电阻性非易失性逻辑电路的容差分离预充感测放大器

Jooyoon Kim, Jongsun Park
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引用次数: 2

摘要

由于基于CMOS的逻辑电路的可扩展性和泄漏功率有限,自旋传递扭矩(STT)器件具有低面积、零泄漏功率、非易失性和无限耐用性等特点,是克服CMOS局限性的最有力候选器件之一。基于这些特点,人们努力开发stt器件逻辑电路。然而,stt器件逻辑电路却遇到了读取可靠性的问题。为了解决读取可靠性问题,我们提出了一种新的传感放大器,即容差分离预充式传感放大器。该电路采用传输门和反馈电路,对工艺变化具有良好的适应能力,具有较高的读取可靠性。采用65nm工艺进行了仿真,以显示所提出的传感电路的性能。仿真结果表明,与传统的SPCSA和RESPCSA相比,该传感器的读取误差率分别降低了68%和37%。
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Variation-Tolerant Separated Pre-Charge Sense Amplifier for Resistive Non-Volatile logic circuit
Due to limited scalability and leakage power of CMOS-based logic circuit, Spin Transfer Torque (STT) device, which has the characteristics of a low area, zero leakage power, nonvolatile and infinite endurance, is one of the strongest candidates to overcome limitations of CMOS. Based on these characteristics, efforts have been made to develop STT-device logic circuit. However, STT-device logic circuit has encountered the problem of read reliability. To address read reliability issue, we propose a new Sense amplifier, named variation-tolerant separated precharge sense amplifier. This circuit, by using transmission gate and feedback, is resilient to process variation and has high read reliability. Simulation using the 65nm process is conducted to show the performance of the proposed sensing circuit. Simulation results demonstrate that the reading error rate of the proposed sense amplifier decreased by 68% and 37% respectively, compared to the conventional SPCSA and RESPCSA.
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