Title :
A new Tunnel-FET based RAM concept for ultra-low power applications
Author :
Rahman, Mosaddequr ; Mingyu Li ; Jiajun Shi ; Khasanvis, Santosh ; Moritz, Csaba Andras
Author_Institution :
Electr. & Comput. Eng. Dept., Univ. of Massachusetts, Amherst, MA, USA
Abstract :
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.
Keywords :
CMOS memory circuits; MOSFET; SRAM chips; low-power electronics; 6T-SRAM; 6T-TNRAM; CMOS SRAM; MOSFETs; random access memory; size 16 nm; tunnel-FET based RAM concept; ultralow power applications; volatile memory architecture; CMOS integrated circuits; Circuit stability; Field effect transistors; Nanoscale devices; Random access memory; Stability criteria; Nanoscale Memory; Noise Margin; TNRAM; Tunnel FET; Ultra-Low Power;
Conference_Titel :
Nanoscale Architectures (NANOARCH), 2014 IEEE/ACM International Symposium on
Conference_Location :
Paris
DOI :
10.1109/NANOARCH.2014.6880505
