Costs and benefits of flexibility in spatial division circuit switched networks-on-chip

Network on Chip Architectures Pub Date : 2013-12-08 DOI:10.1145/2536522.2536526

Ahsen Ejaz, A. Jantsch

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引用次数: 8

Abstract

Although most Network-on-Chip (NoC) designs are based on Packet Switching (PS), the importance of Circuit Switching (CS) should not be underestimated. Many MPSoC executing real-time applications require an underlying communication backbone that can relay messages from one node to another with guaranteed throughput. Compared to PS, CS can provide guaranteed throughput with lower area and power overheads. It is also highly suited for applications where nodes transfer long messages. Spatial Division Multiplexing (SDM) can allow more efficient use of available network resources by dividing them among multiple simultaneous transactions. The network developed by Vali [1] has three design variations based on the number of sub-channels, has a predictable connection setup time, and uses CS to provide guaranteed throughput once a connection is established. In this paper we use this network as a basis to study the effect of flexibility based on SDM, on the performance of a CS networks. A network evaluation platform has been developed to configure and evaluate networks with a maximum of 8 sub-networks, with each subnetwork comprising of 1, 2 or 4 sub-channels. We show that under uniform traffic pattern with requests of uniform random bandwidth (BW) requirement, a less flexible network outperforms a network with higher flexibility due to a phenomenon we call 'stray requests'. We conclude this paper by showing that under high network traffic, performance of our flexible networks can be as much as 113% better than HAGAR [2] and Liu's [3] network.

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片上空间划分电路交换网络灵活性的成本与效益

虽然大多数片上网络(NoC)设计都是基于分组交换(PS)，但电路交换(CS)的重要性也不应被低估。许多执行实时应用程序的MPSoC需要一个底层通信骨干，可以在保证吞吐量的情况下将消息从一个节点中继到另一个节点。与PS相比，CS可以以更低的面积和功耗开销提供有保证的吞吐量。它也非常适合节点传输长消息的应用程序。空间分路复用(SDM)通过将可用的网络资源分配给多个同时进行的事务，可以更有效地利用可用的网络资源。Vali[1]开发的网络根据子通道的数量有三种设计变化，具有可预测的连接建立时间，并使用CS在连接建立后提供保证的吞吐量。本文以该网络为基础，研究了基于SDM的柔性对CS网络性能的影响。开发了一个网络评估平台，可以配置和评估最多8个子网的网络，每个子网由1、2或4个子通道组成。我们表明，在具有均匀随机带宽(BW)要求的请求的均匀流量模式下，由于我们称之为“杂散请求”的现象，灵活性较低的网络优于灵活性较高的网络。在高网络流量下，我们的灵活网络的性能可以比HAGAR[2]和Liu的[3]网络高出113%。

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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Network on Chip Architectures

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