Dynamics of Leaky Integrate‐and‐Fire Neurons Based on Oxyvanite Memristors for Spiking Neural Networks

Dynamics of Leaky Integrate‐and‐Fire Neurons Based on Oxyvanite Memristors for Spiking Neural Networks

Neuromorphic computing implemented with spiking neural networks (SNNs) based on volatile threshold switching is an energy‐efficient computing paradigm that may overcome future limitations of the von Neumann architecture. Herein, threshold switching in oxyvanite (V3O5) memristors and their applicatio...

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Bibliographic Details
Published in:Advanced intelligent systems Vol. 6; no. 11
Main Authors: Das, Sujan Kumar, Nandi, Sanjoy Kumar, Marquez, Camilo Verbel, Rúa, Armando, Uenuma, Mutsunori, Nath, Shimul Kanti, Zhang, Shuo, Lin, Chun‐Ho, Chu, Dewei, Ratcliff, Tom, Elliman, Robert Glen
Format: Journal Article
Language:English
Published: Weinheim John Wiley & Sons, Inc 01-11-2024
Wiley
Subjects:
Algorithms
cascading effects
Complex systems
Electrodes
Electron microscopes
image recognitions
leaky integrate‐and‐fire neurons
Memristors
Neural networks
Neuromorphic computing
Neurons
Parameters
Phase transitions
Pulse amplitude
Spiking
spiking neural networks
switching dynamics
Temperature
Temperature dependence
threshold switches
Transmission electron microscopy
V3O5
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Summary:Neuromorphic computing implemented with spiking neural networks (SNNs) based on volatile threshold switching is an energy‐efficient computing paradigm that may overcome future limitations of the von Neumann architecture. Herein, threshold switching in oxyvanite (V3O5) memristors and their application as a leaky integrate‐and‐fire (LIF) neuron are explored. The spiking response of individual neurons is examined as a function of circuit parameters, input pulse train, and temperature and reveals a pulse height‐dependent spike rate in which devices exhibit excitatory spiking behavior under low input voltages and protective inhibition spiking under high voltages. Resistively coupled LIF neurons are shown to exhibit additional neural functionalities (i.e., phasic, regular and adaptation, etc.) depending on the input voltage and circuit parameters. The behavior of both individual and coupled neurons is shown to be described by a physics‐based lumped element circuit model, which therefore provides a solid foundation for exploring more complex systems. Finally, the performance of a perceptron SNN employing these LIF neurons is assessed by simulating the classification of image recognition algorithm. These results advance the development of robust solid‐state neurons with low power consumption for neuromorphic computing. This study explores the dynamics of threshold switching in oxyvanite (V3O5) memristors for leaky integrate‐and‐fire neurons. Further, an example of interpretation on handwritten digits from the Modified National Institure of Standard and Technology database with a 28 × 28 array of coupled neurons feeding into a single hidden layer neural network for testing image recognition algorithms is demonstrated.
ISSN:2640-4567
2640-4567
DOI:10.1002/aisy.202400191