Enhancement of DRAMs performance using resonant tunneling diode buffer

2014 The 1st International Conference on Information Technology, Computer, and Electrical Engineering Pub Date : 2014-11-01 DOI:10.1109/ICITACEE.2014.7065706

Ahmed Lutfi Elgreatly, A. A. Shaaban, E. M. El-Rabaie

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引用次数: 7

Abstract

DRAM industry has gained most of the interest in the memory chip industry in the last decades for its high density (due to its simple structure) and lower power consumption. As the density of DRAM chips increased, the bit-line parasitic capacitances increased and many problems appeared such as increased power consumption and larger read/write access times which gave great attention to improve the design of the CMOS sense amplifier used in the memory chip for its great effects on memory access time, overall memory power dissipation and chip density. In this paper, we introduce one of the most effective solutions to increase the performance of the advanced high density DRAMs by replacing the sense amplifier circuit with a specially designed logic buffer circuit based on Resonant Tunneling Diode (RTD) that can be fabricated in Nano-scale and exhibit higher operation speed with lower power consumption and higher chip density. The proposed design improves the Power Delay Product (PDP) by about 36% compared with that in conventional RTD-CMOS sense amplifier and 15% compared with that in conventional CMOS sense amplifier. The 45nm CMOS technology is used in this paper.

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利用共振隧道二极管缓冲器增强dram性能

在过去的几十年里，DRAM产业因其高密度(由于其结构简单)和低功耗而在存储芯片产业中获得了大部分的兴趣。随着DRAM芯片密度的增加，位线寄生电容增大，出现了功耗增加、读写访问次数增加等问题，存储芯片中CMOS感测放大器的设计对存储器访问时间、存储器整体功耗和芯片密度有很大影响，因此需要引起人们的重视。本文介绍了一种提高先进高密度dram性能的最有效的解决方案，即用基于谐振隧道二极管(RTD)的特殊设计的逻辑缓冲电路取代感测放大器电路，该电路可以在纳米尺度上制造，具有更高的运行速度，更低的功耗和更高的芯片密度。与传统的RTD-CMOS感测放大器相比，该设计将功率延迟积(PDP)提高了约36%，比传统的CMOS感测放大器提高了约15%。本文采用45纳米CMOS技术。

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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2014 The 1st International Conference on Information Technology, Computer, and Electrical Engineering

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