English

Memory-Free and Parallel Computation for Quantized Spiking Neural Networks

Neural and Evolutionary Computing 2025-03-04 v1 Computer Vision and Pattern Recognition

Abstract

Quantized Spiking Neural Networks (QSNNs) offer superior energy efficiency and are well-suited for deployment on resource-limited edge devices. However, limited bit-width weight and membrane potential result in a notable performance decline. In this study, we first identify a new underlying cause for this decline: the loss of historical information due to the quantized membrane potential. To tackle this issue, we introduce a memory-free quantization method that captures all historical information without directly storing membrane potentials, resulting in better performance with less memory requirements. To further improve the computational efficiency, we propose a parallel training and asynchronous inference framework that greatly increases training speed and energy efficiency. We combine the proposed memory-free quantization and parallel computation methods to develop a high-performance and efficient QSNN, named MFP-QSNN. Extensive experiments show that our MFP-QSNN achieves state-of-the-art performance on various static and neuromorphic image datasets, requiring less memory and faster training speeds. The efficiency and efficacy of the MFP-QSNN highlight its potential for energy-efficient neuromorphic computing.

Keywords

Cite

@article{arxiv.2503.00040,
  title  = {Memory-Free and Parallel Computation for Quantized Spiking Neural Networks},
  author = {Dehao Zhang and Shuai Wang and Yichen Xiao and Wenjie Wei and Yimeng Shan and Malu Zhang and Yang Yang},
  journal= {arXiv preprint arXiv:2503.00040},
  year   = {2025}
}
R2 v1 2026-06-28T22:02:21.841Z