Optimizing gaze control in three dimensions

Douglas Tweed; Thomas Haslwanter; Michael Fetter

doi:10.1126/science.281.5381.1363

Optimizing gaze control in three dimensions

Douglas Tweed, Thomas Haslwanter, Michael Fetter

Research Center Linz

Publikation: Beitrag in Fachzeitschrift › Artikel › Begutachtung

74 Zitate (Scopus)

Abstract

Horizontal and vertical movements of the human eye bring new objects to the center of the visual field, but torsional movements rotate the visual world about its center. Ocular torsion stays near zero during head-fixed gaze shifts, and eye movements to visual targets are thought to be driven by purely horizontal and vertical commands. Here, analysis of eye-head gaze shifts revealed that gaze commands were three-dimensional, with a separate neural control system for torsion. Active torsion optimized gaze control as no two-dimensional system could have, stabilizing the retinal image as quickly as possible when it would otherwise have spun around the fixation point.

Originalsprache	Englisch
Seiten (von - bis)	1363-1366
Seitenumfang	4
Fachzeitschrift	Science
Jahrgang	281
Ausgabenummer	5381
DOIs	https://doi.org/10.1126/science.281.5381.1363
Publikationsstatus	Veröffentlicht - 28 Aug. 1998

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abstract = "Horizontal and vertical movements of the human eye bring new objects to the center of the visual field, but torsional movements rotate the visual world about its center. Ocular torsion stays near zero during head-fixed gaze shifts, and eye movements to visual targets are thought to be driven by purely horizontal and vertical commands. Here, analysis of eye-head gaze shifts revealed that gaze commands were three-dimensional, with a separate neural control system for torsion. Active torsion optimized gaze control as no two-dimensional system could have, stabilizing the retinal image as quickly as possible when it would otherwise have spun around the fixation point.",

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AB - Horizontal and vertical movements of the human eye bring new objects to the center of the visual field, but torsional movements rotate the visual world about its center. Ocular torsion stays near zero during head-fixed gaze shifts, and eye movements to visual targets are thought to be driven by purely horizontal and vertical commands. Here, analysis of eye-head gaze shifts revealed that gaze commands were three-dimensional, with a separate neural control system for torsion. Active torsion optimized gaze control as no two-dimensional system could have, stabilizing the retinal image as quickly as possible when it would otherwise have spun around the fixation point.

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KW - Feedback

KW - Fixation, Ocular/physiology

KW - Head Movements/physiology

KW - Humans

KW - Models, Biological

KW - Oculomotor Muscles/physiology

KW - Vision, Ocular/physiology

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Optimizing gaze control in three dimensions

Abstract

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