 A state space approach for piecewise-linear recurrent neural networks for identifying computational dynamics from neural measurementsDaniel Durstewitz PLOS Computational Biology, 2017, vol. 13, issue 6, 1-33 Abstract: The computational and cognitive properties of neural systems are often thought to be implemented in terms of their (stochastic) network dynamics. Hence, recovering the system dynamics from experimentally observed neuronal time series, like multiple single-unit recordings or neuroimaging data, is an important step toward understanding its computations. Ideally, one would not only seek a (lower-dimensional) state space representation of the dynamics, but would wish to have access to its statistical properties and their generative equations for in-depth analysis. Recurrent neural networks (RNNs) are a computationally powerful and dynamically universal formal framework which has been extensively studied from both the computational and the dynamical systems perspective. Here we develop a semi-analytical maximum-likelihood estimation scheme for piecewise-linear RNNs (PLRNNs) within the statistical framework of state space models, which accounts for noise in both the underlying latent dynamics and the observation process. The Expectation-Maximization algorithm is used to infer the latent state distribution, through a global Laplace approximation, and the PLRNN parameters iteratively. After validating the procedure on toy examples, and using inference through particle filters for comparison, the approach is applied to multiple single-unit recordings from the rodent anterior cingulate cortex (ACC) obtained during performance of a classical working memory task, delayed alternation. Models estimated from kernel-smoothed spike time data were able to capture the essential computational dynamics underlying task performance, including stimulus-selective delay activity. The estimated models were rarely multi-stable, however, but rather were tuned to exhibit slow dynamics in the vicinity of a bifurcation point. In summary, the present work advances a semi-analytical (thus reasonably fast) maximum-likelihood estimation framework for PLRNNs that may enable to recover relevant aspects of the nonlinear dynamics underlying observed neuronal time series, and directly link these to computational properties.Author summary: Neuronal dynamics mediate between the physiological and anatomical properties of a neural system and the computations it performs, in fact may be seen as the ‘computational language’ of the brain. It is therefore of great interest to recover from experimentally recorded time series, like multiple single-unit or neuroimaging data, the underlying stochastic network dynamics and, ideally, even equations governing their statistical evolution. This is not at all a trivial enterprise, however, since neural systems are very high-dimensional, come with considerable levels of intrinsic (process) noise, are usually only partially observable, and these observations may be further corrupted by noise from measurement and preprocessing steps. The present article embeds piecewise-linear recurrent neural networks (PLRNNs) within a state space approach, a statistical estimation framework that deals with both process and observation noise. PLRNNs are computationally and dynamically powerful nonlinear systems. Their statistically principled estimation from multivariate neuronal time series thus may provide access to some essential features of the neuronal dynamics, like attractor states, generative equations, and their computational implications. The approach is exemplified on multiple single-unit recordings from the rat prefrontal cortex during working memory. Date: 2017 Downloads: (external link) Related works: Export reference: BibTeX RIS (EndNote, ProCite, RefMan) HTML/Text Persistent link: https://EconPapers.repec.org/RePEc:plo:pcbi00:1005542 DOI: 10.1371/journal.pcbi.1005542 Access Statistics for this article More articles in PLOS Computational Biology from Public Library of Science |
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