Bimodal alteration of cognitive accuracy for spintronic artificial neural networks

IF 5.4 2区医学 Q2 MATERIALS SCIENCE, BIOMATERIALS

ACS Biomaterials Science & Engineering Pub Date : 2024-07-02 DOI:10.1039/D4NH00097H

Anuj Kumar, Debasis Das, Dennis J. X. Lin, Lisen Huang, Sherry L. K. Yap, Hang Khume Tan, Royston J. J. Lim, Hui Ru Tan, Yeow Teck Toh, Sze Ter Lim, Xuanyao Fong and Pin Ho

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Abstract

Spintronics-based artificial neural networks (ANNs) exhibiting nonvolatile, fast, and energy-efficient computing capabilities are promising neuromorphic hardware for performing complex cognitive tasks of artificial intelligence and machine learning. Early experimental efforts focused on multistate device concepts to enhance synaptic weight precisions, albeit compromising on cognitive accuracy due to their low magnetoresistance. Here, we propose a hybrid approach based on the tuning of tunnel magnetoresistance (TMR) and the number of states in the compound magnetic tunnel junctions (MTJs) to improve the cognitive performance of an all-spin ANN. A TMR variation of 33–78% is controlled by the free layer (FL) thickness wedge (1.6–2.6 nm) across the wafer. Meanwhile, the number of resistance states in the compound MTJ is manipulated by varying the number of constituent MTJ cells (n = 1–3), generating n + 1 states with a TMR difference between consecutive states of at least 21%. Using MNIST handwritten digit and fashion object databases, the test accuracy of the compound MTJ ANN is observed to increase with the number of intermediate states for a fixed FL thickness or TMR. Meanwhile, the test accuracy for a 1-cell MTJ increases linearly by 8.3% and 7.4% for handwritten digits and fashion objects, respectively, with increasing TMR. Interestingly, a multifarious TMR dependence of test accuracy is observed with the increasing synaptic complexity in the 2- and 3-cell MTJs. By leveraging on the bimodal tuning of multilevel and TMR, we establish viable paths for enhancing the cognitive performance of spintronic ANN for in-memory and neuromorphic computing.

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双模改变自旋电子人工神经网络的认知准确性

基于自旋电子学的人工神经网络（ANN）具有非易失性、快速和节能的计算能力，是执行人工智能和机器学习复杂认知任务的有前途的神经形态硬件。早期的实验工作主要集中在多态器件概念上，以提高突触权重的精确度，但由于其磁电阻较低，认知精确度受到影响。在这里，我们提出了一种基于隧道磁阻（TMR）和复合磁隧道结（MTJ）中状态数量调整的混合方法，以提高全旋 ANN 的认知性能。整个晶片的自由层（FL）厚度楔形（1.6-2.6 nm）可控制 33-78% 的 TMR 变化。同时，通过改变组成 MTJ 单元的数量（n = 1-3）来控制复合 MTJ 中电阻状态的数量，产生 n + 1 个状态，连续状态之间的 TMR 差至少为 21%。通过使用 MNIST 手写数字和时尚物品数据库，可以观察到在 FL 厚度或 TMR 固定的情况下，复合 MTJ ANN 的测试准确率随着中间状态数量的增加而提高。同时，随着 TMR 的增加，1 单元 MTJ 的手写数字和时尚物品测试准确率分别线性增加了 8.3% 和 7.4%。有趣的是，随着 2 细胞和 3 细胞 MTJ 中突触复杂性的增加，测试准确性与 TMR 呈多种依赖关系。通过利用多级和 TMR 的双模调谐，我们为提高用于内存和神经形态计算的自旋电子 ANN 的认知性能建立了可行的途径。

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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来源期刊

ACS Biomaterials Science & Engineering Materials Science-Biomaterials

CiteScore

10.30

自引率

3.40%

发文量

413

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