Judging object motion during smooth pursuit eye movements: The role of optic flow

We tend to follow moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit, velocity judgements can be led astray by moving the background. Do we misjudge an object's velocity when the background moves because the ad...

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Published in	Vision research (Oxford) Vol. 31; no. 11; pp. 1893 - 1902
Main Author	Brenner, Eli
Format	Journal Article
Language	English
Published	Oxford Elsevier Ltd 1991 Elsevier Science
Subjects	Biological and medical sciences Eye movements Fundamental and applied biological sciences. Psychology Humans Motion perception Motion Perception - physiology Optic flow Perception Psychology. Psychoanalysis. Psychiatry Psychology. Psychophysiology Psychophysics Pursuit, Smooth - physiology Smooth pursuit Spatial vision Velocity Vision Smooth pursuit Optic flow Eye movements Psychophysics Velocity Spatial vision Motion perception Human Visual stimulus Stimulus movement Eye movement Vision
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ISSN	0042-6989 1878-5646
DOI	10.1016/0042-6989(91)90184-7

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Abstract	We tend to follow moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit, velocity judgements can be led astray by moving the background. Do we misjudge an object's velocity when the background moves because the additional shift of the background's image on the retina is interpreted as the result of additional motion of the observer rather than as motion of the background? In the present experiment, the traditional configuration of target and background was supplemented with a “floor of tiles” drawn in perspective directly under the “background”. The motion of this new simulated plane was used to specify whether the additional retinal shift represents actual motion in the background, rotation of the observer's eyes, or observer locomotion parallel to the target. Moving the background clearly influenced the perceived velocity of the target. However, “specifying” whether the observer or the background had moved did not affect the outcome. For observer locomotion parallel to the target, the change in target velocity that is predicted by the optic flow depends on the perceived distance of the target. Nevertheless, presenting the target at different distances (by presenting different images to the two eyes) did not affect the subjects' settings. The results show that our judgement of objects' velocities does not depend on an assessment of our own movements on the basis of a global analysis of the optic flow.
AbstractList	We tend to following moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit, velocity judgements can be led astray by moving the background. Do we misjudge an object's velocity when the background moves because the additional shift of the background's image on the retina is interpreted as the result of additional motion of the observer rather than as motion of the background? In the present experiment, the traditional configuration of target and background was supplemented with a "floor of tiles" drawn in perspective directly under the "background". The motion of this new simulated plane was used to specify whether the additional retinal shift represents actual motion in the background, rotation of the observer's eyes, or observer locomotion parallel to the target. Moving the background clearly influenced the perceived velocity of the target. However, "specifying" whether the observer or the background had moved did not affect the outcome. For observer locomotion parallel to the target, the change in target velocity that is predicted by the optic flow depends on the perceived distance of the target. Nevertheless, presenting the target at different distances (by presenting different images of the two eyes) did not affect the subjects' settings. The results show that our judgement of objects' velocities does not depend on an assessment of our own movements on the basis of a global analysis of the optic flow. We tend to following moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit, velocity judgements can be led astray by moving the background. Do we misjudge an object's velocity when the background moves because the additional shift of the background's image on the retina is interpreted as the result of additional motion of the observer rather than as motion of the background? In the present experiment, the traditional configuration of target and background was supplemented with a "floor of tiles" drawn in perspective directly under the "background". The motion of this new simulated plane was used to specify whether the additional retinal shift represents actual motion in the background, rotation of the observer's eyes, or observer locomotion parallel to the target. Moving the background clearly influenced the perceived velocity of the target. However, "specifying" whether the observer or the background had moved did not affect the outcome. For observer locomotion parallel to the target, the change in target velocity that is predicted by the optic flow depends on the perceived distance of the target. Nevertheless, presenting the target at different distances (by presenting different images of the two eyes) did not affect the subjects' settings. The results show that our judgement of objects' velocities does not depend on an assessment of our own movements on the basis of a global analysis of the optic flow.We tend to following moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit, velocity judgements can be led astray by moving the background. Do we misjudge an object's velocity when the background moves because the additional shift of the background's image on the retina is interpreted as the result of additional motion of the observer rather than as motion of the background? In the present experiment, the traditional configuration of target and background was supplemented with a "floor of tiles" drawn in perspective directly under the "background". The motion of this new simulated plane was used to specify whether the additional retinal shift represents actual motion in the background, rotation of the observer's eyes, or observer locomotion parallel to the target. Moving the background clearly influenced the perceived velocity of the target. However, "specifying" whether the observer or the background had moved did not affect the outcome. For observer locomotion parallel to the target, the change in target velocity that is predicted by the optic flow depends on the perceived distance of the target. Nevertheless, presenting the target at different distances (by presenting different images of the two eyes) did not affect the subjects' settings. The results show that our judgement of objects' velocities does not depend on an assessment of our own movements on the basis of a global analysis of the optic flow. We tend to follow moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit, velocity judgements can be led astray by moving the background. Do we misjudge an object's velocity when the background moves because the additional shift of the background's image on the retina is interpreted as the result of additional motion of the observer rather than as motion of the background? In the present experiment, the traditional configuration of target and background was supplemented with a “floor of tiles” drawn in perspective directly under the “background”. The motion of this new simulated plane was used to specify whether the additional retinal shift represents actual motion in the background, rotation of the observer's eyes, or observer locomotion parallel to the target. Moving the background clearly influenced the perceived velocity of the target. However, “specifying” whether the observer or the background had moved did not affect the outcome. For observer locomotion parallel to the target, the change in target velocity that is predicted by the optic flow depends on the perceived distance of the target. Nevertheless, presenting the target at different distances (by presenting different images to the two eyes) did not affect the subjects' settings. The results show that our judgement of objects' velocities does not depend on an assessment of our own movements on the basis of a global analysis of the optic flow.
Author	Brenner, Eli
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Cites_doi	10.1068/p020287 10.1038/348160a0 10.1037/0096-1523.14.4.582 10.3758/BF03206362 10.1038/scientificamerican0585-118 10.1068/p170005 10.1016/0166-4328(86)90076-8 10.1093/brain/111.6.1405 10.1068/p160017 10.3758/BF03203301 10.1016/0042-6989(81)90095-X 10.1007/BF00622503 10.1038/336162a0
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Keywords	Smooth pursuit Optic flow Eye movements Psychophysics Velocity Spatial vision Motion perception Human Visual stimulus Stimulus movement Eye movement Vision
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Snippet	We tend to follow moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit,... We tend to following moving objects with our eyes. To estimate their velocities, therefore, we must take account of our eye movements. During smooth pursuit,...
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SubjectTerms	Biological and medical sciences Eye movements Fundamental and applied biological sciences. Psychology Humans Motion perception Motion Perception - physiology Optic flow Perception Psychology. Psychoanalysis. Psychiatry Psychology. Psychophysiology Psychophysics Pursuit, Smooth - physiology Smooth pursuit Spatial vision Velocity Vision
Title	Judging object motion during smooth pursuit eye movements: The role of optic flow
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