Physical planning of on-chip interconnect architectures

Proceedings. IEEE International Conference on Computer Design: VLSI in Computers and Processors Pub Date : 2002-09-16 DOI:10.1109/ICCD.2002.1106743

Hongyu Chen, B. Yao, Feng Zhou, Chung-Kuan Cheng

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引用次数: 7

Abstract

Interconnect architecture plays an important role in determining the throughput of meshed communication structures. We assume a mesh structure with uniform communication demand for communication. A multi-commodity flow (MCF) model is proposed to find the throughput for several different routing architectures. The experimental results reveal several trends: 1. The throughput is limited by the capacity of the middle row and column in the mesh, simply enlarging the congested channel cannot produce better throughput. A flexible chip shape provides around 30% throughput improvement over a square chip of equal area. 2. A 45-degree mesh allows 17% throughput improvement over 90-degree mesh and a 90-degree and 45-degree mixed mesh provides 30% throughput improvement. 3. To achieve maximum throughput on a mixed Manhattan and diagonal interconnect architecture, the best ratio of the capacity for diagonal routing layers and the capacity for Manhattan routing layers is 5.6. 4. Incorporating a simplified via model, interleaving diagonal routing layers and Manhattan routing layer is the best way to organize the wiring directions on different layers.

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片上互连架构的物理规划

互连体系结构对网状通信结构的吞吐量起着重要的决定作用。我们假设一个具有统一通信需求的网格结构。提出了一种多商品流(MCF)模型，用于求解几种不同路由体系结构的吞吐量。实验结果揭示了几个趋势:1。吞吐量受网络中排和列容量的限制，单纯扩大拥挤通道不能产生更好的吞吐量。灵活的芯片形状比相同面积的方形芯片提供了大约30%的吞吐量提高。2. 与90度网相比，45度网的吞吐量提高了17%，90度和45度混合网的吞吐量提高了30%。3.为了在混合曼哈顿和对角线互连架构上实现最大吞吐量，对角线路由层的容量和曼哈顿路由层的容量的最佳比率是5.6。4. 结合简化的通道模型，交错的对角线路由层和曼哈顿路由层是组织不同层上的布线方向的最佳方式。

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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来源期刊

Proceedings. IEEE International Conference on Computer Design: VLSI in Computers and Processors

CiteScore

2.30

自引率

0.00%

发文量