Energy efficient fJ/spike LTS e-Neuron using 55-nm node

2019 32nd Symposium on Integrated Circuits and Systems Design (SBCCI) Pub Date : 2019-08-26 DOI:10.1145/3338852.3339852

Pietro M. Ferreira, Nathan De Carvalho, G. Klisnick, Aziz Benlarbi-Delaï

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引用次数: 5

Abstract

While CMOS technology is currently reaching its limits in power consumption and circuit density, a challenger is emerging from the analogy between biology and silicon. Hardware-based neural networks may drive a new generation of bio-inspired computers by the urge of a hardware solution for real-time applications. This paper redesigns a previous proposed electronic neuron (e-Neuron) in a higher firing rate to reduce the silicon area and highlight a better energy efficiency trade-off. Besides, an innovative schematic is proposed to state an e-Neuron library based on Izhikevichs model of neural firing patterns. Both e-Neuron circuits are designed using 55 nm technology node. Physical design of transistors in weak inversion are discussed to a minimal leakage. Neural firing pattern behaviors are validated by post-layout simulations, demonstrating the spike frequency adaptation and the rebound spikes due to post-inhibitory effect in LTS e-Neuron. Presented results suggest that the time to rebound spikes is dependent of the excitation current amplitude. Both e-Neurons have presented a fF/spike energy efficiency and a smaller silicon area in comparison to Izhikevichs library propositions in the literature.

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采用55-nm节点的高效fJ/spike LTS e-Neuron

当CMOS技术目前在功耗和电路密度方面达到极限时，一个挑战者正在从生物学和硅之间的类比中出现。基于硬件的神经网络可能会在实时应用的硬件解决方案的推动下驱动新一代的生物启发计算机。本文以更高的放电速率重新设计了先前提出的电子神经元(e-Neuron)，以减少硅面积并突出更好的能源效率权衡。此外，提出了一种基于Izhikevichs神经放电模式模型的e-Neuron库的创新方案。两种e-Neuron电路均采用55纳米技术设计。讨论了弱反转时晶体管的物理设计，使漏损最小。通过布局后模拟验证了LTS e-Neuron的放电模式行为，证明了LTS e-Neuron的脉冲频率适应和由于后抑制效应而产生的反弹峰值。研究结果表明，回弹尖峰的时间与励磁电流幅值有关。与文献中的Izhikevichs库命题相比，这两种e- neuron都具有fF/spike能量效率和更小的硅面积。

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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2019 32nd Symposium on Integrated Circuits and Systems Design (SBCCI)

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