Self-consistent formulations for stochastic nonlinear neuronal dynamics
Jonas Stapmanns, Tobias K\"uhn, David Dahmen, Thomas Luu, Carsten, Honerkamp, Moritz Helias

TL;DR
This paper develops self-consistent, systematic methods using field theory and renormalization group techniques to analyze stochastic nonlinear neuronal models, capturing fluctuations and memory effects beyond mean-field approximations.
Contribution
It introduces a unified framework linking Onsager-Machlup and MSRDJ formalisms, and applies functional renormalization group methods with a new truncation scheme to stochastic neuronal dynamics.
Findings
Derived effective deterministic equations for the first moment.
Established a link between Onsager-Machlup and MSRDJ formalisms.
Presented a new truncation scheme for the fRG hierarchy.
Abstract
Neural dynamics is often investigated with tools from bifurcation theory. However, many neuron models are stochastic, mimicking fluctuations in the input from unknown parts of the brain or the spiking nature of signals. Noise changes the dynamics with respect to the deterministic model; in particular bifurcation theory cannot be applied. We formulate stochastic neuronal dynamics in the Martin-Siggia-Rose de Dominicis-Janssen (MSRDJ) formalism and present the fluctuation expansion of the effective action and the functional renormalization group (fRG) as two systematic ways to incorporate corrections to the mean dynamics and time-dependent statistics due to fluctuations in the presence of nonlinear neuronal gain. To formulate self-consistency equations, we derive a fundamental link between the effective action in the Onsager-Machlup(OM) formalism, which allows the study of phase…
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