TY - JOUR
T1 - Reimagining Sense Amplifiers
T2 - Harnessing Phase Transition Materials for Current and Voltage Sensing
AU - Islam, Md Mazharul
AU - Alam, Shamiul
AU - Jahangir, Mohammad Adnan
AU - Rose, Garrett S.
AU - Datta, Suman
AU - Narayanan, Vijaykrishnan
AU - Gupta, Sumeet Kumar
AU - Aziz, Ahmedullah
N1 - Publisher Copyright:
© 2002-2012 IEEE.
PY - 2024
Y1 - 2024
N2 - Energy-efficient sense amplifier (SA) circuits are essential for reliable detection of stored memory states in emerging memory systems. In this work, we introduce three novel sense amplifier topologies based on phase transition materials (PTM) in addition to the previously proposed one, collectively analyzing all four designs tailored for non-volatile memory applications. We utilize the abrupt switching and volatile hysteretic characteristics of PTMs which enables efficient and fast sensing operation in our proposed SA topologies. We provide comprehensive details of their functionality and assess how process variations impact their performance metrics. Our proposed sense amplifier topologies manifest notable performance enhancement. We achieve a ∼67% reduction in sensing delay and a ∼80% decrease in sensing power for current sensing. For voltage sensing, we achieve a ∼75% reduction in sensing delay and a ∼33% decrease in sensing power. Moreover, the proposed SA topologies exhibit improved variation robustness compared to conventional SAs. We also scrutinize the dependence of transistor mirroring window and PTM transition voltages on several device parameters to determine the optimum operating conditions and stance of tunability for each of the proposed SA topologies.
AB - Energy-efficient sense amplifier (SA) circuits are essential for reliable detection of stored memory states in emerging memory systems. In this work, we introduce three novel sense amplifier topologies based on phase transition materials (PTM) in addition to the previously proposed one, collectively analyzing all four designs tailored for non-volatile memory applications. We utilize the abrupt switching and volatile hysteretic characteristics of PTMs which enables efficient and fast sensing operation in our proposed SA topologies. We provide comprehensive details of their functionality and assess how process variations impact their performance metrics. Our proposed sense amplifier topologies manifest notable performance enhancement. We achieve a ∼67% reduction in sensing delay and a ∼80% decrease in sensing power for current sensing. For voltage sensing, we achieve a ∼75% reduction in sensing delay and a ∼33% decrease in sensing power. Moreover, the proposed SA topologies exhibit improved variation robustness compared to conventional SAs. We also scrutinize the dependence of transistor mirroring window and PTM transition voltages on several device parameters to determine the optimum operating conditions and stance of tunability for each of the proposed SA topologies.
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U2 - 10.1109/TNANO.2024.3438542
DO - 10.1109/TNANO.2024.3438542
M3 - Article
AN - SCOPUS:85200798245
SN - 1536-125X
VL - 23
SP - 606
EP - 614
JO - IEEE Transactions on Nanotechnology
JF - IEEE Transactions on Nanotechnology
ER -