神经形态计算系统:从CMOS到新兴的非易失性存储器

Q4 Engineering
Chaofei Yang, Ximing Qiao, Yiran Chen
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引用次数: 0

摘要

摩尔定律和冯·诺依曼瓶颈的终结促使研究人员寻求替代架构,以满足对计算资源日益增长的需求,这是传统计算范式难以实现的。神经形态计算系统(neural morphic computing system, NCS)是模拟神经元和突触的双生物学行为,加速神经网络计算的重要方法之一。然而,传统的基于cmos的NCS实现需要大量的硬件成本来精确地复制生物特性。近十年来,新兴的非易失性存储器(eNVM)因其高计算效率和集成密度而被引入NCS设计。与建立在其他纳米级器件上的电路类似,基于envm的NCS也存在许多可靠性问题。本文简要介绍了基于CMOS和envm的NCS,包括它们的基本实现以及在各种应用中的训练和推理方案。我们还讨论了这些网络控制系统的设计挑战,并介绍了一些可以提高网络控制系统的可靠性、精度、可扩展性和安全性的技术。最后,我们对NCS的设计趋势和未来挑战提出了自己的见解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Neuromorphic Computing Systems: From CMOS To Emerging Nonvolatile Memory
: The end of Moore’s Law and von Neumann bottleneck motivate researchers to seek alternative architec- tures that can fulfill the increasing demand for computation resources which cannot be easily achieved by traditional computing paradigm. As one important practice, neuromorphic computing systems (NCS) are proposed to mimic bi- ological behaviors of neurons and synapses, and accelerate computation of neural networks. Traditional CMOS-based implementation of NCS, however, are subject to large hardware cost required to precisely replicate the biological prop- erties. In very recent decade, emerging nonvolatile memory (eNVM) was introduced to NCS design due to its high computing e ffi ciency and integration density. Similar to the circuits built on other nanoscale devices, eNVM-based NCS also su ff ers from many reliability issues. In this paper, we give a short survey about CMOS- and eNVM-based NCS, including their basic implementations and training and inference schemes in various applications. We also dis- cuss the design challenges of these NCS and introduce some techniques that can improve the reliability, precision, scalability, and security of the NCS. At the end, we provide our insights on the design trend and future challenges of the NCS.
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来源期刊
IPSJ Transactions on System LSI Design Methodology
IPSJ Transactions on System LSI Design Methodology Engineering-Electrical and Electronic Engineering
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