Reliability-Enhanced Separated Pre-Charge Sensing Amplifier for Hybrid CMOS/MTJ Logic Circuits

Benefitting from its non-volatility, low power, high speed, nearly infinite endurance, good scalability, and great CMOS compatibility, magnetic tunnel junction (MTJ) embedded in conventional CMOS logic circuits has been proposed as one potentially powerful solution to introduce non-volatility in tod...

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Veröffentlicht in:	IEEE transactions on magnetics 2017-09, Vol.53 (9), p.1-5
Hauptverfasser:	Deming Zhang, Lang Zeng, Tianqi Gao, Fanghui Gong, Xiaowan Qin, Wang Kang, Yue Zhang, Youguang Zhang, Klein, Jacques Olivier, Weisheng Zhao
Format:	Artikel
Sprache:	eng
Schlagworte:	Circuit reliability Circuits CMOS Computer simulation Detection Discharges (electric) Electric charge Electric discharges Electronics Endurance Error detection Field programmable gate arrays Hybrid CMOS/MTJ logic circuit Integrated circuit reliability Logic circuits magnetic tunnel junction (MTJ) Magnetic tunneling Magnetism Monte Carlo simulation non-volatility Product development Resistance Semiconductor devices sensing reliability Sensors Transistors Volatility
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container_title	IEEE transactions on magnetics
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creator	Deming Zhang Lang Zeng Tianqi Gao Fanghui Gong Xiaowan Qin Wang Kang Yue Zhang Youguang Zhang Klein, Jacques Olivier Weisheng Zhao
description	Benefitting from its non-volatility, low power, high speed, nearly infinite endurance, good scalability, and great CMOS compatibility, magnetic tunnel junction (MTJ) embedded in conventional CMOS logic circuits has been proposed as one potentially powerful solution to introduce non-volatility in today's programmable logic circuits, which is envisioned to extend Moore's law. However, a critical issue in such hybrid CMOS/MTJ logic circuit is the reliable transmission of MTJ electric signals to the CMOS electronics, i.e., the requirement of nearly zero read/write error for logic applications. In this paper, a reliability-enhanced separated pre-charge sensing amplifier (RESPCSA) is proposed for hybrid CMOS/MTJ logic circuits. By adding two feedback paths with only two transistors between its discharge and evaluation terminal, such proposed RESPCSA can achieve a more and more larger dynamic resistance difference between its two discharge branches with the MTJs during the discharge phase, thereby obtaining a large sensing margin. By using a commercial CMOS 40 nm design kit and a physics-based MTJ compact model, hybrid CMOS/MTJ transient and Monte-Carlo statistic simulations have been conducted to demonstrate its functionality and evaluate its performance, respectively.
doi_str_mv	10.1109/TMAG.2017.2702743
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However, a critical issue in such hybrid CMOS/MTJ logic circuit is the reliable transmission of MTJ electric signals to the CMOS electronics, i.e., the requirement of nearly zero read/write error for logic applications. In this paper, a reliability-enhanced separated pre-charge sensing amplifier (RESPCSA) is proposed for hybrid CMOS/MTJ logic circuits. By adding two feedback paths with only two transistors between its discharge and evaluation terminal, such proposed RESPCSA can achieve a more and more larger dynamic resistance difference between its two discharge branches with the MTJs during the discharge phase, thereby obtaining a large sensing margin. 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However, a critical issue in such hybrid CMOS/MTJ logic circuit is the reliable transmission of MTJ electric signals to the CMOS electronics, i.e., the requirement of nearly zero read/write error for logic applications. In this paper, a reliability-enhanced separated pre-charge sensing amplifier (RESPCSA) is proposed for hybrid CMOS/MTJ logic circuits. By adding two feedback paths with only two transistors between its discharge and evaluation terminal, such proposed RESPCSA can achieve a more and more larger dynamic resistance difference between its two discharge branches with the MTJs during the discharge phase, thereby obtaining a large sensing margin. 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subjects	Circuit reliability Circuits CMOS Computer simulation Detection Discharges (electric) Electric charge Electric discharges Electronics Endurance Error detection Field programmable gate arrays Hybrid CMOS/MTJ logic circuit Integrated circuit reliability Logic circuits magnetic tunnel junction (MTJ) Magnetic tunneling Magnetism Monte Carlo simulation non-volatility Product development Resistance Semiconductor devices sensing reliability Sensors Transistors Volatility
title	Reliability-Enhanced Separated Pre-Charge Sensing Amplifier for Hybrid CMOS/MTJ Logic Circuits
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