Low-Power and High-Density Neuron Device for Simultaneous Processing of Excitatory and Inhibitory Signals in Neuromorphic Systems

Sung Yun Woo, Dongseok Kwon, Nagyong Choi, Won Mook Kang, Young Tak Seo, Min Kyu Park, Jong Ho Bae, Byung Gook Park, Jong Ho Lee

Research output: Contribution to journalArticlepeer-review

13 Scopus citations

Abstract

A positive-feedback (PF) neuron device capable of threshold tuning and simultaneously processing excitatory ( G+ ) and inhibitory ( G- ) signals is experimentally demonstrated to replace conventional neuron circuits, for the first time. Thanks to the PF operation, the PF neuron device with steep switching characteristics can implement integrate-and-fire (IF) function of neurons with low-energy consumption. The structure of the PF neuron device efficiently merges a gated PNPN diode and a single MOSFET. Integrate-and-fire (IF) operation with steep subthreshold swing (SS < 1 mV/dec) is experimentally implemented by carriers accumulated in an n floating body of the PF neuron device. The carriers accumulated in the n floating body are discharged by an inhibitory signal applied to the merged FET. Moreover, the threshold voltage ( Vth ) of the proposed PF neuron is controlled by using a charge storage layer. The low-energy consuming PF neuron circuit (0.62 pJ/spike) consists of one PF device and only five MOSFETs for the IF and reset operation. In a high-level system simulation, a deep-spiking neural network (D-SNN) based on PF neurons with four hidden layers (1024 neurons in each layer) shows high-accuracy (98.55%) during a MNIST classification task. The PF neuron device provides a viable solution for high-density and low-energy neuromorphic systems.

Original languageEnglish
Article number9249234
Pages (from-to)202639-202647
Number of pages9
JournalIEEE Access
Volume8
DOIs
StatePublished - 2020

Keywords

  • hardware-based neural networks
  • Neuron device
  • positive-feedback (PF) device
  • semiconductor device reliability
  • silicon-on-insulator (SOI) technology

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