Energy-Efficient, Two-Dimensional Analog Memory for Neuromorphic Computing

2018 76th Device Research Conference (DRC) Pub Date : 2018-06-01 DOI:10.1109/DRC.2018.8442140

M. Sharbati, Yanhao Du, Feng Xiong

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Abstract

Unlike modern computers that use digital ‘0’ and ‘1’ for computation, neural networks in human brains exhibit analog changes in neural connections (i.e. synaptic weight) during the decision-making and learning processes. This analog nature as well as the neural network's massive parallelism are partly why human brains (~20 W) are much better at complex tasks such as pattern recognition than even the most powerful computers (~1 MW) with significantly better energy efficiency. Currently, majority of the research efforts towards developing artificial neural networks are based on digital technology with CMOS devices [1], which cannot mimic the analog behaviors of biological synapses and thus energy-extensive. Recently, emerging memory devices such as phase change memory (PCM), resistive random access memory (RRAM), and spin-torque transfer (STT) RAM [2]–[4] have been studied to mimic synaptic connections with their programmable conductance. While these approaches are promising, they still face various limitations such as poor controllability, subpar reliability, large variability, and non-symmetrical resistance response.

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用于神经形态计算的高能效二维模拟存储器

与使用数字“0”和“1”进行计算的现代计算机不同，人类大脑中的神经网络在决策和学习过程中表现出神经连接(即突触权重)的模拟变化。这种模拟性质以及神经网络的大规模并行性部分解释了为什么人类大脑(~ 20w)在模式识别等复杂任务上比最强大的计算机(~ 1mw)表现得更好，而且能效显著提高。目前，大多数开发人工神经网络的研究工作都是基于CMOS器件的数字技术[1]，无法模拟生物突触的模拟行为，因此耗费大量能量。最近，人们研究了相变存储器(PCM)、电阻随机存取存储器(RRAM)和自旋转矩传递存储器(STT)[2] -[4]等新兴存储器件来模拟具有可编程电导的突触连接。虽然这些方法很有前途，但它们仍然面临各种限制，如可控性差、可靠性欠佳、可变性大、电阻响应不对称等。

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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2018 76th Device Research Conference (DRC)

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