Abstract
The human visual system is capable of detecting a vernier misalignment with extraordinary accuracy. Since this remarkable precision in spatial localization is better than can be naively predicted by simple optical or anatomical considerations it has been termed a hyperacuity1. So far no single neurone model seems capable of accounting for hyperacuity2, and the retinal image might require reconstitution in a finer grained form in the visual cortex3. We report here an electrophysiological correlate of hyperacuity recorded from the human visual cortex. The amplitude of the visually evoked potentials (v.e.ps) elicited by the appearance of a vernier offset varied systematically with the magnitude of the offset. Extrapolation of the function relating v.e.p. amplitude and log offset to zero voltage resulted in an electrophysiological estimate of vernier acuity that was similar to the observer's psychophysical threshold.
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Levi, D., Manny, R., Klein, S. et al. Electrophysiological correlates of hyperacuity in the human visual cortex. Nature 306, 468–470 (1983). https://doi.org/10.1038/306468a0
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DOI: https://doi.org/10.1038/306468a0
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