0.4 v STT-MRAM可耐受工艺变化的计数器读电路

Q4 Engineering
Youhei Umeki, Koji Yanagida, S. Yoshimoto, S. Izumi, M. Yoshimoto, H. Kawaguchi, K. Tsunoda, T. Sugii
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引用次数: 1

摘要

lsi上的嵌入式存储器容量不断增加。对于低功耗lsi来说,降低嵌入式存储器的漏功率是非常重要的。事实上,ITRS预测,到2024年,嵌入式存储器的泄漏功率将占总功耗的40%[1]。自旋转移转矩磁阻随机存取存储器(STT-MRAM)有望用作非易失性存储器,以降低泄漏功率。它很有用,因为它可以在低电压下工作,并且具有超过1016个写入周期的寿命[2]。此外,STT-MRAM技术具有比SRAM更小的位单元。制作STT-MRAM适用于高密度产品[3-7]。STT-MRAM采用磁隧道结(MTJ)。MTJ有两种状态:并行状态和反并行状态。这些状态意味着MTJ各层的磁化方向相同或不同。方向对决定了MTJ的磁阻值。电流的流动可以改变MTJ的状态。并联时MTJ电阻变低,反并联时变高。MTJ的潜在工作电压低于0.4 V[8]。另一方面,在如此低的电压下为STT-MRAM阵列设计外围电路是很困难的。在本文中,我们提出了一种基于计数器的读取电路,该电路工作在0.4 V,可以容忍工艺变化和温度波动。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Counter-based Read Circuit Tolerant to Process Variation for 0.4-V Operating STT-MRAM
The capacity of embedded memory on LSIs has kept increasing. It is important to reduce the leakage power of embedded memory for low-power LSIs. In fact, the ITRS predicts that the leakage power in embedded memory will account for 40% of all power consumption by 2024 [1]. A spin transfer torque magneto-resistance random access memory (STT-MRAM) is promising for use as non-volatile memory to reduce the leakage power. It is useful because it can function at low voltages and has a lifetime of over 1016 write cycles [2]. In addition, the STT-MRAM technology has a smaller bit cell than an SRAM. Making the STT-MRAM is suitable for use in high-density products [3–7]. The STT-MRAM uses magnetic tunnel junction (MTJ). The MTJ has two states: a parallel state and an anti-parallel state. These states mean that the magnetization direction of the MTJ’s layers are the same or different. The directions pair determines the MTJ’s magneto- resistance value. The states of MTJ can be changed by the current flowing. The MTJ resistance becomes low in the parallel state and high in the anti-parallel state. The MTJ potentially operates at less than 0.4 V [8]. In other hands, it is difficult to design peripheral circuitry for an STT-MRAM array at such a low voltage. In this paper, we propose a counter-based read circuit that functions at 0.4 V, which is tolerant of process variation and temperature fluctuation.
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来源期刊
IPSJ Transactions on System LSI Design Methodology
IPSJ Transactions on System LSI Design Methodology Engineering-Electrical and Electronic Engineering
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