基于隧道场效应管的超低功耗RAM概念

Mostafizur Rahman, Mingyu Li, Jiajun Shi, S. Khasanvis, C. A. Moritz
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引用次数: 2

摘要

保持功率缩放趋势和电池稳定性是20nm以下CMOS SRAM技术面临的关键挑战。这些挑战主要源于mosfet的基本限制,以及SRAM设计的严格器件掺杂和尺寸要求。在本文中,我们提出了一种新的易失性存储器架构,称为基于隧道场效应管的随机存取存储器(TNRAM),它通过以新颖的电路风格集成超低功耗隧道场效应管(tfet)来解决CMOS SRAM的缩放挑战。它被设计为使用单一类型的均匀晶体管,以消除纳米级器件尺寸要求,并且是定制的,以防止SRAM的稳定性问题。分析预测显示显著的电力效益;在16nm技术节点,6T-TNRAM的有功功率比HP 6T-SRAM低4.38倍,漏功率低174倍。
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A new Tunnel-FET based RAM concept for ultra-low power applications
Maintaining power scaling trend and cell stability are critical challenges facing CMOS SRAM at sub-20nm technologies. These challenges primarily stem from the fundamental limitations of MOSFETs, and the rigid device doping and sizing requirements of underlying SRAM design. In this paper, we propose a new volatile memory architecture called Tunnel FET based Random Access Memory (TNRAM) that solves CMOS SRAM scaling challenges through integration of ultra-low power Tunnel FETs (TFETs) in a novel circuit style. It is designed to operate with single type uniform transistors to eliminate nanoscale device sizing requirements, and is customized to prevent SRAM like stability concerns. Analytical projections show significant power benefits; 6T-TNRAM has 4.38x lower active power and 174x lower leakage power over HP 6T-SRAM at 16nm technology node.
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