In-sensor neuromorphic computing using perovskites and transition metal dichalcogenides

Shen-Yi Li, Ji-Tuo Li, Kui Zhou, Yan Yan, Guanglong Ding, Su-Ting Han and Ye Zhou
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Abstract

With the advancements in Web of Things, Artificial Intelligence, and other emerging technologies, there is an increasing demand for artificial visual systems to perceive and learn about external environments. However, traditional sensing and computing systems are limited by the physical separation of sense, processing, and memory units that results in the challenges such as high energy consumption, large additional hardware costs, and long latency time. Integrating neuromorphic computing functions into the sensing unit is an effective way to overcome these challenges. Therefore, it is extremely important to design neuromorphic devices with sensing ability and the properties of low power consumption and high switching speed for exploring in-sensor computing devices and systems. In this review, we provide an elementary introduction to the structures and properties of two common optoelectronic materials, perovskites and transition metal dichalcogenides (TMDs). Subsequently, we discuss the fundamental concepts of neuromorphic devices, including device structures and working mechanisms. Furthermore, we summarize and extensively discuss the applications of perovskites and TMDs in in-sensor computing. Finally, we propose potential strategies to address challenges and offer a brief outlook on the application of optoelectronic materials in term of in-sensor computing.
使用过氧化物和过渡金属二卤化物的传感器内神经形态计算
随着物联网、人工智能和其他新兴技术的发展,人们越来越需要人工视觉系统来感知和了解外部环境。然而,传统的感知和计算系统受限于感知、处理和存储单元的物理分离,导致能耗高、额外硬件成本大、延迟时间长等挑战。将神经形态计算功能集成到感知单元中是克服这些挑战的有效方法。因此,设计具有传感能力、低功耗和高开关速度特性的神经形态设备对于探索传感内计算设备和系统极为重要。在这篇综述中,我们首先介绍了两种常见光电材料--包晶和过渡金属二掺杂物(TMDs)的结构和特性。随后,我们讨论了神经形态设备的基本概念,包括设备结构和工作机制。此外,我们还总结并广泛讨论了包晶和 TMD 在传感计算中的应用。最后,我们提出了应对挑战的潜在策略,并简要展望了光电材料在传感计算方面的应用。
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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