Ferroelectric-based synapses and neurons for neuromorphic computing

Neuromorph. Comput. Eng. Pub Date : 2022-01-07 DOI:10.1088/2634-4386/ac4918

E. Covi, H. Mulaosmanovic, B. Max, S. Slesazeck, T. Mikolajick

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引用次数: 27

Abstract

The shift towards a distributed computing paradigm, where multiple systems acquire and elaborate data in real-time, leads to challenges that must be met. In particular, it is becoming increasingly essential to compute on the edge of the network, close to the sensor collecting data. The requirements of a system operating on the edge are very tight: power efficiency, low area occupation, fast response times, and on-line learning. Brain-inspired architectures such as Spiking Neural Networks (SNNs) use artificial neurons and synapses that simultaneously perform low-latency computation and internal-state storage with very low power consumption. Still, they mainly rely on standard complementary metal-oxide-semiconductor (CMOS) technologies, making SNNs unfit to meet the aforementioned constraints. Recently, emerging technologies such as memristive devices have been investigated to flank CMOS technology and overcome edge computing systems' power and memory constraints. In this review, we will focus on ferroelectric technology. Thanks to its CMOS-compatible fabrication process and extreme energy efficiency, ferroelectric devices are rapidly affirming themselves as one of the most promising technology for neuromorphic computing. Therefore, we will discuss their role in emulating neural and synaptic behaviors in an area and power-efficient way.

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基于铁电的突触和神经元用于神经形态计算

向分布式计算范式的转变，即多个系统实时获取和详细处理数据，带来了必须应对的挑战。特别是，在网络边缘、靠近传感器收集数据的地方进行计算变得越来越重要。在边缘上运行的系统的要求非常严格:功率效率，占地面积小，响应时间快，在线学习。以大脑为灵感的架构，如脉冲神经网络(snn)使用人工神经元和突触，同时以极低的功耗执行低延迟计算和内部状态存储。然而，它们主要依赖于标准的互补金属氧化物半导体(CMOS)技术，使得snn不适合满足上述限制。最近，人们研究了诸如记忆器件之类的新兴技术来辅助CMOS技术，以克服边缘计算系统的功率和内存限制。在这篇综述中，我们将重点介绍铁电技术。由于其与cmos兼容的制造工艺和极高的能源效率，铁电器件正迅速成为最有前途的神经形态计算技术之一。因此，我们将讨论它们在模拟神经和突触行为方面的作用，以一种区域和节能的方式。

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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Neuromorph. Comput. Eng.

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