Abstract
Symmetry is a highly salient feature in the visual world, abundant in both man-made and natural objects. In particular, humans find reflectional symmetry most salient. Electrophysiological work on symmetry perception has identified a difference wave known as the Sustained Posterior Negativity (SPN) originating from extrastriate areas. Amplitude is more negative for symmetrical than random patterns, from around 200 msec after stimulus onset. For the first time, we report responses to patterns presented exclusively in one hemifield. Participants were presented with reflection or random dot patterns to the left and right of fixation (3.2°). They judged whether the patterns were light red or dark red in colour. In Experiment 1, the pair always included one symmetrical and one random pattern. In Experiments 2 and 3 we varied the information presented contralaterally. The SPN was generated separately in each hemisphere in response to what was presented in the contralateral visual hemifield (a lateralised SPN). We conclude that a symmetry-sensitive network of extrastriate areas can be activated independently in each cerebral hemisphere.
Highlights
Symmetry has a central role in the study of vision
We find a similar Sustained Posterior Negativity (SPN) wave when people are explicitly classifying the patterns as symmetrical or random, and when they are attending to an orthogonal visual dimension, like colour cortex 8 6 ( 2 0 1 7 ) 9 3 e1 0 8 (Makin, Rampone, & Bertamini, 2015) or the number of blocks (Makin, Rampone, Wright, Martinovic, & Bertamini, 2014)
The results showed that the SPN wave (Reflection < Random) could be generated within a single cerebral hemisphere, with the information being processed in the opposite hemisphere having no detectable effect on this lateralized neural response to symmetry
Summary
Symmetry has a central role in the study of vision. Symmetry is a non-accidental property of an image, linked to the presence of objects in the environment, and it can contribute to perceptual organization (Bertamini, 2010), to image segmentation (Machilsen, Pauwels, & Wagemans, 2009), and to the recovery of 3D structure (Pizlo & Stevenson, 1999). How the two hemispheres interact to process symmetry is a question that has been central to research in the topic since early work by Mach (1886/1959). We will review this background and introduce our experiments that directly compared responses to symmetry presented to the left or the right hemifield
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