MESO-CMOS Hybrid Circuits With Time-Multiplexing Technique for Energy and Area-Efficient Computing in Memory

IF 2 Q3 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE Journal on Exploratory Solid-State Computational Devices and Circuits Pub Date : 2025-01-16 DOI:10.1109/JXCDC.2025.3530906

Tzuping Huang;Linran Zhao;Yiming Han;Hai Li;Ian A. Young;Yaoyao Jia

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Abstract

The magnetoelectric spin orbit (MESO), one of the emerging spin devices, represents a promising alternative to complementary metal-oxide–semiconductor (CMOS) technology. MESO provides dual functionality: each device can perform logic operations while acting as a nonvolatile memory device. MESO also offers advantages, such as an ultralow supply voltage of 100 mV and the potential to vertically integrate with CMOS, which promises significant energy and area efficiency. These features support MESO’s suitability for improving the energy efficiency and area efficiency of computing-in-memory (CIM) circuits. To harness the advantages of MESO in large-scale complex circuit systems, this article presents the development of a MESO-based standard cell library. This library is critical to realize automated design, as it allows the implementation of all the basic CMOS functions with MESO, thereby enabling MESO-CMOS hybrid design in large-scale complex circuits. This article also introduces a highly area-efficient time-multiplexing technique to optimize the complex function inside CIM. Specifically, the multiplier and multiply-and-accumulate (MAC) circuits using the MESO-CMOS hybrid time-multiplexing technique reduce the area by 85% and 81%, respectively, compared to CMOS implementations.

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基于时间复用技术的MESO-CMOS混合电路在内存中的能量和面积高效计算

磁电自旋轨道（MESO）是一种新兴的自旋器件，代表了互补金属氧化物半导体（CMOS）技术的一个有前途的替代方案。MESO提供双重功能：每个器件都可以执行逻辑操作，同时充当非易失性存储器器件。MESO还具有一些优势，例如100 mV的超低电源电压以及与CMOS垂直集成的潜力，从而保证了显著的能量和面积效率。这些特性支持MESO在提高内存计算（CIM）电路的能效和面积效率方面的适用性。为了利用MESO在大型复杂电路系统中的优势，本文提出了基于MESO的标准单元库的开发。该库是实现自动化设计的关键，因为它允许用MESO实现所有基本的CMOS功能，从而实现大规模复杂电路的MESO-CMOS混合设计。本文还介绍了一种高效的时间复用技术，用于优化CIM内部的复杂功能。具体来说，与CMOS实现相比，使用MESO-CMOS混合时间复用技术的乘法器和乘积（MAC）电路分别减少了85%和81%的面积。

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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