使用模拟尖峰神经元的深度神经网络可行性

2022 35th SBC/SBMicro/IEEE/ACM Symposium on Integrated Circuits and Systems Design (SBCCI) Pub Date : 2022-08-22 DOI:10.1109/SBCCI55532.2022.9893216

Thomas Soupizet, Zalfa Jouni, João F. Sulzbach, A. Benlarbi-Delai, Pietro M. Ferreira

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引用次数: 3

摘要

基于人工智能(AI)的新型非冯-诺伊曼解决方案已经出现，例如模拟或数字领域的神经形态尖峰处理器。本文提出研究深度神经网络在超低功耗eNeuron技术上的可行性。强调了深度学习能力和能源效率方面的权衡。该研究表明，已发表的神经元和突触满足激励电流大于200pa和峰值频率高于150khz的线性拟合，其中能量效率是最佳的。因此，深度学习和能量效率对于研究的模拟尖峰神经元是相互排斥的。

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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Deep Neural Network Feasibility Using Analog Spiking Neurons

Novel non-Von-Neumann solutions based on artificial intelligence (AI) have surfaced such as the neuromorphic spiking processors in either analog or digital domain. This paper proposes to study the feasibility of deep neural networks on ultra-low-power eNeuron technology. The trade-offs in terms of deep learning capabilities and energy efficiency are highlighted. This study reveals that published eNeurons and synapses satisfy linear fittings for an excitation current greater than 200 pA and a spiking frequency higher than 150 kHz, where energy efficiency is optimal. Thus, deep learning and energy efficiency are mutually exclusive for studied analog spiking neurons.

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2022 35th SBC/SBMicro/IEEE/ACM Symposium on Integrated Circuits and Systems Design (SBCCI)

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