English

SpikingSSMs: Learning Long Sequences with Sparse and Parallel Spiking State Space Models

Computation and Language 2024-12-25 v2 Machine Learning Neural and Evolutionary Computing

Abstract

Known as low energy consumption networks, spiking neural networks (SNNs) have gained a lot of attention within the past decades. While SNNs are increasing competitive with artificial neural networks (ANNs) for vision tasks, they are rarely used for long sequence tasks, despite their intrinsic temporal dynamics. In this work, we develop spiking state space models (SpikingSSMs) for long sequence learning by leveraging on the sequence learning abilities of state space models (SSMs). Inspired by dendritic neuron structure, we hierarchically integrate neuronal dynamics with the original SSM block, meanwhile realizing sparse synaptic computation. Furthermore, to solve the conflict of event-driven neuronal dynamics with parallel computing, we propose a light-weight surrogate dynamic network which accurately predicts the after-reset membrane potential and compatible to learnable thresholds, enabling orders of acceleration in training speed compared with conventional iterative methods. On the long range arena benchmark task, SpikingSSM achieves competitive performance to state-of-the-art SSMs meanwhile realizing on average 90\% of network sparsity. On language modeling, our network significantly surpasses existing spiking large language models (spikingLLMs) on the WikiText-103 dataset with only a third of the model size, demonstrating its potential as backbone architecture for low computation cost LLMs.

Keywords

Cite

@article{arxiv.2408.14909,
  title  = {SpikingSSMs: Learning Long Sequences with Sparse and Parallel Spiking State Space Models},
  author = {Shuaijie Shen and Chao Wang and Renzhuo Huang and Yan Zhong and Qinghai Guo and Zhichao Lu and Jianguo Zhang and Luziwei Leng},
  journal= {arXiv preprint arXiv:2408.14909},
  year   = {2024}
}
R2 v1 2026-06-28T18:25:05.725Z