Abstract

The segregation of neural processing into distinct streams has been interpreted by some as evidence in favour of a modular view of brain function. This implies a set of specialised ‘modules’, each of which performs a specific kind of computation in isolation of other brain systems, before sharing the result of this operation with other modules. In light of a modern understanding of stochastic non-equilibrium systems, like the brain, a simpler and more parsimonious explanation presents itself. Formulating the evolution of a non-equilibrium steady state system in terms of its density dynamics reveals that such systems appear on average to perform a gradient ascent on their steady state density. If this steady state implies a sufficiently sparse conditional independency structure, this endorses a mean-field dynamical formulation. This decomposes the density over all states in a system into the product of marginal probabilities for those states. This factorisation lends the system a modular appearance, in the sense that we can interpret the dynamics of each factor independently. However, the argument here is that it is factorisation, as opposed to modularisation, that gives rise to the functional anatomy of the brain or, indeed, any sentient system. In the following, we briefly overview mean-field theory and its applications to stochastic dynamical systems. We then unpack the consequences of this factorisation through simple numerical simulations and highlight the implications for neuronal message passing and the computational architecture of sentience.

Highlights

  • Attempts to understand neuroanatomical and psychological organisation have often appealed to the notion of a ‘module’ [1,2,3,4,5]

  • We appealed to mean-field theory—a branch of statistical physics that deals with factorisation of probabilistic systems

  • We illustrated, using a system described by an arbitrarily constructed Hamiltonian, that the density dynamics of a high-dimensional stochastic system may be decomposed into factorised densities of low dimensional components that communicate with one another via their mean-fields

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Summary

Introduction

Attempts to understand neuroanatomical and psychological organisation have often appealed to the notion of a ‘module’ [1,2,3,4,5]. We argue that the emergence of a modular architecture is more expressed in terms of factorisation This perspective arises from an approach developed in statistical physics called mean-field theory [7,8]. This solution does not involve complete independence of each factor. We suggest that accounts of cognitive function in terms of modular architectures rest upon an intuitive application of mean-field theory. Making this explicit provides a useful perspective on brain function and lets us exploit established tools from stochastic physics.

Mean-Field Theory
Non-Equilibrium Stochastic Dynamics
Factors and Modules
Neuronal Message Passing
Discussion
Conclusions

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