications architectures, protocols and applications Pub Date : 1994-10-01 DOI:10.1145/190314.190332

J. Feehrer, J. Sauer, L. Ramfelt

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引用次数: 22

摘要

我们描述了一个具有ShuffleNet拓扑结构的分组交换光纤互连原型的设计和实现，旨在用于共享内存多处理器。结合现有的延迟隐藏机制，它可以减少到远程内存位置的延迟。节点使用偏转路由来解决争用。每个节点包含一个处理器、存储器、光子开关和分组路由处理器。有效载荷从源头到最终目的地保持光学形式。每个主处理器都是一个商用工作站，其总线和光子开关之间有FIFO接口。全局时钟以光学方式分布到每个节点，以最小化偏差。给出了各种节点配置的组件成本和网络性能数据，包括每波长比特和光纤并行分组格式。我们努力实现和测试一个包括真实主机的实际互连，使我们的工作与以前的理论和实验工作不同。我们总结了遇到的困难，并讨论了今后的工作。

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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Design and implementation of a prototype optical deflection network

We describe the design and implementation of a packet-switched fiber optic interconnect prototype with a ShuffleNet topology, intended for use in shared-memory multiprocessors. Coupled with existing latency-hiding mechanisms, it can reduce latency to remote memory locations. Nodes use deflection routing to resolve contention. Each node contains a processor, memory, photonic switch, and packet routing processor. Payload remains in optical form from source to final destination. Each host processor is a commercial workstation with FIFO interfaces between its bus and the photonic switch. A global clock is distributed optically to each node to minimize skew. Component costs and network performance figures are presented for various node configurations including bit-per-wavelength and fiber-parallel packet formats. Our efforts to implement and test a practical interconnect including real host computers distinguishes our work from previous theoretical and experimental work. We summarize obstacles we encountered and discuss future work.

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Proceedings of the conference on Communications architectures, protocols and applications

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