Cyclopean flash-lag illusion

Dylan Nieman; Romi Nijhawan; Beena Khurana; Shinsuke Shimojo

doi:10.1016/j.visres.2006.06.003

Cyclopean flash-lag illusion

Dylan Nieman, Romi Nijhawan, Beena Khurana, Shinsuke Shimojo

Research output: Contribution to journal › Article › peer-review

10 Scopus citations

Abstract

Possible physiological mechanisms to explain the flash-lag effect, in which subjects perceive a flashed item that is co-localized with a moving item as trailing behind the moving item, have been found within the retina of lower species, and in the motor pathways of humans. Here, we demonstrate flash-lag employing "second-order" moving and flashed stimuli, defined solely by their binocular-disparity, to circumvent any possible "early" contributions to the effect. A significant flash-lag effect was measured with cyclopean stimuli composed entirely of correlated random dot patterns. When the disparity-defined moving stimulus was replaced with a luminance-defined one, potentially engaging retinal mechanisms, the magnitude of the measured effect showed no significant change. Thus, in primates, though retinal mechanisms may contribute, flash-lag must be explained through cortical processes.

Original language	English (US)
Pages (from-to)	3909-3914
Number of pages	6
Journal	Vision Research
Volume	46
Issue number	22
DOIs	https://doi.org/10.1016/j.visres.2006.06.003
State	Published - Oct 2006
Externally published	Yes

All Science Journal Classification (ASJC) codes

Ophthalmology
Sensory Systems

Keywords

Flash-lag
Second-order motion

Access to Document

10.1016/j.visres.2006.06.003

Cite this

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title = "Cyclopean flash-lag illusion",

abstract = "Possible physiological mechanisms to explain the flash-lag effect, in which subjects perceive a flashed item that is co-localized with a moving item as trailing behind the moving item, have been found within the retina of lower species, and in the motor pathways of humans. Here, we demonstrate flash-lag employing {"}second-order{"} moving and flashed stimuli, defined solely by their binocular-disparity, to circumvent any possible {"}early{"} contributions to the effect. A significant flash-lag effect was measured with cyclopean stimuli composed entirely of correlated random dot patterns. When the disparity-defined moving stimulus was replaced with a luminance-defined one, potentially engaging retinal mechanisms, the magnitude of the measured effect showed no significant change. Thus, in primates, though retinal mechanisms may contribute, flash-lag must be explained through cortical processes.",

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AU - Nijhawan, Romi

AU - Khurana, Beena

AU - Shimojo, Shinsuke

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AB - Possible physiological mechanisms to explain the flash-lag effect, in which subjects perceive a flashed item that is co-localized with a moving item as trailing behind the moving item, have been found within the retina of lower species, and in the motor pathways of humans. Here, we demonstrate flash-lag employing "second-order" moving and flashed stimuli, defined solely by their binocular-disparity, to circumvent any possible "early" contributions to the effect. A significant flash-lag effect was measured with cyclopean stimuli composed entirely of correlated random dot patterns. When the disparity-defined moving stimulus was replaced with a luminance-defined one, potentially engaging retinal mechanisms, the magnitude of the measured effect showed no significant change. Thus, in primates, though retinal mechanisms may contribute, flash-lag must be explained through cortical processes.

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Cyclopean flash-lag illusion

Abstract

All Science Journal Classification (ASJC) codes

Keywords

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