Working Memory in a Recurrent Spiking Neural Networks With Heterogeneous Synaptic Delays
TLDR
Recurrent spiking neural networks with heterogeneous synaptic delays enable perfect working memory of temporal spike patterns.
Key contributions
- Introduces recurrent SNN with 41 heterogeneous synaptic delays per connection.
- Trains weight tensor end-to-end using surrogate-gradient backpropagation through time.
- Stores and recalls 16 arbitrary spike patterns with perfect mean F1 score on benchmark.
- Demonstrates recall propagates forward from initial clamped window in time.
Why it matters
This work shows heterogeneous synaptic delays enable precise temporal working memory in spiking networks. It advances energy-efficient neuromorphic computing by improving memory capacity and temporal pattern recall.
Original Abstract
Working memory -- the ability to store and recall precise temporal patterns of neural activity -- remains an open challenge for spiking neural networks (SNNs). We propose a recurrent SNN of $N$ neurons in which each synapse is equipped with $D = 41$ delays, modelled as a weight tensor $\mathbf{W} \in \mathbb{R}^{N \times N \times D}$ and trained end-to-end with surrogate-gradient backpropagation through time. The network stores $M$ arbitrary target spike patterns by representing each as a sequential chain of overlapping Spiking Motifs: contiguous windows of length $D$ that uniquely predict spikes at the next time step. On a synthetic benchmark of $M=16$ patterns ($N=512$ neurons, $T=1000$ steps), training achieves a mean F1 score of $1.0$, with recall emerging first near the clamped initialisation window and propagating forward in time. This result demonstrates that heterogeneous delays provide an efficient substrate for working memory in SNNs, enabling energy-efficient neuromorphic edge deployment.
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