一种新型多节点抗扰辐射硬化SOT-MRAM读电路

IF 1.8 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY
Alok Kumar Shukla;Seema Dhull;Arshid Nisar;Sandeep Soni;Namita Bindal;Brajesh Kumar Kaushik
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引用次数: 4

摘要

晶体管的快速缩小和阈值电压的降低带来了一些挑战,如高泄漏电流和可靠性问题。这些挑战也使VLSI电路更容易受到软错误的影响,特别是在恶劣的环境条件下。自旋电子/CMOS混合技术已成为实现低泄漏功率和无挥发性的有前途的技术之一。此外,自旋电子存储器具有固有的抗重离子辐照和总电离剂量等辐射效应的特性。然而,其CMOS外围电路更容易受到辐射引起的单事件干扰(SEU)和双节点干扰(DNU)。本文提出了一种新的45nm工艺的抗辐射SOT磁随机存取存储器(MRAM)读电路。与先前报道的设计相比,所提出的电路对所有可能的seu和dnu具有很高的抵抗力。结果表明,与交叉耦合CMOS晶体管、11T、13T和11T辐射硬化电路相比,该电路的临界电荷承受能力分别提高4.5倍、11X、9X和10.5倍。此外,与交叉耦合CMOS晶体管电路相比,该电路的恢复时间提高了20%。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Novel Radiation Hardened SOT-MRAM Read Circuit for Multi-Node Upset Tolerance
The rapid transistor scaling and threshold voltage reduction pose several challenges such as high leakage current and reliability issues. These challenges also make VLSI circuits more susceptible to soft-errors, particularly when subjected to harsh environmental conditions. Hybrid spintronic/CMOS technology has emerged as one of the promising techniques to achieve low leakage power and non-volatility. Moreover, the spintronic memories are inherently resistant to the radiation effects such as heavy-ion irradiation and total ionizing dose. However, its CMOS peripheral circuitry is more susceptible to radiation-induced single-event upset (SEU) and double-node upset (DNU). In this paper, a new radiation-hardened read circuit for SOT magnetic random access memory (MRAM) on 45nm technology has been presented. The proposed circuit is highly resistant to all the probable SEUs and DNUs when compared to the previously reported designs. The results show that it can tolerate 4.5X, 11X, 9X, and 10.5X more critical charge as compared to the cross-coupled CMOS transistor, 11T, 13T, and 11T radiation hardened circuits, respectively. Moreover, the recovery time of the proposed circuit is improved by 20% when compared to cross-coupled CMOS transistor circuits.
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来源期刊
CiteScore
3.90
自引率
17.60%
发文量
10
审稿时长
12 weeks
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