K. I. Beverley scite author profile

An orientational difference of only 0.3-0.5 deg can be discriminated between two gratings or two lines, although psychophysical channels and cortical cells both have comparatively broad orientation bandwidths of 10-25 deg. One proposed explanation for the fineness of orientation discrimination is that, while detection is determined by the most excited orientation-tuned neural elements, superthreshold orientation discrimination is determined by difference signals between these elements [Westheimer et al., J. Opt. Soc. Am. 66, 332 (1976)]. This implies that, if stimulus orientation is changed slightly, the most important elements for discriminating this change will be those whose relative activity changes most, even though the excitation of these elements may be comparatively weak. In accord with this prediction, we found that adapting to a high-contrast grating degraded discrimination for test gratings inclined at about 10-20 deg to the adapting grating while having little effect on the detection of these inclined gratings. For test gratings parallel to the adapting grating, discrimination was improved, but detection was degraded. Either an opponent-process or a line-element model can account for these effects of adaptation. An opponent model can also explain our findings that subjects do not confound orientation change with contrast change and that suprathreshold orientation discrimination is almost independent of contrast, varying by only +/- 10% from about 3 to about 25 times contrast threshold. A discrimination model must incorporate reliable storage of spatial frequency, because discrimination was not affected by increasing the interval between grating presentations from 1 to 10 sec.(ABSTRACT TRUNCATED AT 250 WORDS)

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Looming detectors in the human visual pathway

Regan

1978

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How Do We Avoid Confounding the Direction We Are Looking and the Direction We Are Moving?

Regan

Beverley

1982

Science

205

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Contrary to a previous assumption, the center of the expanding pattern of visual flow is not generally useful as an aid in judging the direction of self motion since its direction depends on the direction of gaze. For some visual environments, however, the point of maximum rate of change of magnification in the retinal image coincides with the direction of self motion, independently of the direction of gaze. This visual indicator could be used to judge the direction of self motion.

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Binocular and monocular stimuli for motion in depth: Changing-disparity and changing-size feed the same motion-in-depth stage

1979

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The Visual Perception of Motion in Depth

Regan¹,

Beverley²,

Cynader³

1979

Sci Am

141

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K. I. Beverley

Postadaptation orientation discrimination

Looming detectors in the human visual pathway

How Do We Avoid Confounding the Direction We Are Looking and the Direction We Are Moving?

Binocular and monocular stimuli for motion in depth: Changing-disparity and changing-size feed the same motion-in-depth stage

The Visual Perception of Motion in Depth

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