English

Distributed Representations Enable Robust Multi-Timescale Symbolic Computation in Neuromorphic Hardware

Neural and Evolutionary Computing 2025-01-14 v3 Artificial Intelligence

Abstract

Programming recurrent spiking neural networks (RSNNs) to robustly perform multi-timescale computation remains a difficult challenge. To address this, we describe a single-shot weight learning scheme to embed robust multi-timescale dynamics into attractor-based RSNNs, by exploiting the properties of high-dimensional distributed representations. We embed finite state machines into the RSNN dynamics by superimposing a symmetric autoassociative weight matrix and asymmetric transition terms, which are each formed by the vector binding of an input and heteroassociative outer-products between states. Our approach is validated through simulations with highly nonideal weights; an experimental closed-loop memristive hardware setup; and on Loihi 2, where it scales seamlessly to large state machines. This work introduces a scalable approach to embed robust symbolic computation through recurrent dynamics into neuromorphic hardware, without requiring parameter fine-tuning or significant platform-specific optimisation. Moreover, it demonstrates that distributed symbolic representations serve as a highly capable representation-invariant language for cognitive algorithms in neuromorphic hardware.

Keywords

Cite

@article{arxiv.2405.01305,
  title  = {Distributed Representations Enable Robust Multi-Timescale Symbolic Computation in Neuromorphic Hardware},
  author = {Madison Cotteret and Hugh Greatorex and Alpha Renner and Junren Chen and Emre Neftci and Huaqiang Wu and Giacomo Indiveri and Martin Ziegler and Elisabetta Chicca},
  journal= {arXiv preprint arXiv:2405.01305},
  year   = {2025}
}

Comments

19 pages, 7 figures. Supplementary material: 13 pages, 8 figures. Accepted for publication in Neuromorphic Computing and Engineering

R2 v1 2026-06-28T16:14:04.072Z