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Что (кто) такое structural slab - определение
MEMORY MANAGEMENT MECHANISM
Slab allocator; Kernel slab; Slab (Unix); Slab (Sun); Slab (Oracle); Slab (Solaris)
Найдено результатов: 522
Waffle slab
CONCRETE FLOORING STRUCTURAL SYSTEM
User:Moniortz/New sandbox; Waffle Slab
A waffle slab or two-way joist slab is a concrete slab made of reinforced concrete with concrete ribs running in two directions on its underside. The name waffle comes from the grid pattern created by the reinforcing ribs.
Structural element
ENGINEERING TERM; STRUCTURAL PART OF A COMPLEX STRUCTURE
Structural member; Structural component; List of structural elements
Structural elements are used in structural analysis to split a complex structure into simple elements. Within a structure, an element cannot be broken down (decomposed) into parts of different kinds (e.
Structural coloration
![Magnificent non-iridescent colours of [[blue-and-yellow macaw]] created by random nanochannels](https://commons.wikimedia.org/wiki/Special:FilePath/Ara ararauna Luc Viatour.jpg?width=200 "Magnificent non-iridescent colours of [[blue-and-yellow macaw]] created by random nanochannels")
![Electron micrograph]] of a fractured surface of [[nacre]] showing multiple thin layers](https://commons.wikimedia.org/wiki/Special:FilePath/Bruchfläche eines Perlmuttstücks.JPG?width=200 "Electron micrograph]] of a fractured surface of [[nacre]] showing multiple thin layers")
![[[Buttercup]] petals exploit both yellow pigment and structural coloration.](https://commons.wikimedia.org/wiki/Special:FilePath/Buttercup petal structural and pigment coloration.svg?width=200 "[[Buttercup]] petals exploit both yellow pigment and structural coloration.")
![Butterfly wing at different magnifications reveals microstructured chitin acting as a [[diffraction grating]]](https://commons.wikimedia.org/wiki/Special:FilePath/Butterfly magnification series collage.jpg?width=200 "Butterfly wing at different magnifications reveals microstructured chitin acting as a [[diffraction grating]]")
![Structural coloration through selective mirrors in the [[emerald swallowtail]]](https://commons.wikimedia.org/wiki/Special:FilePath/Emerald Swallowtail Papilio palinurus scale structure diagrams.svg?width=200 "Structural coloration through selective mirrors in the [[emerald swallowtail]]")
![One of [[Gabriel Lippmann]]'s colour photographs, "Le Cervin", 1899, made using a monochrome photographic process (a single emulsion). The colours are structural, created by interference with light reflected from the back of the glass plate.](https://commons.wikimedia.org/wiki/Special:FilePath/Gabriel Lippmann Le Cervin 1891-1899.jpg?width=200 "One of [[Gabriel Lippmann]]'s colour photographs, \"Le Cervin\", 1899, made using a monochrome photographic process (a single emulsion). The colours are structural, created by interference with light reflected from the back of the glass plate.")
![[[Robert Hooke]]'s 1665 ''[[Micrographia]]'' contains the first observations of structural colours.](https://commons.wikimedia.org/wiki/Special:FilePath/Micrographia title page.gif?width=200 "[[Robert Hooke]]'s 1665 ''[[Micrographia]]'' contains the first observations of structural colours.")
![Drawing of 'firtree' micro-structures in ''[[Morpho]]'' butterfly wing scale](https://commons.wikimedia.org/wiki/Special:FilePath/Morpho butterfly scale christmas tree multilayer structures drawing from electron micrograph.jpg?width=200 "Drawing of 'firtree' micro-structures in ''[[Morpho]]'' butterfly wing scale")
![In 1892, [[Frank Evers Beddard]] noted that ''[[Chrysospalax]]'' golden moles' thick fur was structurally coloured.](https://commons.wikimedia.org/wiki/Special:FilePath/NHM Chrysospalax trevelyani (cropped).JPG?width=200 "In 1892, [[Frank Evers Beddard]] noted that ''[[Chrysospalax]]'' golden moles' thick fur was structurally coloured.")
