AI Article Synopsis
- Researchers have developed hardware-based spiking neural networks (SNNs) to replicate how biological neurons work, but traditional neuron circuits are often large and consume a lot of power.
- A new device called the split-gate floating-body positive feedback (PF) device is introduced, which greatly reduces energy consumption to about 0.25 pJ/spike—approximately 100 times less than conventional neuron circuits.
- This PF device effectively mimics biological neuron functions, taking up 17 times less space and demonstrating successful operation in simulations for tasks like unsupervised pattern learning and recognition.
Article Abstract
Hardware-based spiking neural networks (SNNs) to mimic biological neurons have been reported. However, conventional neuron circuits in SNNs have a large area and high power consumption. In this work, a split-gate floating-body positive feedback (PF) device with a charge trapping capability is proposed as a new neuron device that imitates the integrate-and-fire function. Because of the PF characteristic, the subthreshold swing () of the device is less than 0.04 mV/dec. The super-steep of the device leads to a low energy consumption of ∼0.25 pJ/spike for a neuron circuit (PF neuron) with the PF device, which is ∼100 times smaller than that of a conventional neuron circuit. The charge storage properties of the device mimic the integrate function of biological neurons without a large membrane capacitor, reducing the PF neuron area by about 17 times compared to that of a conventional neuron. We demonstrate the successful operation of a dense multiple PF neuron system with reset and lateral inhibition using a common self-controller in a neuron layer through simulation. With the multiple PF neuron system and the synapse array, on-line unsupervised pattern learning and recognition are successfully performed to demonstrate the feasibility of our PF device in a neural network.
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|---|---|
| http://www.ncbi.nlm.nih.gov/pmc/articles/PMC6189404 | PMC |
| http://dx.doi.org/10.3389/fnins.2018.00704 | DOI Listing |
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