A body-voltage-sensing-based short pulse reading circuit for spin-torque transfer RAMs (STT-RAMs)

Thirteenth International Symposium on Quality Electronic Design (ISQED) Pub Date : 2012-03-19 DOI:10.1109/ISQED.2012.6187506

Fengbo Ren, Henry Park, R. Dorrance, Y. Toriyama, C. Yang, D. Markovic

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引用次数: 31

Abstract

With scaling of CMOS and Magnetic Tunnel Junction (MTJ) devices, conventional low-current reading techniques for STT-RAMs face challenges in achieving reliability and performance improvements that are expected from scaled devices. The challenges arise from the increasing variability of the CMOS sensing current and the reduction in MTJ switching current. This paper proposes a short-pulse reading circuit, based on a body-voltage sensing scheme to mitigate the scaling issues. Compared to existing sensing techniques, our technique shows substantially higher read margin (RM) despite a much shorter sensing time. A narrow current pulse applied to an MTJ significantly reduces the probability of read disturbance. The RM analysis is validated by Monte-Carlo simulations in a 65-nm CMOS technology with both CMOS and MTJ variations considered. Simulation results show that our technique is able to provide over 300 mV RM at a GHz frequency across process-voltage-temperature (PVT) variations, while the reference designs require 4.3 ns and 2.3 ns sensing time for a 200 mV RM, respectively. The effective read energy per bit required by the proposed sensing circuit is around 195 ft in the nominal case.

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基于体电压传感的自旋转矩传递RAMs (STT-RAMs)短脉冲读取电路

随着CMOS和磁隧道结(MTJ)器件的规模化，传统的stt - ram低电流读取技术在实现规模化器件预期的可靠性和性能改进方面面临挑战。挑战来自于CMOS传感电流的变异性增加和MTJ开关电流的减小。本文提出了一种基于体压传感方案的短脉冲读取电路，以缓解标度问题。与现有的传感技术相比，我们的技术在更短的传感时间内显示出更高的读取裕度(RM)。在MTJ上施加窄电流脉冲可显著降低读取干扰的概率。在考虑了CMOS和MTJ变化的65纳米CMOS技术中，通过蒙特卡罗模拟验证了RM分析。仿真结果表明，我们的技术能够在GHz频率下跨越工艺电压温度(PVT)变化提供超过300 mV的RM，而参考设计分别需要4.3 ns和2.3 ns的200 mV RM传感时间。在标称情况下，所提出的传感电路所需的每比特有效读取能量约为195英尺。

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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Thirteenth International Symposium on Quality Electronic Design (ISQED)

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