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Hi. I'm not an expert on eyes, so I don't want to edit this but too me at least the sentence "If one eye falls out the other will split in half and go to the other." is not very clear. If someone who knows more agrees maybe they want to clarify it. Jjhunt06:31, 30 April 2007 (UTC)[reply]
Aperture limitation of resolution -- or phased array[edit]
Unless the phases of a light wave in different ommatidia can be compared to form a phased array, which seem unlikely, diffraction limits the resolution (in radians) to about the wave length divided by twice the lens diameter. This makes this type of eye surprising in small animals. Sensitivity to ultraviolet is some help here. I am not sure that this belongs in the article at this time. David R. Ingham01:39, 1 July 2006 (UTC)[reply]
{If any bug has clearer vision than this limit, that would seem to imply that its nervous system were something like a quantum computer. Classical descriptions do not preserve phase information of individual photons. If the output of an ommatidia is describable classically, then the photon is described as being received in only one ommatidia and relative phase is not measured. David R. Ingham04:27, 1 July 2006 (UTC)}[reply]
I'm not sure what you mean by having to be like a quantum computer here. Fased arrays are common in astronomy, and none of them have anything to do with quantum computers. Measuring and correlating phases gets more difficult the higher the frequency of the light is, but the VLTI is an example in infrared light. As far as I know (which isn't very far) animal vision works by incorherently absorbing radiation, which does not capture phase information (unlike a radio antenna, which does), so as neat as it would be, I doubt that insects have interferometric vision. Amaurea (talk) 16:49, 15 June 2013 (UTC)[reply]
I don't know much about the physiology, but a compound eye looks like a phased array, and does not look as good as a single larger dish or lens antenna if the phases are not used. The relevance to quantum is that if the the light phase is transmitted as a nerve phase, without a reference signal and decoding, then neurons can transmit data by their relative phases in other contexts. David R. Ingham (talk) 03:56, 14 June 2021 (UTC)[reply]
Compound eyes: Compound eyes are composed of many light-sensitive elements, each having its own refractive system and each forming a portion of an image [1]. Compared with single-aperature eyes, they have poor resolution, but a very large view angle, polarization, or fast movement detection often make up for the lack of resolution [2].Compound eyes are typically classified as either apposition eyes, that form multiple inverted images, or superposition eyes, that form a single erect image[3]. In the superposition compound eye each rhabdom (light sensitive unit) receives light through many ommatidial facets, while in the apposition compound eye every rhabdom receives light from a single facet[4]. Species: Compound eyes are found in a large number of arthropods, including various species of insects, crustaceans, centipedes, and millipedes [5] as well as a few species of annelids and mollusks [6]. Trilobites, an extinct class of arthropods, also utilized various types of compound eyes. A combination of both types of compound eyes is used in some insects [7]. The various types of compound eyes (apposition and all three superposition types) are present in all crustacean classes except Copepoda[8].
Apposition eyes: Apposition eyes consist of an array of individual units with a single lens and photoreceptor called ommatidia. Each ommatidium gathers light from a small part of the visual field[9]. This type of eye allows for reasonably high resolution but low sensitivity[10]. There are two types of apposition eyes: the typical apposition eye and the neural superposition eye. Species: Apposition eyes are found in Drosophila, many diurnal insects, shallow-water and terrestrial crabs, lower crustacea, and the Limulus horseshoe crab [11][12][13].
Apposition eye (typical)
Neural superposition eye, or schizochroal eyes: Neural superposition eyes are identical to the typical apposition eye in that each lens forms an image on the rhabdom, but the images are combined in the brain. Species: Neural superposition eyes are found in Strepsiptera and dipteran flies [14].
Superposition eyesorclear zone eyes: In superposition eyes, the light from multiple facets combines on the surface of the photoreceptor layer to form a single erect image of the object. Compared to apposition eyes, the superposition eye is much more light sensitive [15][16][17]. In these types of eyes, the dioptric apparatus and the rhabdom layer are separated by an unpigmented clear zone. This permits, in theory, the superposition of light from a number of corneal facets onto a single rhabdom [18]. There are three types of superposition eyes: refracting superposition eyes, reflecting superposition eyes, or parabolic superposition eyes. Many ommatidia contribute to a deep-lying erect image [19]. Species: Superposition eyes are found in nocturnal insects such as neuropteran flies and moths as well as deep-water crustaceans and crabs [20][21][22].
Refracting superposition eyes: Refracting superposition eyes have lenses which are spherical in shape, causing the light to be bent into fewer convergence points on the retina, creating a much higher quality image[23]. Species: Refracting superposition eyes are found in insects, including the Hummingbird hawkmoth, and euphausid crustaceans (krill) [24][25].
Reflecting superposition eyes: In reflecting superposition eyes, the lenses are rectangular in shape, so light is not bent through each of them, rather it is reflected creating multiple convergence points on the retina [26]. Species: Reflecting superposition eyes are found only in most long-bodied decapodcrustaceans such as crayfish, lobsters, and shrimp[27][28][29].
Parabolic superposition eyes: In parabolic superposition eyes, the ommatidia are shaped much like lightbulbs, with the larger end facing outward. Light is processed in a similar fashion as with the refracting superposition eye, however, not to such a precise degree [30]. Species: Parabolic superposition eyes are found in swimming crabs and hermit crabs [31][32].
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