Disruptive coloration provides camouflage independent of background matching

Schaefer, H. Martin; Stobbe, Nina

doi:10.1098/rspb.2006.3615

Cited by 184 publications

(183 citation statements)

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“…In our case, the lower survival of the high-contrast (disruptive black) edge treatment compared with the monocolour average clearly indicates that a reasonable degree of background matching of both component colours must also be involved if disruptive coloration is to provide a camouflage effect. Although both Schaefer & Stobbe (2006) and proposed on the basis of their results that disruptive patterns are still effective even when some of the pattern elements do not match the background, the current results indicate that it is important to consider the specific degree to which pattern elements differ from their background. To take an extreme, if disruptive markings are highly conspicuous, then subtle differences in where they are placed is likely to have little effect on the survivorship of the prey.…”

Section: Discussionmentioning

confidence: 90%

“…Third, since mealworms were placed on top of the artificial moths, there is a possibility that differences in relative contrast between the mealworm and the interior of each moth type played some role in affecting their detectability. Both Cuthill et al (2006) and Schaefer & Stobbe (2006) recognized this problem, and while both considered the effect to be small when compared with the edge effect (Schaefer & Stobbe (2006) had halfconcealed their mealworm for this very reason), it remains a potentially confounding factor. Finally, as a field experiment, there was no direct control over the predators and therefore no direct recording of instances in which prey could have potentially been encountered is yet overlooked owing to the difficulty of detecting them.…”

Section: Introductionmentioning

confidence: 99%

“…For example, in generating disruptively patterned nonbackground-matching moths, varied the lighter colour to create a non-matching treatment, but not the colour of the darker disruptive marks themselves. Moreover, only five different patterns were presented by Schaefer & Stobbe (2006), hence (as the authors note) their results strictly pertain to the specific colour patterns that were evaluated. Second, more importantly, in generating the 'inside' treatments in Cuthill et al (2005) (see also , the density of the interior black patterns was concomitantly increased, raising the possibility that the edge treatments survived better than the inside treatments not because edges were obscured, but because they more closely matched their backgrounds in terms of pattern density.…”

Section: Introductionmentioning

confidence: 99%

“…First, Cuthill et al used colours that effectively matched their backgrounds, so the adaptive value of disruptive coloration is hard to evaluate completely independently of background matching. This limitation has recently been addressed by Merilaita & Lind (2005), Schaefer & Stobbe (2006) and , but, nevertheless, more work needs to be done (Endler 2006). For example, in generating disruptively patterned nonbackground-matching moths, varied the lighter colour to create a non-matching treatment, but not the colour of the darker disruptive marks themselves.…”

Section: Introductionmentioning

confidence: 99%

“…Yet despite its widespread application, it is only recently that ecologists and evolutionary biologists have begun to test the effectiveness of disruptive coloration in the field, and to design experiments to distinguish between the benefits of background matching and disruptive coloration per se (Cuthill et al 2005;Merilaita & Lind 2005;Schaefer & Stobbe 2006;. In an influential recent paper, Cuthill et al (2005) pinned artificial mothlike prey, baited with mealworms, onto oak trees and evaluated their 'survivorship' over 24 h. In their main experiment, five different types of artificial moth were pinned out.…”

Section: Introductionmentioning

confidence: 99%

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Empirical tests of the role of disruptive coloration in reducing detectability

et al. 2007

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Disruptive patterning is a potentially universal camouflage technique that is thought to enhance concealment by rendering the detection of body shapes more difficult. In a recent series of field experiments, artificial moths with markings that extended to the edges of their 'wings' survived at higher rates than moths with the same edge patterns inwardly displaced. While this result seemingly indicates a benefit to obscuring edges, it is possible that the higher density markings of the inwardly displaced patterns concomitantly reduced their extent of background matching. Likewise, it has been suggested that the mealworm baits placed on the artificial moths could have created differential contrasts with different moth patterns. To address these concerns, we conducted controlled trials in which human subjects searched for computer-generated moth images presented against images of oak trees. Moths with edge-extended disruptive markings survived at higher rates, and took longer to find, than all other moth types, whether presented sequentially or simultaneously. However, moths with no edge markings and reduced interior pattern density survived better than their high-density counterparts, indicating that background matching may have played a so-far unrecognized role in the earlier experiments. Our disruptively patterned nonbackground-matching moths also had the lowest overall survivorship, indicating that disruptive coloration alone may not provide significant protection from predators. Collectively, our results provide independent support for the survival value of disruptive markings and demonstrate that there are common features in human and avian perception of camouflage.

