Spatiochromatic Properties of Natural Images and Human Vision

Párraga, C. Alejandro; Trościanko, Tom; Tolhurst, David J.

doi:10.1016/s0960-9822(02)00718-2

Cited by 145 publications

(128 citation statements)

References 12 publications

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“…In recent years, a number of computational models of colour vision have been employed to test whether the primate M/L pigments are well suited to underlie the discrimination of fruits embedded in foliage. The consistent answer is that they are (Osorio & Vorobyev 1996;Regan et al 2001;Parraga et al 2002). However, model computations also show that there are other classes of critical behaviours, for example discrimination of edible foliage or of variations in skin coloration, which would be similarly well served by the M/L dimension of primate colour vision Changizi et al 2006).…”

Section: Review Evolution Of Colour Vision In Mammals G H Jacobs 2961mentioning

confidence: 99%

Evolution of colour vision in mammals

Jacobs

2009

Phil. Trans. R. Soc. B

277

228

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Colour vision allows animals to reliably distinguish differences in the distributions of spectral energies reaching the eye. Although not universal, a capacity for colour vision is sufficiently widespread across the animal kingdom to provide prima facie evidence of its importance as a tool for analysing and interpreting the visual environment. The basic biological mechanisms on which vertebrate colour vision ultimately rests, the cone opsin genes and the photopigments they specify, are highly conserved. Within that constraint, however, the utilization of these basic elements varies in striking ways in that they appear, disappear and emerge in altered form during the course of evolution. These changes, along with other alterations in the visual system, have led to profound variations in the nature and salience of colour vision among the vertebrates. This article concerns the evolution of colour vision among the mammals, viewing that process in the context of relevant biological mechanisms, of variations in mammalian colour vision, and of the utility of colour vision.

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Section: Review Evolution Of Colour Vision In Mammals G H Jacobs 2961mentioning

confidence: 99%

Evolution of colour vision in mammals

Jacobs

2009

Phil. Trans. R. Soc. B

277

228

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“…Predicted cone catch values for each predator visual system were modelled from digital images after a transformation from camera to animal color space following a widely used mapping technique (Párraga et al 2002;Pike 2010;Troscianko and Stevens 2015). Cone catch images (32-bits/channel) were used for all image processing, for each predatory visual system.…”

Section: Image Processingmentioning

confidence: 99%

Escape Distance in Ground-Nesting Birds Differs with Individual Level of Camouflage

Wilson‐Aggarwal

Troscianko

Stevens

et al. 2016

The American Naturalist

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Camouflage is one of the most widespread anti-predator strategies in the animal kingdom, yet no animal can match its background perfectly in a complex environment. Therefore, selection should favour individuals that use information on how effective their camouflage is in their immediate habitat when responding to an approaching threat. In a field study of African ground-nesting birds (plovers, coursers, and nightjars), we tested the hypothesis that individuals adaptively modulate their escape behaviour in relation to their degree of background matching. We used digital imaging and models of predator vision to quantify

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“…We transformed the camera's red (R), green (G), blue (B) data to a bird-specific colour space using a polynomial mapping method (Párraga et al 2002;Párraga 2003;Westland & Ripamonti 2004;Stevens et al in press b). We used the European starling (Sturnus vulgaris) as the model (Hart et al 1998), because the cone sensitivities are typical for passerine birds (Hart 2001), identified as the major predators in our study system.…”

Section: Edge Processing Model (A) Stimulimentioning

confidence: 99%

Disruptive coloration, crypsis and edge detection in early visual processing

Stevens

Cuthill²

2006

Proc. R. Soc. B.

216

206

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Many animals use concealing markings to reduce the risk of predation. These include background pattern matching (crypsis), where the coloration matches a random sample of the background and disruptive patterns, whose effectiveness has been hypothesized to lie in breaking up the body into a series of apparently unrelated objects. We have previously established the effectiveness of disruptive coloration against avian predators, using artificial moth-like stimuli with colours designed to match natural backgrounds as perceived by birds. Here, we investigate the mechanism by which disruptive patterns reduce detectability, using a computational vision model of edge detection applied to photographs of our experimental stimuli, calibrated for bird colour vision. We show that, disruptive coloration is effective by exploiting edge detection algorithms that we use to model early visual processing. Thus, 'false' edges are detected within the body rather than at its periphery, so inhibiting successful detection of the animal's body outline.

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Spatiochromatic Properties of Natural Images and Human Vision

Cited by 145 publications

References 12 publications

Evolution of colour vision in mammals

Evolution of colour vision in mammals

Escape Distance in Ground-Nesting Birds Differs with Individual Level of Camouflage

Disruptive coloration, crypsis and edge detection in early visual processing

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