A flexible framework for structural plasticity in GPU-accelerated sparse spiking neural networks

TL;DR

This paper introduces a GPU-accelerated framework for structural plasticity in sparse spiking neural networks, enabling efficient training and topographic map formation, with significant reductions in training time and maintained performance.

Contribution

The paper presents a novel flexible GPU framework for structural plasticity in sparse SNNs, supporting supervised and unsupervised learning, and demonstrating substantial training speedups.

Findings

Sparse classifiers reduce training time by up to 10x.

DEEP R rewiring maintains performance in sparse models.

Topographic maps formed faster than real-time simulations.

Abstract

The majority of research in both training Artificial Neural Networks (ANNs) and modeling learning in biological brains focuses on synaptic plasticity, where learning equates to changing the strength of existing connections. However, in biological brains, structural plasticity - where new connections are created and others removed - is also vital, not only for effective learning but also for recovery from damage and optimal resource usage. Inspired by structural plasticity, pruning is often used in machine learning to remove weak connections from trained models to reduce the computational requirements of inference. However, the machine learning frameworks typically used for backpropagation-based training of both ANNs and Spiking Neural Networks (SNNs) are optimized for dense connectivity, meaning that pruning does not help reduce the training costs of ever-larger models. The GeNN simulator already supports efficient GPU-accelerated simulation of sparse SNNs for computational neuroscience and machine learning. Here, we present a new flexible framework for implementing GPU-accelerated structural plasticity rules and demonstrate this first using the e-prop supervised learning rule and DEEP R to train efficient, sparse SNN classifiers and then, in an unsupervised learning context, to learn topographic maps. Compared to baseline dense models, our sparse classifiers reduce training time by up to 10x while the DEEP R rewiring enables them to perform as well as the original models. We demonstrate topographic map formation in faster-than-realtime simulations, provide insights into the connectivity evolution, and measure simulation speed versus network size. The proposed framework will enable further research into achieving and maintaining sparsity in network structure and neural communication, as well as exploring the computational benefits of sparsity in a range of neuromorphic applications.