利用压控磁各向异性和自旋轨道转矩磁隧道结产生随机比特流

IF 2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE IEEE Journal on Exploratory Solid-State Computational Devices and Circuits Pub Date : 2022-12-23 DOI:10.1109/JXCDC.2022.3231550
Samuel Liu;Jaesuk Kwon;Paul W. Bessler;Suma G. Cardwell;Catherine Schuman;J. Darby Smith;James B. Aimone;Shashank Misra;Jean Anne C. Incorvia
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引用次数: 5

摘要

使用随机数生成器(RNG)的概率计算可以利用纳米器件固有的随机性来获得系统级的好处。该应用程序的候选设备需要产生高度随机的“硬币翻转”,同时还具有可调的硬币偏置。磁性隧道结(MTJ)由于其热驱动的磁化动力学而被研究为RNG,通常使用自旋转移力矩(STT)电流幅度来控制MTJ自由层(FL)磁化的随机切换,这里称为随机写入方法。有额外的旋钮来控制MTJ-RNG,包括压控磁各向异性(VCMA)和自旋轨道转矩(SOT),需要系统地研究和比较这些方法。我们建立了一个MTJ的分析模型,使用VCMA和SOT生成随机比特流进行表征。结果表明,这两种方法都能产生高质量、均匀分布的比特流。使用STT电流或施加的磁场对比特流进行偏置显示出VCMA和SOT相对于偏置幅度的S形分布,而随机写入的S形较小。每个样本的能量消耗计算为0.1pJ(SOT)、1pJ(随机写入)和20pJ(VCMA),揭示了使用SOT的潜在能量效益,并表明使用VCMA可能需要更高的阻尼材料。然后将生成的比特流应用于两个任务:生成任意概率分布,并使用MTJ RNG作为随机神经元来执行模拟退火,其中VCMA和SOT方法都显示出以小延迟和低能量有效最小化系统能量的能力。这些结果显示了MTJ作为真正RNG的灵活性,并阐明了用于优化应用的设备操作的设计参数。
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Random Bitstream Generation Using Voltage-Controlled Magnetic Anisotropy and Spin Orbit Torque Magnetic Tunnel Junctions
Probabilistic computing using random number generators (RNGs) can leverage the inherent stochasticity of nanodevices for system-level benefits. Device candidates for this application need to produce highly random “coinflips” while also having tunable biasing of the coin. The magnetic tunnel junction (MTJ) has been studied as an RNG due to its thermally-driven magnetization dynamics, often using spin transfer torque (STT) current amplitude to control the random switching of the MTJ free layer (FL) magnetization, here called the stochastic write method. There are additional knobs to control the MTJ-RNG, including voltage-controlled magnetic anisotropy (VCMA) and spin orbit torque (SOT), and there is a need to systematically study and compare these methods. We build an analytical model of the MTJ to characterize using VCMA and SOT to generate random bit streams. The results show that both methods produce high-quality, uniformly distributed bitstreams. Biasing the bitstreams using either STT current or an applied magnetic field shows a sigmoidal distribution versus bias amplitude for both VCMA and SOT, compared to less sigmoidal for stochastic write. The energy consumption per sample is calculated to be 0.1 pJ (SOT), 1 pJ (stochastic write), and 20 pJ (VCMA), revealing the potential energy benefit of using SOT and showing using VCMA may require higher damping materials. The generated bitstreams are then applied to two tasks: generating an arbitrary probability distribution and using the MTJ-RNGs as stochastic neurons to perform simulated annealing, where both VCMA and SOT methods show the ability to effectively minimize the system energy with a small delay and low energy. These results show the flexibility of the MTJ as a true RNG and elucidate design parameters for optimizing the device operation for applications.
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来源期刊
CiteScore
5.00
自引率
4.20%
发文量
11
审稿时长
13 weeks
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