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Section: Discussionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Empirical tests of the role of disruptive coloration in reducing detectability

et al. 2007

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Bioinspired Color Change through Guided Reflection

Song

Hao

et al. 2018

Advanced Optical Materials

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been pursued, which is highly desirable in potential wide spread civil and military applications. [20][21][22][23] Some tunable coloration systems, such as stimuli-responsive chromic polymers, [24] cholesteric liquid crystals, [25] photonic crystals, [26,27] microfluidic system, [28,29] and plasmonic structures have been extensively investigated. [30,31] These systems help lay the foundation for the engineering of artificial adaptive camouflage systems with the capability similar to those biological systems that can rapidly alter their colors and patterns in response to the changing background. For example, through the use of simple microfluidic networks, Whitesides and co-workers were able to demonstrate the adaptive color change of their soft robots by pumping fluids with different colors into the microfluidic networks, [28] and using the similar microfluidic approach they further demonstrated entirely soft, autonomous robots. [32] Recently, a biomimetic plasmonic chameleon has been demonstrated, which showed the ability in matching the background using three primary colors by integrating color sensors, microcontrol system, and Au/Ag core-shell nanostructures. [33] Rogers and co-workers also reported an autonomous camouflage system consisting of a thermochromic dye film, distributed Joule heating actuators, and photodetectors lately. [34] With such system they were able to demonstrate the capability of adaptively matching of the background patterns without user input and external measurement.The above mentioned approaches certainly represent the exciting development in adaptive color change. Most of them, however, require the integration of color sensing, signal processing, and active color generation components in their color-change systems, which make both the systems and their fabrication processes relatively complex. Recently, there are explorations of using metamaterials to redirect the background light for "cloaking" of targets, and the practical applications involving metamaterial systems are actively pursued. [35][36][37][38][39][40] Currently, achieving effective color change that can response fast to match background spectra over the entire visible region through a practical and compact system is still a challenging task.Different from above active color-change approaches that involve active color sensing, signal processing, and active color generation, in this work, we explored a passive color-change approach based on guiding of the reflected light from the background (Figure 1a). The use of guiding of the light for matching Color change to match background has attracted particular attentions for many civil and military applications. Different from most current efforts in adaptive color change that include active color processing and generation, in this work a new passive color-change approach without the need of color processing and generation is proposed. Such approach takes inspiration from the biological camouflage systems such as those in the midwater squid Galiteuthis, which use "leaky" fiber-l...

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Optimal camouflage colors determination using spectral reflectance of real‐scene objects

Daneshvar

Tehran

2020

Color Research & Application

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Color selection for a camouflage pattern is a substantial part in designing an effective camouflage pattern. Current color selection methods are often based on the prevailing colors of digital images captured from a scene. However, color extraction from digital images has shown a major difference between the pattern color and the real environment colors. In this article, we present a more precise approach to camouflage color selection based on the spectrophotometric data of dominant objects in a scene. To this end, the dominant objects of a grassland scene were identified. The spectral reflectance of the dominant objects was measured and the percentage of each of them occurred in the scene was estimated. Then, the chromatic values of dominant objects were inserted into an existing camouflage pattern based on the occurrence of each dominant object in the scene. The performance of the obtained colors was assessed by calculating the color difference between the printed camouflage pattern and the dominant objects of the scene. The results showed that using a portable spectrophotometer instead of using a digital camera is more accurate for camouflage color selection and reduces the color difference from the surrounding environment. Furthermore, our method guarantees the absolute similarity between camouflage colors and terrain colors without using camouflage evaluation indexes or photo‐simulation assessment.

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Disruptive coloration provides camouflage independent of background matching

Cited by 184 publications

References 32 publications

Empirical tests of the role of disruptive coloration in reducing detectability

Empirical tests of the role of disruptive coloration in reducing detectability

Bioinspired Color Change through Guided Reflection

Optimal camouflage colors determination using spectral reflectance of real‐scene objects

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