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Neuronal Circuit Policies

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abstract

We propose an effective way to create interpretable control agents, by re-purposing the function of a biological neural circuit model, to govern simulated and real world reinforcement learning (RL) test-beds. We model the tap-withdrawal (TW) neural circuit of the nematode, C. elegans, a circuit responsible for the worm's reflexive response to external mechanical touch stimulations, and learn its synaptic and neuronal parameters as a policy for controlling basic RL tasks. We also autonomously park a real rover robot on a pre-defined trajectory, by deploying such neuronal circuit policies learned in a simulated environment. For reconfiguration of the purpose of the TW neural circuit, we adopt a search-based RL algorithm. We show that our neuronal policies perform as good as deep neural network policies with the advantage of realizing interpretable dynamics at the cell level.

fields

cs.LG 1

years

2026 1

verdicts

UNVERDICTED 1

representative citing papers

Neuronal Stochastic Attention Circuit (NSAC) for Probabilistic Representation Learning

cs.LG · 2026-05-25 · unverdicted · novelty 5.0

NSAC reformulates attention logit computation as the solution of an Ornstein-Uhlenbeck SDE with input-dependent nonlinear gates from NCPs to induce Gaussian distributions over logits and logistic-normal distributions over attention weights for joint aleatoric and epistemic uncertainty quantification

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  • Neuronal Stochastic Attention Circuit (NSAC) for Probabilistic Representation Learning cs.LG · 2026-05-25 · unverdicted · none · ref 3 · internal anchor

    NSAC reformulates attention logit computation as the solution of an Ornstein-Uhlenbeck SDE with input-dependent nonlinear gates from NCPs to induce Gaussian distributions over logits and logistic-normal distributions over attention weights for joint aleatoric and epistemic uncertainty quantification