![The most intense blue known in nature: ''[[Pollia condensata]]'' berries](https://commons.wikimedia.org/wiki/Special:FilePath/Pollia.jpg?width=200 "The most intense blue known in nature: ''[[Pollia condensata]]'' berries")
![interfere]].](https://commons.wikimedia.org/wiki/Special:FilePath/Thin film interference.svg?width=200 "interfere]].")
![[[European bee-eater]]s owe their brilliant colours partly to diffraction grating microstructures in their feathers](https://commons.wikimedia.org/wiki/Special:FilePath/European bee eater.jpg?width=200 "[[European bee-eater]]s owe their brilliant colours partly to diffraction grating microstructures in their feathers")
![In ''[[Morpho]]'' butterflies such as ''Morpho helena'' the brilliant colours are produced by intricate firtree-shaped microstructures too small for optical microscopes.](https://commons.wikimedia.org/wiki/Special:FilePath/butterfly Morpho rhetenor helena (M) KL.jpg?width=200 "In ''[[Morpho]]'' butterflies such as ''Morpho helena'' the brilliant colours are produced by intricate firtree-shaped microstructures too small for optical microscopes.")
![The male ''[[Parotia lawesii]]'' bird of paradise signals to the female with his breast feathers that switch from blue to yellow.](https://commons.wikimedia.org/wiki/Special:FilePath/Parotia lawesii by Bowdler Sharpe.jpg?width=200 "The male ''[[Parotia lawesii]]'' bird of paradise signals to the female with his breast feathers that switch from blue to yellow.")
![Brilliant green of emerald swallowtail, ''[[Papilio palinurus]]'', is created by arrays of microscopic bowls that reflect yellow directly and blue from the sides.](https://commons.wikimedia.org/wiki/Special:FilePath/green Swallotail (Papilio palinurus) - Relic38.jpg?width=200 "Brilliant green of emerald swallowtail, ''[[Papilio palinurus]]'', is created by arrays of microscopic bowls that reflect yellow directly and blue from the sides.")
![Emerald-patched cattleheart butterfly, ''[[Parides sesostris]]'', creates its brilliant green using photonic crystals.](https://commons.wikimedia.org/wiki/Special:FilePath/Parides sesostris MHNT dos.jpg?width=200 "Emerald-patched cattleheart butterfly, ''[[Parides sesostris]]'', creates its brilliant green using photonic crystals.")
![Iridescent scales of ''[[Lamprocyphus augustus]]'' weevil contain diamond-based crystal lattices oriented in all directions to give almost uniform green.](https://commons.wikimedia.org/wiki/Special:FilePath/Curculionidae - Lamprocyphus augustus.JPG?width=200 "Iridescent scales of ''[[Lamprocyphus augustus]]'' weevil contain diamond-based crystal lattices oriented in all directions to give almost uniform green.")
![Iridescent scales on ''[[Entimus imperialis]]'' weevil](https://commons.wikimedia.org/wiki/Special:FilePath/scales covering Entimus imperialis' elytra.jpg?width=200 "Iridescent scales on ''[[Entimus imperialis]]'' weevil")
![Electron micrograph of the three-dimensional [[photonic crystal]]s within the scales on ''[[Entimus imperialis]]'' weevil](https://commons.wikimedia.org/wiki/Special:FilePath/Entimus imperialis' photonic crystal.jpg?width=200 "Electron micrograph of the three-dimensional [[photonic crystal]]s within the scales on ''[[Entimus imperialis]]'' weevil")
![Hollow nanofibre bristles of ''[[Aphrodita aculeata]]'' (a species of sea mouse) reflect light in yellows, reds and greens to warn off predators.](https://commons.wikimedia.org/wiki/Special:FilePath/Aphrodita aculeata (Sea mouse).jpg?width=200 "Hollow nanofibre bristles of ''[[Aphrodita aculeata]]'' (a species of sea mouse) reflect light in yellows, reds and greens to warn off predators.")
