English

Biological learning in key-value memory networks

Neurons and Cognition 2021-10-28 v1 Neural and Evolutionary Computing

Abstract

In neuroscience, classical Hopfield networks are the standard biologically plausible model of long-term memory, relying on Hebbian plasticity for storage and attractor dynamics for recall. In contrast, memory-augmented neural networks in machine learning commonly use a key-value mechanism to store and read out memories in a single step. Such augmented networks achieve impressive feats of memory compared to traditional variants, yet their biological relevance is unclear. We propose an implementation of basic key-value memory that stores inputs using a combination of biologically plausible three-factor plasticity rules. The same rules are recovered when network parameters are meta-learned. Our network performs on par with classical Hopfield networks on autoassociative memory tasks and can be naturally extended to continual recall, heteroassociative memory, and sequence learning. Our results suggest a compelling alternative to the classical Hopfield network as a model of biological long-term memory.

Keywords

Cite

@article{arxiv.2110.13976,
  title  = {Biological learning in key-value memory networks},
  author = {Danil Tyulmankov and Ching Fang and Annapurna Vadaparty and Guangyu Robert Yang},
  journal= {arXiv preprint arXiv:2110.13976},
  year   = {2021}
}

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NeurIPS 2021

R2 v1 2026-06-24T07:12:46.376Z