Fast learning without synaptic plasticity in spiking neural networks

A. Subramoney, G. Bellec, F. Scherr, R. Legenstein, and W. Maass

Abstract:

Spiking neural networks are of high current interest, both from the perspective of modelling neural networks of the brain and for porting their fast learning capability and energy efficiency into neuromorphic hardware. But so far we have not been able to reproduce fast learning capabilities of the brain in spiking neural networks. Biological data suggest that a synergy of synaptic plasticity on a slow time scale with network dynamics on a faster time scale is responsible for fast learning capabilities of the brain. We show here that a suitable orchestration of this synergy between synaptic plasticity and network dynamics does in fact reproduce fast learning capabilities of generic recurrent networks of spiking neurons. This points to the important role of recurrent connections in spiking networks, since these are necessary for enabling salient network dynamics. We show more specifically that the proposed synergy enables synaptic weights to encode more general information such as priors and task structures, since moment-to-moment processing of new information can be delegated to the network dynamics.



Reference: A. Subramoney, G. Bellec, F. Scherr, R. Legenstein, and W. Maass. Fast learning without synaptic plasticity in spiking neural networks. Scientific Reports, 14(1):8557, 2024. Published on April 12, 2024.