Variations in crowding, saccadic precision, and spatial localization reveal the shared topology of spatial vision

Greenwood, John A.; Szinte, Martin; Sayim, Bilge; Cavanagh, Patrick

doi:10.1073/pnas.1615504114

Cited by 121 publications

(202 citation statements)

References 90 publications

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“…This also replicates the vertical meridian asymmetry in both human and non-human primates [5,24]. A more recent study carried out by Greenwood and his colleagues [25] found that crowding zones and saccadic error zones are on average larger along the vertical than horizontal meridian and that there are variations between observers, which is consistent with what we showed in the current study. Our study goes beyond previous ones by showing that the individual differences in acuity, perceived position, and perceived size are unique to the individual observer, are highly reliable, and are not due to a group level effect.…”

Section: Discussionsupporting

confidence: 93%

Idiosyncratic Perception: A Link Between Acuity, Perceived Position, and Apparent Size

Wang

Murai

Whitney³

2020

Preprint

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Perceiving the positions of objects is a prerequisite for most other visual and visuomotor functions, but human perception of object position varies from one individual to the next. The source of these individual differences in perceived position and their perceptual consequences are unknown. Here, we tested whether idiosyncratic biases in the underlying representation of visual space propagate across different levels of visual processing. In Experiment 1, using a position matching task, we found stable, observer-specific compressions and expansions within local regions throughout the visual field. We then measured Vernier acuity (Experiment 2) and perceived size of objects (Experiment 3) across the visual field and found that individualized spatial distortions were closely associated with variations in both visual acuity and apparent object size. Our results reveal idiosyncratic biases in perceived position and size, originating from a heterogeneous spatial resolution that carries across the visual hierarchy.Accurately registering the locations of objects is a critical visual function. Most other perceptual functions including pattern and object recognition, as well as visually guided behavior, hinge on first localizing object positions. Position perception is generally assumed to be dictated by retinotopic location, and that may explain a lot of the variance in perceived position. However, perceived position can be biased due to various external factors, such as overt attention [1], motion [2] and saccadic eye movements [3]. The impact of these factors can be significant, especially considering the spatial scale at which object recognition and visually guided action happen. A 0.5-degree shift in the location of a pedestrian or car crossing a freeway could result in a catastrophic collision. The scale at which perception and action needs to operate is often very fine, and many factors bias perceived position at a scale that is behaviorally relevant.In the absence of these external factors, perceived position is often assumed to be uniformly dictated by retinotopic position. However, a recent study challenges this belief and demonstrates that people mislocalize objects idiosyncratically and consistently even without apparent change in the environment [4]. The unique biases in object locations were shown to be stable across time when tested after weeks or months, indicating a stable perceptual fingerprint of object location.Why do people perceive idiosyncratically biased object locations in different parts of the visual field and what are the perceptual consequences of it? Here, we test the possibility that variations in spatial resolution across the visual field might cause the spatial distortions in perceived position. Many researchers have shown that visual acuity varies across the visual field [5][6][7]. Because many models of localization depend implicitly or explicitly on the underlying resolution and homogeneity of spatial coding [1,[8][9][10], it is conceivable that the inhomogeneity in visual acuity could...

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Section: Discussionsupporting

confidence: 93%

Idiosyncratic Perception: A Link Between Acuity, Perceived Position, and Apparent Size

Wang

Murai

Whitney³

2020

Preprint

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“…Figure 3C shows the critical 406 spacing estimates for all observers and the median for the group. Critical spacing estimates 407 19 span an almost-fourfold range, and such between-subjects variability has been reported 408 previously (Greenwood, Szinte, Sayim, & Cavanagh, 2017;Petrov & Meleshkevich, 2011). 409 To control for between-subjects crowding variability in the memory experiment, and 410 therefore control for cortical spacing variability across participants, we adjusted the spatial 411 range of memoranda in the memory experiment to be either 0.75 times ("crowded") or 1.5 412 times ("uncrowded") an observer's critical spacing.…”

supporting

confidence: 52%

Visual working memory is independent of the cortical spacing between memoranda

Harrison

Bays

2017

Preprint

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“…A link between the oculomotor control and form processing in peripheral vision has been suggested in previous psychophysical studies. By measuring the size of the crowding zone and the saccade-landing zone, Greenwood et al (2017) demonstrated that the saccadic precision and crowding covary across the visual fields. Harrison et al (2013) showed that eye movement preparation effectively reduces the critical spacing of the crowding zone.…”

Section: Orymentioning

confidence: 99%

Cortical reorganization of peripheral vision induced by simulated central vision loss

Chen

Shin²,

Millin

et al. 2019

J. Neurosci.

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When one's central vision is deprived, a spared part of the peripheral retina acts as a pseudofovea for fixation. The neural mechanisms underlying this compensatory adjustment remain unclear. Here we report cortical reorganization induced by simulated central vision loss. Human subjects of both sexes learned to place the target at an eccentric retinal locus outside their blocked visual field for objecttracking. Before and after training, we measured visual crowding-a bottleneck of object identification in peripheral vision, using psychophysics and fMRI. We found that training led to an axis-specific reduction of crowding. The change of the crowding effect was reflected in the change of BOLD signal, as a release of cortical suppression in multiple visual areas starting as early as V1. Our findings suggest that the adult visual system is capable of reshaping its oculomotor control and sensory coding to adapt to impoverished visual input.

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Variations in crowding, saccadic precision, and spatial localization reveal the shared topology of spatial vision

Cited by 121 publications

References 90 publications

Idiosyncratic Perception: A Link Between Acuity, Perceived Position, and Apparent Size

Idiosyncratic Perception: A Link Between Acuity, Perceived Position, and Apparent Size

Visual working memory is independent of the cortical spacing between memoranda

Cortical reorganization of peripheral vision induced by simulated central vision loss

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