飞速视觉生理学和行为学证据表明,空间对空间的表征和处理使视觉系统能够快速高效地工作。

IF 2 4区 心理学 Q2 OPHTHALMOLOGY
Moshe Gur
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引用次数: 0

摘要

当我们观察世界时,我们的眼睛会在感兴趣的点之间快速移动。即使在盯住一个目标时,我们的眼睛也不会完全静止,而是会执行微小的定睛眼动(FEM)。尽管这种抖动一直存在,但视觉却并不模糊,这似乎推动了一种日益流行的理论,即否认视觉系统依赖于纯粹的空间处理,而倾向于由眼睛在图像上漂移产生的时空机制。据此,FEM 对良好的可视性并非有害,而是必不可少的。然而,空间-时间理论与生理数据不符,生理数据显示,所有信息都是由眼睛落在目标上时产生的短暂神经波动传递的,而且与我们对短暂显示物体的忠实感知也不符,在这段时间内,FEM 没有任何作用。要否定通过反应细胞的位置和性质进行图像表征的观点,转而支持时间码的另一个困难在于,在达到感知时,这种编码必须在某处以某种方式解码成平行的空间编码。因此,除了不可能在视网膜漂移过程中产生有意义的反应之外,空间-时间假说还要求用一个繁琐、延迟的空间-时间-空间过程取代高效的点对点平行传输。本文提出了一个新颖的生理学框架,即视觉系统快速处理信息的能力是由着陆囊视产生的短促而有力的神经波动所促成的。这些波动是正常感知的必要条件和充分条件,而不需要 FEMs 的贡献。这种机制使我们能够很好地感知短暂的刺激,并解释了为什么可见度不会因快速眼动而模糊,因为快速眼动不会产生有用的信息。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Seeing on the fly: Physiological and behavioral evidence show that space-to-space representation and processing enable fast and efficient performance by the visual system.

When we view the world, our eyes saccade quickly between points of interest. Even when fixating a target our eyes are not completely at rest but execute small fixational eye movements (FEMs). That vision is not blurred despite this ever-present jitter has seemingly motivated an increasingly popular theory denying the reliance of the visual system on pure spatial processing in favor of a space-to-time mechanism generated by the eye drifting across the image. Accordingly, FEMs are not detrimental but rather essential to good visibility. However, the space-to-time theory is incompatible with physiological data showing that all information is conveyed by the short neural volleys generated when the eyes land on a target, and with our faithful perception of briefly displayed objects, during which time FEMs have no effect. Another difficulty in rejecting the idea of image representation by the locations and nature of responding cells in favor of a timecode, is that somewhere, somehow, this code must be decoded into a parallel spatial one when reaching perception. Thus, in addition to the implausibility of generating meaningful responses during retinal drift, the space-to-time hypothesis calls for replacing efficient point-to-point parallel transmission with a cumbersome, delayed, space-to-time-to-space process. A novel physiological framework is presented here wherein the ability of the visual system to quickly process information is mediated by the short, powerful neural volleys generated by the landing saccades. These volleys are necessary and sufficient for normal perception without FEMs contribution. This mechanism enables our excellent perception of brief stimuli and explains that visibility is not blurred by FEMs because they do not generate useful information.

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来源期刊
Journal of Vision
Journal of Vision 医学-眼科学
CiteScore
2.90
自引率
5.60%
发文量
218
审稿时长
3-6 weeks
期刊介绍: Exploring all aspects of biological visual function, including spatial vision, perception, low vision, color vision and more, spanning the fields of neuroscience, psychology and psychophysics.
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