A gradient flow formulation for the stochastic Amari neural field model

Christian Kuehn; Jonas M. Tölle

doi:10.1007/s00285-019-01393-w

A gradient flow formulation for the stochastic Amari neural field model

Christian Kuehn
, Jonas M. Tölle

Chair of Multiscale and Stochastic Dynamics

University Hospital Augsburg

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

We study stochastic Amari-type neural field equations, which are mean-field models for neural activity in the cortex. We prove that under certain assumptions on the coupling kernel, the neural field model can be viewed as a gradient flow in a nonlocal Hilbert space. This makes all gradient flow methods available for the analysis, which could previously not be used, as it was not known, whether a rigorous gradient flow formulation exists. We show that the equation is well-posed in the nonlocal Hilbert space in the sense that solutions starting in this space also remain in it for all times and space-time regularity results hold for the case of spatially correlated noise. Uniqueness of invariant measures, ergodic properties for the associated Feller semigroups, and several examples of kernels are also discussed.

Original language	English
Pages (from-to)	1227-1252
Number of pages	26
Journal	Journal of Mathematical Biology
Volume	79
Issue number	4
DOIs	https://doi.org/10.1007/s00285-019-01393-w
State	Published - 1 Sep 2019

Keywords

Gradient flow in nonlocal Hilbert space
Nonnegative kernel
Space-time regularity of solutions
Spatially correlated additive noise
Stochastic Amari neural field equation
Unique invariant measure of the ergodic Feller semigroup

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10.1007/s00285-019-01393-w

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title = "A gradient flow formulation for the stochastic Amari neural field model",

abstract = "We study stochastic Amari-type neural field equations, which are mean-field models for neural activity in the cortex. We prove that under certain assumptions on the coupling kernel, the neural field model can be viewed as a gradient flow in a nonlocal Hilbert space. This makes all gradient flow methods available for the analysis, which could previously not be used, as it was not known, whether a rigorous gradient flow formulation exists. We show that the equation is well-posed in the nonlocal Hilbert space in the sense that solutions starting in this space also remain in it for all times and space-time regularity results hold for the case of spatially correlated noise. Uniqueness of invariant measures, ergodic properties for the associated Feller semigroups, and several examples of kernels are also discussed.",

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AB - We study stochastic Amari-type neural field equations, which are mean-field models for neural activity in the cortex. We prove that under certain assumptions on the coupling kernel, the neural field model can be viewed as a gradient flow in a nonlocal Hilbert space. This makes all gradient flow methods available for the analysis, which could previously not be used, as it was not known, whether a rigorous gradient flow formulation exists. We show that the equation is well-posed in the nonlocal Hilbert space in the sense that solutions starting in this space also remain in it for all times and space-time regularity results hold for the case of spatially correlated noise. Uniqueness of invariant measures, ergodic properties for the associated Feller semigroups, and several examples of kernels are also discussed.

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KW - Space-time regularity of solutions

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A gradient flow formulation for the stochastic Amari neural field model

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