一个16上下文光可重构门阵列

2009 20th IEEE International Conference on Application-specific Systems, Architectures and Processors Pub Date : 2009-07-07 DOI:10.1109/ASAP.2009.41

M. Nakajima, Minoru Watanabe

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引用次数: 7

摘要

由于动态重新配置可以提高处理器的性能，因此对快速动态重新配置的需求有所增加。动态重新配置有两个重要的先决条件:快速重新配置和大量重新配置上下文。不幸的是，在当前的vlsi上，快速重新配置和大量上下文共享一个权衡关系。因此，开发了光可重构门阵列来解决这一难题。光可重构门阵列利用全息存储器的大存储容量，可以实现比当前超大规模集成电路芯片大得多的虚拟门数。此外，光学可重构门阵列可以利用全息存储器和可编程门阵列VLSI之间的大带宽光连接实现快速重构。本文介绍了16个上下文光可重构门阵列架构的最快317-657 ns重构演示。

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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A 16-context Optically Reconfigurable Gate Array

Demand for fast dynamic reconfiguration has increased since dynamic reconfiguration can accelerate the performance of processors. Dynamic reconfiguration has two important prerequisites: fast reconfiguration and numerous reconfiguration contexts. Unfortunately, fast reconfigurations and numerous contexts share a tradeoff relation on current VLSIs. Therefore, optically reconfigurable gate arrays were developed to resolve this dilemma. Optically reconfigurable gate arrays can realize a large virtual gate count that is much larger than those of current VLSI chips by exploiting the large storage capacity of a holographic memory. Furthermore, optically reconfigurable gate arrays can realize rapid reconfiguration using large bandwidth optical connections between a holographic memory and a programmable gate array VLSI. This paper presents the fastest 317–657 ns reconfiguration demonstration of a 16-context optically reconfigurable gate array architecture.

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2009 20th IEEE International Conference on Application-specific Systems, Architectures and Processors

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