Identification of Everyday Objects on the Basis of Gaborized Outline Versions

Sassi, Michaël; Vancleef, Kathleen; Machilsen, Bart; Panis, Sven; Wagemans, Johan

doi:10.1068/i0384

Cited by 25 publications

(60 citation statements)

References 54 publications

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“…Deviations in landing position were also smaller for contours with smaller inter-element angles, which are known to be easier to integrate [21,46,47]. This supports an interpretation of the symmetry effect in terms of grouping and not (only) saccade targeting per se.…”

Section: Discussionsupporting

confidence: 70%

“…Compared to natural scenes, contour integration stimuli are inherently cluttered as a result of the placement of many distracter elements to eliminate proximity or density cues, which is a necessary and general limitation of this paradigm that was designed to isolate grouping by good continuation. Although earlier research has shown that participants can reliably identify many everyday object shapes embedded in such Gabor stimuli when presented in central vision [46,47], it is arguably unclear how accurate or detailed participants' perception of contour shape was with our eccentrically presented shapes, and whether participants perceived the complete closed contour.…”

Section: Discussionmentioning

confidence: 90%

“…Saccadic latency did seem to properly reflect the speed or difficulty of contour integration in the sense that log latency was proportional to the contours' mean path angle in all three experiments, and contour detection difficulty is known to increase with inter-element angle (e.g., [21]; see also [46,47]). However, any influence of symmetry on saccadic latency was simply absent or at least not strong enough to show up in the results.…”

Section: Discussionmentioning

confidence: 99%

“…There is evidence that symmetry serves as a cue in classical figure-ground tasks [17,[53][54][55][56], but local shape characteristics such as the path angle [21,46,47], and global characteristics such as convexity [58] or familiarity [59] seem to be more important determinants of performance in contour integration tasks. Contour integration benefits only slightly from global symmetry in central vision [18], and the benefit is apparently further reduced or entirely absent in peripheral vision.…”

Section: Discussionmentioning

confidence: 99%

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Peripheral Contour Grouping and Saccade Targeting: The Role of Mirror Symmetry

Sassi¹,

Demeyer²,

Wagemans³

2014

Symmetry

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Abstract:Integrating shape contours in the visual periphery is vital to our ability to locate objects and thus make targeted saccadic eye movements to efficiently explore our surroundings. We tested whether global shape symmetry facilitates peripheral contour integration and saccade targeting in three experiments, in which observers responded to a successful peripheral contour detection by making a saccade towards the target shape. The target contours were horizontally (Experiment 1) or vertically (Experiments 2 and 3) mirror symmetric. Observers responded by making a horizontal (Experiments 1 and 2) or vertical (Experiment 3) eye movement. Based on an analysis of the saccadic latency and accuracy, we conclude that the figure-ground cue of global mirror symmetry in the periphery has little effect on contour integration or on the speed and precision with which saccades are targeted towards objects. The role of mirror symmetry may be more apparent under natural viewing conditions with multiple objects competing for attention, where symmetric regions in the visual field can pre-attentively signal the presence of objects, and thus attract eye movements.

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Section: Discussionsupporting

confidence: 70%

Section: Discussionmentioning

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

See 2 more Smart Citations

Peripheral Contour Grouping and Saccade Targeting: The Role of Mirror Symmetry

Sassi¹,

Demeyer²,

Wagemans³

2014

Symmetry

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“…These grouping stimuli come in many flavors: textured regions (e.g., Giora & Casco, 2007;Harrison & Feldman, 2009;Julesz, 1981;Lamme, 1995;Nothdurft, 1985;Roelfsema, Lamme, Spekreijse, & Bosch, 2002;Rossi, Desimone, & Ungerleider, 2001;Wolfson & Landy, 1998), oriented line fields (e.g., Li & Gilbert, 2002;Tversky, Geisler, & Perry, 2004), Gabor fields (e.g., Dakin & Baruch, 2009;Demeyer, De Graef, Verfaillie, & Wagemans, 2011;Field, Hayes, & Hess, 1993;Kovács & Julesz, 1993;Machilsen, Pauwels, & Wagemans, 2009;Nygård, Van Looy, & Wagemans, 2009;Persike & Meinhardt, 2008;Sassi, Vancleef, Machilsen, Panis, & Wagemans, 2010;Watt, Ledgeway, & Dakin, 2008), dot lattices (e.g., Bleumers, De Graef, Verfaillie, & Wagemans, 2008;Claessens & Wagemans, 2005Kubovy & Wagemans, 1995;Põder, 2011), Glass patterns (e.g., Khuu, Moreland, & Phu, 2011;Palomares, Pettet, Vildavski, Hou, & Norcia, 2010;, and many more.…”

Section: Introductionmentioning

confidence: 99%

The construction of perceptual grouping displays using GERT

Demeyer

Machilsen

2011

Behav Res

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To study perceptual grouping processes, vision scientists often use stimuli consisting of spatially separated local elements that, together, elicit the percept of a global structure. We developed a set of methods for constructing such displays and implemented them in an open-source MATLAB toolbox, GERT (Grouping Elements Rendering Toolbox). The main purpose of GERT is to embed a contour in a field of randomly positioned elements, while avoiding the introduction of a local density cue. However, GERT's modular implementation enables the user to create a far greater variety of perceptual grouping displays, using these same methods. A generic rendering engine grants access to a variety of element-drawing functions, including Gabors, Gaussians, letters, and polygons.

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Perceptual Organization

Wagemans

2018

Stevens' Handbook of Experimental Psychology and Cognitive Neuroscience

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Perceptual organization is the process of giving structure to our experience of objects, scenes, and events in the world. The literature on this complex and fascinating topic is huge, dealing with a wide range of phenomena, processes, neural mechanisms, models, and theories. The present overview starts from the seminal work by the Gestalt psychologists, covering the classic laws of perceptual grouping and figure–ground organization. Then follows a review of the main lines of psychophysical and neural research carried out on these and related topics in the past 50 years. The final section covers new directions of research. They refine the conceptual framework and sketch theoretical approaches that could offer interesting alternatives to the mainstream view of information processing in the cortical hierarchy. There is hope for a synthesis to emerge from this scattered field of research, leading to a better understanding of perceptual organization.

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Identification of Everyday Objects on the Basis of Gaborized Outline Versions

Cited by 25 publications

References 54 publications

Peripheral Contour Grouping and Saccade Targeting: The Role of Mirror Symmetry

Peripheral Contour Grouping and Saccade Targeting: The Role of Mirror Symmetry

The construction of perceptual grouping displays using GERT

Perceptual Organization

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