End stopping in V1 is sensitive to contrast

Yazdanbakhsh, Arash; Livingstone, Margaret S.

doi:10.1038/nn1693

Cited by 40 publications

(31 citation statements)

References 44 publications

(13 reference statements)

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“…Our tolerance of multiple points of view in a single painting suggests that one characteristic of this alternative (psycho) physics is that depth cues are processed locally; that is, it is not necessary for the perspective cues to be consistent across the entire image. This idea is consistent with the plausibility at first glance of impossible figures, like Penrose's triangle, and with observations from psychophysics and neurophysiology that figure-ground segregation, depth ordering, and surface stratification are processed at early stages in the visual system, where receptive fields are small and processing is necessarily local [20][21][22][23][24][25][26][27].…”

Section: Nih-pa Author Manuscriptsupporting

confidence: 87%

Perspectives on science and art

Conway¹,

Livingstone²

2007

Current Opinion in Neurobiology

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Artists try to understand how we see, sometimes explicitly exploring rules of perspective or color, visual illusions, or iconography, and conversely, scientists who study vision sometimes address the perceptual questions and discoveries raised by the works of art, as we do here.The integration of visual art with the experimental study of vision has its roots in formal analysis of painting, but this approach has gone out of vogue in art-historical circles because it ignores the impact of cultural context on art appreciation. Advances in our understanding of how the brain works have resuscitated interest in linking art with vision science. Here we review some of these new links, with the caveat that we will not address visual aesthetics, but rather some nuts and bolts of making and looking at art, in an endeavor to enrich our understanding of art 'in much the same way as a knowledge of bones and muscles has for centuries enhanced the ability of artists to portray the human body' [1]. Some recent studies may even illuminate why cultural context is so important in visual art.When we look at the world, or at a work of art, our eyes, and our visual attention, are constantly and alternately moving and fixating [2]. Our fixations are not randomly distributed across a scene, but rather concentrate on key regions-to a first approximation, on the areas of high local contrast [3]. The visual machinery that directs the eyes where to look can have two impacts on art. On the one hand, artists have developed techniques to direct your gaze; on the other hand, the unconscious machinery directing the gaze of the artist may influence which parts of the scene the artist portrays or emphasizes. Leonards et al. [4] have argued that Renaissance artists used gold for its special reflective quality under candlelight to control the viewers' gaze. The authors argue that 'the glow of the gold induced shifts in fixations to symbolically important regions of the painting' (Figure 1). Candle illumination introduces areas of local contrast that is not apparent under daylight conditions-the thin lines of gold extending into the bodies of the two subjects. It is these regions that show increased fixations under low illumination, raising the possibility that the viewer's gaze and attention are drawn to these regions not because of their symbolism, as Leonards et al. argue, but rather because of their low-level visual salience.Eyes are especially potent in attracting the gaze, both because of their behavioral significance and because they are the regions of high local contrast. Tyler [5•] examined 265 portraits spanning the past 600 years and found a strong tendency for one eye to be centered on the vertical midline of the painting (Figure 2). A recent critique of Tyler's observations asserts that 'one eye tends to be relatively close to the vertical midline because of geometric constraints on the placing of a relatively large object, the head, within a pictorial frame' suggesting that there is no behavioral significance to eye-centering [...

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Section: Nih-pa Author Manuscriptsupporting

confidence: 87%

Perspectives on science and art

Conway¹,

Livingstone²

2007

Current Opinion in Neurobiology

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“…As far as we are aware, ours is the first investigation of the binocular equivalent of the barber-pole illusion. The advantage of this approach is that it rules out explanations based on the disparity of contrast envelopes (McKee et al, 2004;Wilcox and Allison, 2009), since the contrast envelopes for the stimuli used in our experiments either had no disparity (Figs. 2, 6), or could account only for a fraction of the response (Fig.…”

Section: Discussionmentioning

confidence: 99%

“…For example, our ability to localize in depth a horizontal bar might be based on the disparity of the two bar endings (or terminators). However, as previously pointed out (McKee et al, 2004;Wilcox and Allison, 2009), under such conditions mechanisms that match the location of the bar in its entirety could also be used. Accordingly, hard evidence for the role played by terminators per se in extracting depth information is currently lacking.…”

Section: Introductionmentioning

confidence: 98%

Terminator Disparity Contributes to Stereo Matching for Eye Movements and Perception

2013

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In the context of motion detection, the endings (or terminators) of 1-D features can be detected as 2-D features, affecting the perceived direction of motion of the 1-D features (the barber-pole illusion) and the direction of tracking eye movements. In the realm of binocular disparity processing, an equivalent role for the disparity of terminators has not been established. Here we explore the stereo analogy of the barber-pole stimulus, applying disparity to a 1-D noise stimulus seen through an elongated, zero-disparity, aperture. We found that, in human subjects, these stimuli induce robust short-latency reflexive vergence eye movements, initially in the direction orthogonal to the 1-D features, but shortly thereafter in the direction predicted by the disparity of the terminators. In addition, these same stimuli induce vivid depth percepts, which can only be attributed to the disparity of line terminators. When the 1-D noise patterns are given opposite contrast in the two eyes (anticorrelation), both components of the vergence response reverse sign. Finally, terminators drive vergence even when the aperture is defined by a texture (as opposed to a contrast) boundary. These findings prove that terminators contribute to stereo matching, and constrain the type of neuronal mechanisms that might be responsible for the detection of terminator disparity.

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“…4) consists of -from the left column to the right column -V1, V1C end-stop cells [13] and figure layers. The figure layers correspond to the zero-disparity region of foveation.…”

Section: Structure Of the Modelsmentioning

confidence: 99%

“…There are three sets of layers at three interacting spatial resolutions. The first set corresponds to V1, the second set to V1C end-stop cells [13], and the third set learns to extract the figure from the background. The network is connected in a feedforward fashion from left to right and the figure-ground layers have both recurrent and bidirectional connectivity.…”

Section: Structure Of the Modelsmentioning

confidence: 99%

Generalization of Figure-Ground Segmentation from Binocular to Monocular Vision in an Embodied Biological Brain Model

Mingus

Kriete

Herd

et al. 2011

Artificial General Intelligence

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Abstract. Monocular figure-ground segmentation is an important problem in the field of Artificial General Intelligence. A solution to this problem will unlock vast sets of training data, such as Google Images, in which salient objects of interest are situated against complex backgrounds. In order to gain traction on the figure-ground problem we enhanced the Leabra Vision (LVis) model, which is our state-of-the-art model of 3D invariant object recognition [8], such that it can continue to recognize objects against cluttered backgrounds that, while simple, are complex enough to substantially hurt object recognition performance. The principle of operation of the network is that it learns to use a low resolution view of the scene in which high spatial frequency information such as the background falls out of focus in order to predict which aspects of the high resolution scene are the figure. This filtered view then serves to enhance the figure in the input stages of LVis and substantially improves object recognition performance against cluttered backgrounds.

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End stopping in V1 is sensitive to contrast

Cited by 40 publications

References 44 publications

Perspectives on science and art

Perspectives on science and art

Terminator Disparity Contributes to Stereo Matching for Eye Movements and Perception

Generalization of Figure-Ground Segmentation from Binocular to Monocular Vision in an Embodied Biological Brain Model

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