A data-driven framework for neural field modeling
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Date
2011-02
Journal Title
Journal ISSN
Volume Title
Publisher
Elsevier Ltd.
Abstract
This paper presents a framework for creating neural field models from electrophysiological data. The Wilson and Cowan or Amari style neural field equations are used to form a parametric model, where the parameters
are estimated from data. To illustrate the estimation framework, data is generated using the neural field equations incorporating modeled sensors enabling a comparison between the estimated and true parameters.
To facilitate state and parameter estimation, we introduce a method to reduce the continuum neural field model using a basis function decomposition to form a finite-dimensional state-space model. Spatial frequency
analysis methods are introduced that systematically specify the basis function configuration required to capture the dominant characteristics of the neural field. The estimation procedure consists of a two-stage iterative algorithm incorporating the unscented Rauch–Tung–Striebel smoother for state estimation and a least squares algorithm for parameter estimation. The results show that it is theoretically possible to reconstruct the neural field and estimate intracortical connectivity structure and synaptic dynamics with the proposed framework.
Description
Keywords
Neural field model, Nonlinear estimation, Intracortical connectivity, Nonlinear dynamics
Citation
Freestone, D. R., P. Aram, M. Dewar, K. Scerri, D. B. Grayden, and V. Kadirkamanathan. 2011. A data-driven framework for neural field modeling. Neuroimage. 56(3): 1043-58