An improved dynamic optically reconfigurable gate array

IEEE Computer Society Annual Symposium on VLSI: New Frontiers in VLSI Design (ISVLSI'05) Pub Date : 2005-05-11 DOI:10.1109/ISVLSI.2005.16

Minoru Watanabe, F. Kobayashi

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引用次数: 1

Abstract

To date, we have proposed dynamic optically reconfigurable gate arrays (DORGAs), the implemented photodiodes of which serve not only as receivers but also as memory. DORGA offers the merit of easily providing a high gate count optically reconfigurable gate array (ORGA) because each reconfiguration circuit consists of only a photodiode and a refresh transistor. However, even though the fast reconfiguration capability has been confirmed as less than 6 ns, such systems have a demerit: their gate arrays can not function during reconfiguration. Consequently, reconfiguration and operation of the implemented circuit on a gate array can not be executed in parallel. Because of that fact, the dynamical reconfiguration frequency of DORGA is slow compared to those of ORGAs with latches, flip-flops, or memory. For that reason, this paper proposes a new optical reconfiguration architecture. Using it, the reconfiguration and implemented circuit operation on a gate array are executable in parallel merely by adding a pass transistor. The new design of a 476-gate-count improved DORGA using a standard 0.35 /spl mu/m three-metal CMOS process technology is also shown.

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一种改进的动态光可重构门阵列

到目前为止，我们已经提出了动态光可重构门阵列(DORGAs)，其实现的光电二极管不仅可以作为接收器，还可以作为存储器。由于每个重构电路仅由一个光电二极管和一个刷新晶体管组成，因此DORGA提供了易于提供高门计数光可重构门阵列(ORGA)的优点。然而，即使快速重构能力已被确认为小于6 ns，这种系统也有一个缺点:它们的门阵列在重构过程中不能正常工作。因此，门阵列上所实现电路的重构和操作不能并行执行。因此，与锁存器、触发器或存储器相比，DORGA的动态重构频率较慢。为此，本文提出了一种新的光重构结构。使用它，门阵列上的重构和实现的电路操作仅通过增加一个通管即可并行执行。采用标准的0.35 /spl mu/m三金属CMOS工艺技术，改进了476栅极数的新设计。

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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IEEE Computer Society Annual Symposium on VLSI: New Frontiers in VLSI Design (ISVLSI'05)

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