Photonic Approach to Optimize Energy Consumption for On-chip Clos Network

Journal of lasers, optics & photonics Pub Date : 2016-03-01 DOI:10.4172/2469-410X.1000128

B. Deepalakshmi, G. Maruthachalam

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引用次数: 1

Abstract

To meet energy-efficient performance needs, the computation has positioned to parallel computer architectures, such as chip multiprocessors (CMPs), internally interconnected via networks-on-Chip (NoC) to achieve increasing communication needs. To accomplish scaling execution as center include increment to the hundreds future CMPs, all things considered, will require elite, yet vitality productive interconnects. Silicon Nano photonics is a promising swap for electronic on-chip interconnect for its high data transfer capacity and low inactivity, by the by, earlier methods have required high static force for the laser and warm ring tuning. We propose novel Nano photonic NoC (PNoC) design, upgraded for elite and force effectiveness. This paper makes three essential elements: a novel, Nano photonic engineering which isolates the system into subnets for better productivity; an exclusively photonic, inband, appropriated discretion plan; and a channel sharing schematic are using the same waveguides and wavelengths for intervention as information transmission. As a result the interconnection can be reduced latency with increased throughput.

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片上Clos网络能耗优化的光子方法

为了满足节能性能需求，计算已经定位为并行计算机架构，例如芯片多处理器(cmp)，通过片上网络(NoC)内部互连，以满足日益增长的通信需求。考虑到所有因素，为了实现以扩展执行为中心的数百个未来cmp的增量，将需要精英，但充满活力的生产性互连。硅纳米光子学因其高数据传输能力和低不活动性而成为一种很有前途的电子片上互连交换，顺便说一下，早期的方法需要高静力来进行激光和暖环调谐。我们提出了一种新型的纳米光子NoC (PNoC)设计，针对精英和部队效能进行了升级。本文提出了三个基本要素:一种新颖的纳米光子工程，将系统隔离到子网中以提高生产率;一个完全光子的，带内的，适当的自由裁量计划;和信道共享原理图使用相同的波导和波长进行干预作为信息传输。因此，可以通过增加吞吐量来减少互连的延迟。

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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Journal of lasers, optics & photonics

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