Self-decoration camouflage

Last updated

Reduvius personatus, the masked hunter bug nymph, camouflaged with grains of sand Reduvius personatus, Masked Hunter Bug nymph camouflaged with sand grains.JPG
Reduvius personatus , the masked hunter bug nymph, camouflaged with grains of sand

Self-decoration camouflage is a method of camouflage in which animals or soldiers select materials, sometimes living, from the environment and attach these to themselves for concealment.

Contents

The method was described in 1889 by William Bateson, who observed Stenorhynchus decorator crabs. It was classified as "adventitious protection" by Edward Bagnall Poulton in 1890, and as "adventitious concealing coloration" or "adventitious resemblance" by Hugh Bamford Cott in 1940, who compared it to the way Australian aborigines stalked waterfowl, covering their faces with water lily leaves.

Among animals, self-decoration is found in decorator crabs, some insects such as caddis flies and the masked hunter bug, and occasionally also in octopuses. In military camouflage, it is seen in the use of ghillie suits by snipers and the helmet nets of soldiers more generally, when these are camouflaged by inserting grass and other local plant materials, and in a more general way by the use of decorated camouflage netting over vehicles, gun emplacements and observation posts.

History

Caddisfly larva creates a portable tube decorated with local materials, here small pebbles, in which it lives. Caddisfly-larva.jpg
Caddisfly larva creates a portable tube decorated with local materials, here small pebbles, in which it lives.

In 1889, William Bateson observed in detail the way that decorator crabs fix materials on their backs. He noted that "[t]he whole proceeding is most human and purposeful", and that if a Stenorhynchus crab is cleaned, it will "immediately begin to clothe itself again with the same care and precision as before". [1]

In his book The Colours of Animals (1890), Edward Bagnall Poulton [2] classified protective animal coloration into types such as warning colours and protective mimicry. He included self decoration under the heading "Adventitious Protection", quoting Bateson's account of decorator crabs. [3]

In his textbook Adaptive Coloration in Animals (1940), Hugh Bamford Cott describes self-decoration under the heading "adventitious concealing coloration", also naming it "adventitious resemblance". He describes it as a device "perhaps unrivalled" for effective concealment, and points out that it is brought about and depends on "highly specialized behaviour". Further, it grades into other means of protection including "the borrowing of protection from aposematic partners" and the use of "fortified hiding-places" and burrows. Cott compares the way Australian aborigines once used water lily leaves over their faces to swim towards waterfowl until they were close enough to catch them by the legs. [4]

In animals

Sponge decorator crabs, Hyastenus elatus Hyastenus elatus.jpg
Sponge decorator crabs, Hyastenus elatus

A variety of animals, both predators and prey, make use of self-decoration to conceal themselves. [5]

Antipredator adaptations

Decorator crabs of many species camouflage themselves with pieces of seaweed, shells, small stones, and living organisms such as hydrozoa, sponges, and sea anemones to evade predators. They pick up these pieces and stick them to their shells as semi-permanent camouflage, keeping them until they next moult. Their shells are covered with curved hairs to hold the decorations. [1] [4] [6] The relationship with some of these animals, such as sea anemones is mutualistic; in the case of aposematic animals like stinging sea anemones, the crabs are making use of the warning coloration of these partners to ward off predators. [7]

Self-decoration is seen in some insects such as caddis fly larvae, [5] the nymphs of the masked hunter bug, [8] and occasionally also in octopuses. [5]

Engraving 'Emu Hunting in Australia' by Maturin M. Ballou, 1889 Emu Hunting in Australia 1889.jpg
Engraving 'Emu Hunting in Australia' by Maturin M. Ballou, 1889

Aggressive mimicry

Chrysopidae lacewing larvae decorate themselves with a mixture of materials including moulted cuticle and their own droppings, which appears to serve both to camouflage the larvae and to repel predators. Larvae of species that eat aphids decorate themselves with the waxy material produced by the aphids; larvae decorated like this are ignored by ants which farm the aphids, whereas the ants eject undecorated larvae, making this a wolf in sheep's clothing strategy of aggressive mimicry. [5] [9] Some owlfly larvae, which are ambush predators, similarly self-decorate, hiding until prey comes within range. [10]

The strategy has been used by traditional human hunters, such as when Australian aborigines dressed in emu skins and adopted emu-like postures to hunt these birds. [11]

