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Spatial Cognition: a Wave Hypothesis (2405.10112v1)

Published 16 May 2024 in q-bio.NC and q-bio.PE

Abstract: Animals build Bayesian 3D models of their surroundings, to control their movements. There is strong selection pressure to make these models as precise as possible, given their sense data. A previous paper has described how a precise 3D model of space can be built by object tracking. This only works if 3D locations are stored with high spatial precision. Neural models of 3D spatial memory have large random errors; too large to support the tracking model. An alternative is described, in which neurons couple to a wave excitation in the brain, representing 3-D space. This can give high spatial precision, fast response, and other benefits. Three lines of evidence support the wave hypothesis: (1) it has better precision and speed than neural spatial memory, and is good enough to support object tracking; (2) the central body of the insect brain, whose form is highly conserved across all insect species, is well suited to hold a wave; and (3) the thalamus, whose round shape is conserved across all mammal species, is well suited to hold a wave. These lines of evidence strongly support the wave hypothesis.

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