Coarse-to-fine information integration in human vision

Coarse-to-fine theories of vision propose that the coarse information carried by the low spatial frequencies (LSF) of visual input guides the integration of finer, high spatial frequency (HSF) detail. Whether and how LSF modulates HSF processing in naturalistic broad-band stimuli is still unclear. H...

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Veröffentlicht in:NeuroImage (Orlando, Fla.) Fla.), 2019-02, Vol.186, p.103-112
Hauptverfasser: Petras, Kirsten, ten Oever, Sanne, Jacobs, Christianne, Goffaux, Valerie
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Sprache:eng
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Zusammenfassung:Coarse-to-fine theories of vision propose that the coarse information carried by the low spatial frequencies (LSF) of visual input guides the integration of finer, high spatial frequency (HSF) detail. Whether and how LSF modulates HSF processing in naturalistic broad-band stimuli is still unclear. Here we used multivariate decoding of EEG signals to separate the respective contribution of LSF and HSF to the neural response evoked by broad-band images. Participants viewed images of human faces, monkey faces and phase-scrambled versions that were either broad-band or filtered to contain LSF or HSF. We trained classifiers on EEG scalp-patterns evoked by filtered scrambled stimuli and evaluated the derived models on broad-band scrambled and intact trials. We found reduced HSF contribution when LSF was informative towards image content, indicating that coarse information does guide the processing of fine detail, in line with coarse-to-fine theories. We discuss the potential cortical mechanisms underlying such coarse-to-fine feedback. [Display omitted] •Spatial frequency integration proceeds in a coarse-to-fine manner.•Low spatial frequency information reduces high spatial frequency processing.•EEG topographies differ between low and high spatial frequency trials.•Classifier generalization reveals spatial frequency dominance in broadband vision.
ISSN:1053-8119
1095-9572
DOI:10.1016/j.neuroimage.2018.10.086