In military usage

Snipers, working alone, rely heavily on effective camouflage. This is often provided by a ghillie suit, a whole-body covering fitted with many loops into which the wearer can insert grass or other plant materials to match the local environment, or are made with cloth simulating tufts of leaves. Such good camouflage comes at the price of the weight of the ghillie suit and the attached materials; the suit is hot and uncomfortable to wear in hot weather, and it restricts mobility. [12]

The ghillie suit was developed by Scottish gamekeepers for hunting deer, and adapted initially by a Scottish Highland regiment, the Lovat Scouts, for military use. [13] In 1916, the Lovat Scouts became the British Army's first sniper unit. Snipers of many armies have since then adopted the ghillie suit for the effective concealment that it affords. [12]

Cott used the example of the larva of the blotched emerald moth, which fixes a screen of fragments of leaves to its specially hooked bristles, to argue that military camouflage had used the same method, pointing out that the "device is ... essentially the same as one widely practised during the Great War for the concealment, not of caterpillars, but of caterpillar-tractors, [gun] battery positions, observation posts and so forth." [4]

Related Research Articles

<span class="mw-page-title-main">Camouflage</span> Concealment in plain sight by any means, e.g. colour, pattern and shape

Camouflage is the use of any combination of materials, coloration, or illumination for concealment, either by making animals or objects hard to see, or by disguising them as something else. Examples include the leopard's spotted coat, the battledress of a modern soldier, and the leaf-mimic katydid's wings. A third approach, motion dazzle, confuses the observer with a conspicuous pattern, making the object visible but momentarily harder to locate, as well as making general aiming easier. The majority of camouflage methods aim for crypsis, often through a general resemblance to the background, high contrast disruptive coloration, eliminating shadow, and countershading. In the open ocean, where there is no background, the principal methods of camouflage are transparency, silvering, and countershading, while the ability to produce light is among other things used for counter-illumination on the undersides of cephalopods such as squid. Some animals, such as chameleons and octopuses, are capable of actively changing their skin pattern and colours, whether for camouflage or for signalling. It is possible that some plants use camouflage to evade being eaten by herbivores.

<span class="mw-page-title-main">Anti-predator adaptation</span> Defensive feature of prey for selective advantage

Anti-predator adaptations are mechanisms developed through evolution that assist prey organisms in their constant struggle against predators. Throughout the animal kingdom, adaptations have evolved for every stage of this struggle, namely by avoiding detection, warding off attack, fighting back, or escaping when caught.

<span class="mw-page-title-main">Aposematism</span> Honest signalling of an animals powerful defences

Aposematism is the advertising by an animal, whether terrestrial or marine, to potential predators that it is not worth attacking or eating. This unprofitability may consist of any defenses which make the prey difficult to kill and eat, such as toxicity, venom, foul taste or smell, sharp spines, or aggressive nature. These advertising signals may take the form of conspicuous coloration, sounds, odours, or other perceivable characteristics. Aposematic signals are beneficial for both predator and prey, since both avoid potential harm.

<span class="mw-page-title-main">Crypsis</span> Aspect of animal behaviour and morphology

In ecology, crypsis is the ability of an animal or a plant to avoid observation or detection by other animals. It may be a predation strategy or an antipredator adaptation. Methods include camouflage, nocturnality, subterranean lifestyle and mimicry. Crypsis can involve visual, olfactory or auditory concealment. When it is visual, the term cryptic coloration, effectively a synonym for animal camouflage, is sometimes used, but many different methods of camouflage are employed in nature.

<span class="mw-page-title-main">Edward Bagnall Poulton</span> British evolutionary biologist

Sir Edward Bagnall Poulton, FRS HFRSE FLS was a British evolutionary biologist, a lifelong advocate of natural selection through a period in which many scientists such as Reginald Punnett doubted its importance. He invented the term sympatric for evolution of species in the same place, and in his book The Colours of Animals (1890) was the first to recognise frequency-dependent selection. He is remembered for his pioneering work on animal coloration and camouflage, and in particular for inventing the term aposematism for warning coloration. He became Hope Professor of Zoology at the University of Oxford in 1893.

