Computer Vision - ECCV 2024,
Oktober 2024
Spiking neural networks (SNNs) present a promising com- puting paradigm for neuromorphic processing of event-based sensor data. The resonate-and-fire (RF) neuron, in particular, appeals through its biological plausibility, complex dynamics, yet computational simplicity. Despite theoretically predicted benefits, challenges in parameter initial- ization and efficient learning inhibited the implementation of RF net- works, constraining their use to a single layer. In this paper, we address these shortcomings by deriving the RF neuron as a structured state space model (SSM) from the HiPPO framework. We introduce S5-RF, a new SSM layer comprised of RF neurons based on the S5 model, that fea- tures a generic initialization scheme and fast training within a deep ar- chitecture. S5-RF scales for the first time a RF network to a deep SNN with up to four layers and achieves with 78.8% a new state-of-the-art result for recurrent SNNs on the Spiking Speech Commands dataset in under three hours of training time. Moreover, compared to the reference SNNs that solve our benchmarking tasks, it achieves similar performance with much fewer spiking operations. Our code is publicly available at https://github.com/ThomasEHuber/s5-rf.
Stichworte: Spiking Neural Networks · Resonate-and-Fire Neuron · State Space Models · Bio-Inspired Computational Methods