Analog Spike Processing with High Scalability and Low Energy Consumption Using Thermal Degree of Freedom in Phase Transition Materials

T. Yajima, T. Nishimura, A. Toriumi
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引用次数: 4

Abstract

Spike integration and threshold processing are the basic signal processing in brain-inspired computing, such as deep learning, reservoir computing etc. In such processes, analog technology is essential for suppressing energy consumption. However, analog technology often faces problems in miniaturization due to deteriorated noise tolerance by scaling and intrinsically large analog elements such as capacitors. Here, we propose to exploit a thermal degree of freedom in phase transition materials for scalable and noise-tolerant analog spike processing. We focus on a two-terminal metal-insulator-transition VO2 device, where quasi-adiabatic Joule heating enables efficient spike integration, and metal-insulator transition implements threshold processing. This VO2 device is highly scalable, consuming only ~1fJ/spike (smallest so far) according to the simulation. By using this device, fully autonomous spike integration and threshold processing are also demonstrated. Exploiting the quasi-adiabatic thermal degree of freedom will facilitate scalable and energy-efficient analog implementation for a wide range of brain-inspired computing.
基于相变材料热自由度的高可扩展性和低能耗模拟尖峰处理
尖峰积分和阈值处理是深度学习、储层计算等脑启发计算中的基本信号处理方法。在这样的过程中,模拟技术是必不可少的,以抑制能源消耗。然而,模拟技术往往面临小型化的问题,由于缩放和本质上较大的模拟元件,如电容器的噪声容限恶化。在这里,我们建议利用相变材料的热自由度来进行可扩展和耐噪声的模拟尖峰处理。我们重点研究了一种双端金属-绝缘体过渡VO2器件,其中准绝热焦耳加热实现了高效的尖峰集成,金属-绝缘体过渡实现了阈值处理。该VO2器件具有高度可扩展性,根据模拟,仅消耗~1fJ/spike(迄今为止最小)。利用该装置,还演示了完全自主的脉冲集成和阈值处理。利用准绝热自由度将促进可扩展和节能的模拟实现,用于广泛的脑启发计算。
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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