<i>Hymenopus coronatus</i> Species of praying mantis

Hymenopus coronatus is a mantis from the tropical forests of Southeast Asia. It is known by various common names, including walking flower mantis, orchid-blossom mantis and (pink) orchid mantis. It is one of several species known as flower mantis, a reference to their unique physical form and behaviour, which often involves moving with a “swaying” motion, as if being “blown” in the breeze. Several species have evolved to mimic orchid flowers as a hunting and camouflaging strategy, “hiding” themselves in plain view and preying upon pollinating insects that visit the blooms. They are known to grab their prey with blinding speed.

<span class="mw-page-title-main">Hugh B. Cott</span> English zoologist and camouflage expert (1900–1987)

Hugh Bamford Cott was a British zoologist, an authority on both natural and military camouflage, and a scientific illustrator and photographer. Many of his field studies took place in Africa, where he was especially interested in the Nile crocodile, the evolution of pattern and colour in animals. During the Second World War, Cott worked as a camouflage expert for the British Army and helped to influence War Office policy on camouflage. His book Adaptive Coloration in Animals (1940), popular among serving soldiers, was the major textbook on camouflage in zoology of the twentieth century. After the war, he became a Fellow of Selwyn College, Cambridge. As a Fellow of the Zoological Society of London, he undertook expeditions to Africa and the Amazon to collect specimens, mainly reptiles and amphibians.

<span class="mw-page-title-main">Countershading</span> Camouflage to counteract self-shading

Countershading, or Thayer's law, is a method of camouflage in which an animal's coloration is darker on the top or upper side and lighter on the underside of the body. This pattern is found in many species of mammals, reptiles, birds, fish, and insects, both in predators and in prey.

<span class="mw-page-title-main">Decorator crab</span> Self-camouflaging animals

Decorator crabs are crabs of several different species, belonging to the superfamily Majoidea, that use materials from their environment to hide from, or ward off, predators. They decorate themselves by sticking mostly sedentary animals and plants to their bodies as camouflage, or if the attached organisms are noxious, to ward off predators through aposematism.

<span class="mw-page-title-main">Animal coloration</span> General appearance of an animal

Animal colouration is the general appearance of an animal resulting from the reflection or emission of light from its surfaces. Some animals are brightly coloured, while others are hard to see. In some species, such as the peafowl, the male has strong patterns, conspicuous colours and is iridescent, while the female is far less visible.

<span class="mw-page-title-main">Underwater camouflage</span> Camouflage in water, mainly by transparency, reflection, counter-illumination

Underwater camouflage is the set of methods of achieving crypsis—avoidance of observation—that allows otherwise visible aquatic organisms to remain unnoticed by other organisms such as predators or prey.

<span class="mw-page-title-main">Disruptive coloration</span> Camouflage to break up an objects outlines

Disruptive coloration is a form of camouflage that works by breaking up the outlines of an animal, soldier or military hardware with a strongly contrasting pattern. It is often combined with other methods of crypsis including background colour matching and countershading; special cases are coincident disruptive coloration and the disruptive eye mask seen in some fishes, amphibians, and reptiles. It appears paradoxical as a way of not being seen, since disruption of outlines depends on high contrast, so the patches of colour are themselves conspicuous.

<i>Adaptive Coloration in Animals</i> 1940 textbook on camouflage, mimicry and aposematism by Hugh Cott

Adaptive Coloration in Animals is a 500-page textbook about camouflage, warning coloration and mimicry by the Cambridge zoologist Hugh Cott, first published during the Second World War in 1940; the book sold widely and made him famous.

<i>The Colours of Animals</i> 1890 book by Edward Bagnall Poulton

The Colours of Animals is a zoology book written in 1890 by Sir Edward Bagnall Poulton (1856–1943). It was the first substantial textbook to argue the case for Darwinian selection applying to all aspects of animal coloration. The book also pioneered the concept of frequency-dependent selection and introduced the term "aposematism".

<i>Concealing-Coloration in the Animal Kingdom</i> Book by Abbott Handerson Thayer

Concealing-Coloration in the Animal Kingdom: An Exposition of the Laws of Disguise Through Color and Pattern; Being a Summary of Abbott H. Thayer's Discoveries is a book published ostensibly by Gerald H. Thayer in 1909, and revised in 1918, but in fact a collaboration with and completion of his father Abbott Handerson Thayer's major work.

<i>Animal Coloration</i> (book) 1892 book by Frank Evers Beddard

Animal Coloration, or in full Animal Coloration: An Account of the Principal Facts and Theories Relating to the Colours and Markings of Animals, is a book by the English zoologist Frank Evers Beddard, published by Swan Sonnenschein in 1892. It formed part of the ongoing debate amongst zoologists about the relevance of Charles Darwin's theory of natural selection to the observed appearance, structure, and behaviour of animals, and vice versa.

