Related papers: Q-SNNs: Quantized Spiking Neural Networks

Q-SNNs: Quantized Spiking Neural Networks

URL: http://arxiv.org/abs/2406.13672v1
Date: Wed, 19 Jun 2024 16:23:26 GMT
Title: Q-SNNs: Quantized Spiking Neural Networks
Authors: Wenjie Wei, Yu Liang, Ammar Belatreche, Yichen Xiao, Honglin Cao, Zhenbang Ren, Guoqing Wang, Malu Zhang, Yang Yang,
Abstract summary: Spiking Neural Networks (SNNs) leverage sparse spikes to represent information and process them in an event-driven manner. We introduce a lightweight and hardware-friendly Quantized SNN that applies quantization to both synaptic weights and membrane potentials. We present a new Weight-Spike Dual Regulation (WS-DR) method inspired by information entropy theory.
Score: 12.719590949933105
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Brain-inspired Spiking Neural Networks (SNNs) leverage sparse spikes to represent information and process them in an asynchronous event-driven manner, offering an energy-efficient paradigm for the next generation of machine intelligence. However, the current focus within the SNN community prioritizes accuracy optimization through the development of large-scale models, limiting their viability in resource-constrained and low-power edge devices. To address this challenge, we introduce a lightweight and hardware-friendly Quantized SNN (Q-SNN) that applies quantization to both synaptic weights and membrane potentials. By significantly compressing these two key elements, the proposed Q-SNNs substantially reduce both memory usage and computational complexity. Moreover, to prevent the performance degradation caused by this compression, we present a new Weight-Spike Dual Regulation (WS-DR) method inspired by information entropy theory. Experimental evaluations on various datasets, including static and neuromorphic, demonstrate that our Q-SNNs outperform existing methods in terms of both model size and accuracy. These state-of-the-art results in efficiency and efficacy suggest that the proposed method can significantly improve edge intelligent computing.

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