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April 8, 2026Open Access

Gauge-covariant stochastic neural fields: stability and finite-width effects

Key Points

The research aims to model stability and finite-width effects in deep neural systems using a gauge-covariant framework.
Developed a stochastic effective field theory.
Utilized classical commuting fields and a fictitious stochastic depth variable.
Applied the Martin–Siggia–Rose–Janssen–de Dominicis formalism for functional representation.
Constructed a two-replica linear-response model to determine the maximal Lyapunov exponent.
Finite-width multilayer perceptrons align with the mean-field instability threshold.
A linear stochastic effective sector predicts low-frequency spectral deformation.
Perturbative corrections due to finite-width effects were identified in dressed kernels.

Abstract

We develop a gauge-covariant stochastic effective field theory for stability and finite-width effects in deep neural systems. The model uses classical commuting fields: a complex matter field, a real Abelian connection field, and a fictitious stochastic depth variable. Using the Martin–Siggia–Rose–Janssen–de Dominicis formalism, we derive its functional representation and a two-replica linear-response construction defining the maximal Lyapunov exponent and the amplification factor for the edge of chaos. Finite-width effects appear as perturbative corrections to dressed kernels, and the marginality condition remains unchanged at the order considered for fixed kernel geometry. Numerically, finite-width multilayer perceptrons follow the mean-field instability threshold, and a linear stochastic effective sector reproduces the predicted low-frequency spectral deformation.

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Gauge-covariant stochastic neural fields: stability and finite-width effects

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Abstract

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