<span class="mw-page-title-main">Multi-spectral camouflage</span> Camouflage designed to work at multiple frequencies, not just visible light

Multi-spectral camouflage is the use of counter-surveillance techniques to conceal objects from detection across several parts of the electromagnetic spectrum at the same time. While traditional military camouflage attempts to hide an object in the visible spectrum, multi-spectral camouflage also tries to simultaneously hide objects from detection methods such as infrared, radar, and millimetre-wave radar imaging.

<span class="mw-page-title-main">Coloration evidence for natural selection</span> Early evidence for Darwinism from animal coloration

Animal coloration provided important early evidence for evolution by natural selection, at a time when little direct evidence was available. Three major functions of coloration were discovered in the second half of the 19th century, and subsequently used as evidence of selection: camouflage ; mimicry, both Batesian and Müllerian; and aposematism.

<span class="mw-page-title-main">Disruptive eye mask</span> Camouflage to conceal the eye

Disruptive eye masks are camouflage markings that conceal the eyes of an animal from its predators or prey. They are used by prey, to avoid being seen by predators, and by predators to help them approach their prey.

References

  1. 1 2 Bateson, William (1889). "Notes on the Senses and Habits of some Crustacea". Journal of the Marine Biological Association of the United Kingdom . new series. 1 (2): 211–214. doi:10.1017/S0025315400058045. S2CID   250948106.
  2. Poulton, Edward Bagnall (1890). The Colours of Animals, their meaning and use, especially considered in the case of insects . London: Kegan Paul, Trench, Trübner. pp. 76–79.
  3. Forbes, Peter (2009). Dazzled and Deceived: Mimicry and Camouflage . New Haven, CT: Yale University Press. pp. 50–52. ISBN   9780300178968.
  4. 1 2 3 Cott, Hugh Bamford (1940). Adaptive Coloration in Animals. London: Methuen. pp.  358–360.
  5. 1 2 3 4 Bates, Mary. "Natural Bling: 6 Amazing Animals That Decorate Themselves". National Geographic. Archived from the original on June 11, 2015. Retrieved 11 June 2015.
  6. Hultgren, Kristin; Stachowicz, Jay (2011). "Camouflage in decorator crabs: integrating ecological, behavioural and evolutionary approaches". In Stevens, Martin; Merilaita, Sami (eds.). Animal Camouflage (PDF). Cambridge University Press. ISBN   978-0-521-19911-7.
  7. Acuna, F. H.; Excoffon, A. C.; Scelzo, M. A. (2003). "Mutualism between the sea anemone Antholoba achates (Drayton, 1846) (Cnidaria: Actiniaria: Actinostolidae) and the spider crab Libinia spinosa Milne-Edwards, 1834 (Crustacea: Decapoda, Majidae)". Belgian Journal of Zoology. 133: 85–87. hdl:2246/5820.
  8. Weirauch, Christiane (2006). "Anatomy of Disguise: Camouflaging Structures in Nymphs of Some Reduviidae (Heteroptera)". American Museum Novitates (3542): 1–18. doi:10.1206/0003-0082(2006)3542[1:aodcsi]2.0.co;2. S2CID   7894145.
  9. Eisner, T.; Hicks, K.; Eisner, M.; Robson, D. S. (1978). ""Wolf-in-Sheep's-Clothing" Strategy of a Predaceous Insect Larva". Science. 199 (4330): 790–794. Bibcode:1978Sci...199..790E. doi:10.1126/science.199.4330.790. PMID   17836295. S2CID   11558335.
  10. Henry, C. S. (1977). "The behavior and life histories of two North American ascalaphids" (PDF). Annals of the Entomological Society of America. 70 (2): 179–195. doi:10.1093/aesa/70.2.179.
  11. Ballou, Maturin M. (1889). Foot-Prints of Travel. Boston: Ginn & Company. p. 64.
  12. 1 2 Plaster, John (2006). The Ultimate Sniper: An Advanced Training Manual For Military And Police Snipers. Paladin Press. p. 5. ISBN   0-87364-704-1.
  13. Pegler, Martin (2004). Out of Nowhere: A History of the Military Sniper. Osprey Publishing. ISBN   0-87364-704-1.
This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.