Open AccessThe Discrete and Continuous Brain: From Decisions to Movement—And Back Again
Author(s) -
Thomas Parr,
Karl Friston
Publication year - 2018
Publication title -
neural computation
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.235
H-Index - 169
eISSN - 1530-888X
pISSN - 0899-7667
DOI - 10.1162/neco_a_01102
Subject(s) - superior colliculus , inference , focus (optics) , computer science , computation , movement (music) , creatures , process (computing) , artificial intelligence , action selection , action (physics) , cognitive science , psychology , human–computer interaction , neuroscience , algorithm , programming language , physics , biology , perception , paleontology , quantum mechanics , natural (archaeology) , optics , acoustics
To act upon the world, creatures must change continuous variables such as muscle length or chemical concentration. In contrast, decision making is an inherently discrete process, involving the selection among alternative courses of action. In this article, we consider the interface between the discrete and continuous processes that translate our decisions into movement in a Newtonian world-and how movement informs our decisions. We do so by appealing to active inference, with a special focus on the oculomotor system. Within this exemplar system, we argue that the superior colliculus is well placed to act as a discrete-continuous interface. Interestingly, when the neuronal computations within the superior colliculus are formulated in terms of active inference, we find that many aspects of its neuroanatomy emerge from the computations it must perform in this role.
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