神经形态工程学
MNIST数据库
计算机科学
尖峰神经网络
香料
人工神经网络
计算机体系结构
计算机工程
人工智能
电子工程
工程类
作者
Reon Oshio,Takuya Sugahara,Atsushi Sawada,Mutsumi Kimura,Renyuan Zhang,Yasuhiko Nakashima
出处
期刊:IEEE Micro
[Institute of Electrical and Electronics Engineers]
日期:2023-06-19
卷期号:44 (1): 8-16
被引量:5
标识
DOI:10.1109/mm.2023.3285529
摘要
Spiking neural networks (SNNs) enable the execution of deep learning-compatible tasks and approximation algorithms with low latency and low power consumption by operating on a neuromorphic system. Adopting analog in-memory computing (AiMC) in a neuromorphic system can build a system that has an advantage in memory density over a pure digital implementation. However, sensing the AiMC output with simple circuitry inevitably leads to unintended nonlinearities. In this study, we design a neuromorphic circuit using memcapacitive AiMC synapses with ultra-low power. We combine circuit nonlinearity-aware training (CNAT) with network compression techniques to prevent the SNN from losing accuracy caused by the neuron circuit’s nonlinearity and the synapse’s low resolution. The training runs on a machine learning framework and does not need to incorporate computationally intensive SPICE simulations. As simulated, our circuit performs MNIST classifications with almost no loss from ideal accuracy (97.64%) and consumes 15.7 nJ per inference.
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