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Vector Symbolic Finite State Machines in Attractor Neural Networks

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arxiv 2212.01196 v2 pith:K5K2S2C2 submitted 2022-12-02 cs.NE

Vector Symbolic Finite State Machines in Attractor Neural Networks

classification cs.NE
keywords attractorstatenetworksnetworkvectorsarbitrarydistributedfinite
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Hopfield attractor networks are robust distributed models of human memory, but lack a general mechanism for effecting state-dependent attractor transitions in response to input. We propose construction rules such that an attractor network may implement an arbitrary finite state machine (FSM), where states and stimuli are represented by high-dimensional random vectors, and all state transitions are enacted by the attractor network's dynamics. Numerical simulations show the capacity of the model, in terms of the maximum size of implementable FSM, to be linear in the size of the attractor network for dense bipolar state vectors, and approximately quadratic for sparse binary state vectors. We show that the model is robust to imprecise and noisy weights, and so a prime candidate for implementation with high-density but unreliable devices. By endowing attractor networks with the ability to emulate arbitrary FSMs, we propose a plausible path by which FSMs could exist as a distributed computational primitive in biological neural networks.

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