Lele Ashwin Sanjay, Zhang Bo, Khwa Win-San, Chang Meng-Fan
Corporate Research, TSMC, San Jose, California 95134, United States.
Corporate Research, TSMC, Hsinchu, 300-094, Taiwan.
Nano Lett. 2025 Jan 29;25(4):1243-1249. doi: 10.1021/acs.nanolett.4c05299. Epub 2025 Jan 13.
Unprecedented penetration of artificial intelligence (AI) algorithms has brought about rapid innovations in electronic hardware, including new memory devices. Nonvolatile memory (NVM) devices offer one such attractive alternative with ∼2× density and data retention after powering off. Compute-in-memory (CIM) architectures further improve energy efficiency by fusing the computation operations with AI model storage. Electronic characteristics of NVM devices, like resistance in the two resistance states, directly affect the circuit designers' decisions and result in the varying performance of NVM-CIM chips. In this mini review, we assess the bounds on device resistances for accuracy and circuit performance to suggest recommendations to device engineers for frictionless device-circuit-system interactions. Furthermore, we review challenges in reliably programming NVM devices, followed by benchmarking recent NVM-CIM chips. Our literature review and analytical modeling reveal that a high resistance ratio and low variability are favored, and the resistance in a low resistance state is bound by accuracy and circuit performance constraints.
人工智能(AI)算法前所未有的渗透给电子硬件带来了快速创新,包括新型存储设备。非易失性存储器(NVM)设备提供了一种颇具吸引力的选择,其密度约为传统设备的2倍,并且断电后仍能保留数据。存内计算(CIM)架构通过将计算操作与AI模型存储相融合,进一步提高了能源效率。NVM设备的电子特性,如两种电阻状态下的电阻,直接影响电路设计者的决策,并导致NVM-CIM芯片性能各异。在本综述中,我们评估了器件电阻在精度和电路性能方面的限制,为器件工程师提供建议,以实现器件-电路-系统的无缝交互。此外,我们回顾了可靠编程NVM设备所面临的挑战,随后对近期的NVM-CIM芯片进行了基准测试。我们的文献综述和分析模型表明,高电阻比和低变异性是有利的,低电阻状态下的电阻受到精度和电路性能的限制。
