逆流管道实验

Proceedings. Fifth International Symposium on Advanced Research in Asynchronous Circuits and Systems Pub Date : 1999-04-19 DOI:10.1109/ASYNC.1999.761531

B. Coates, J. Ebergen, J. Lexau, Scott M. Fairbanks, I. W. Jones, Alex Ridgway, David M. Harris, I. Sutherland

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引用次数: 10

摘要

逆流管道体系结构由两个相互作用的管道组成，其中数据项以相反的方向流动。当两个项目在一个阶段中相遇时，它们之间发生交互。我们提出了一种异步芯片的设计决策和测试测量，该芯片探索了这种架构的基本思想。我们构建芯片是为了确认仲裁者的正确操作，以确保在一个方向上流动的每个项目都与在另一个方向上流动的每个项目相互作用。我们的芯片名为“Zeke”，通过MOSIS制造工厂以0.6 /spl mu/m CMOS制造。芯片的最大总吞吐量，即两个管道吞吐量的总和，根据发生的交互量在491 MDI/s(每秒百万数据项)和699 MDI/s之间变化。在平均数据和操作条件下，我们芯片的性能大致介于这些吞吐量值之间。

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A counterflow pipeline experiment

The counterflow pipeline architecture consists of two interacting pipelines in which data items flow in opposite directions. Interactions occur between two items when they meet in a stage. We present the design decisions for, and test measurements from, an asynchronous chip that explores the basic ideas of such an architecture. We built the chip in order to confirm proper operation of the arbiters required to ensure that each and every item flowing in one direction interacts with each and every item flowing in the other direction. Our chip, named "Zeke," was built in 0.6 /spl mu/m CMOS through the MOSIS fabrication facility. The maximum total throughput of the chip, which is the sum of the throughputs of the two pipelines, varies between 491 MDI/s (mega data items per second) and 699 MDI/s, depending on the amount of interaction that takes place. Under average data and operating conditions the performance of our chip was roughly halfway between these throughput values.

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Proceedings. Fifth International Symposium on Advanced Research in Asynchronous Circuits and Systems

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