![Longfin inshore squid, ''[[Doryteuthis pealeii]]'', has been studied for its ability to change colour.](https://commons.wikimedia.org/wiki/Special:FilePath/Loligo pealeii.jpg?width=200 "Longfin inshore squid, ''[[Doryteuthis pealeii]]'', has been studied for its ability to change colour.")
![[[Thin-film interference]] in a soap bubble. Colour varies with film thickness.](https://commons.wikimedia.org/wiki/Special:FilePath/thinfilmbubble.jpg?width=200 "[[Thin-film interference]] in a soap bubble. Colour varies with film thickness.")
![wasps of the ''[[Pepsis]]'' and ''[[Hemipepsis]]'' genera often produce a bluish tint from the [[sculpturing]] of their otherwise black chitin.](https://commons.wikimedia.org/wiki/Special:FilePath/Pepsis.jpg?width=200 "wasps of the ''[[Pepsis]]'' and ''[[Hemipepsis]]'' genera often produce a bluish tint from the [[sculpturing]] of their otherwise black chitin.")
PRODUCTION OF COLOUR BY MICROSCOPICALLY STRUCTURED SURFACES, BOTH AS A NATURAL PHENOMENON AND IN TECHNOLOGY
Structural color; Structural colour; Schemochrome; Structural colouration; Schemochromatic; Structural colours; Morphotex
Structural coloration in animals, and a few plants, is the production of colour by microscopically structured surfaces fine enough to interfere with visible light, sometimes in combination with pigments. For example, peacock tail feathers are pigmented brown, but their microscopic structure makes them also reflect blue, turquoise, and green light, and they are often iridescent.
Structural type system
MAJOR CLASS OF TYPE SYSTEM, IN WHICH TYPE COMPATIBILITY AND EQUIVALENCE ARE DETERMINED BY THE TYPE'S ACTUAL STRUCTURE OR DEFINITION, AND NOT BY OTHER CHARACTERISTICS SUCH AS ITS NAME OR PLACE OF DECLARATION
Structural subtyping; Structural typing; Structural type
A structural type system (or property-based type system) is a major class of type systems in which type compatibility and equivalence are determined by the type's actual structure or definition and not by other characteristics such as its name or place of declaration. Structural systems are used to determine if types are equivalent and whether a type is a subtype of another.
Structural system
LOAD-RESISTING SUB-SYSTEM OF A STRUCTURE
Structural frame
The term structural system or structural frame in structural engineering refers to the load-resisting sub-system of a building or object. The structural system transfers loads through interconnected elements or members.
Structural variation
CONTIGUOUS LARGE-SCALE DIFFERENCES IN THE GENOMIC DNA BETWEEN INDIVIDUALS
Structural variations; Structural variants; Structural variant
Genomic structural variation is the variation in structure of an organism's chromosome. It consists of many kinds of variation in the genome of one species, and usually includes microscopic and submicroscopic types, such as deletions, duplications, copy-number variants, insertions, inversions and translocations.
Structural engineering
![An [[Airbus A380]], the world's largest passenger airliner](https://commons.wikimedia.org/wiki/Special:FilePath/Airbus A380 blue sky.jpg?width=200 "An [[Airbus A380]], the world's largest passenger airliner")
![A [[statically determinate]] simply supported beam, bending under an evenly distributed load](https://commons.wikimedia.org/wiki/Special:FilePath/Bending.svg?width=200 "A [[statically determinate]] simply supported beam, bending under an evenly distributed load")
![bolt]] in [[shear stress]]. Top figure illustrates single shear, bottom figure illustrates double shear.](https://commons.wikimedia.org/wiki/Special:FilePath/Bolt-in-shear.svg?width=200 "bolt]] in [[shear stress]]. Top figure illustrates single shear, bottom figure illustrates double shear.")
![[[Burj Khalifa]], in [[Dubai]], the [[world's tallest building]], shown under construction in 2007 (since completed)](https://commons.wikimedia.org/wiki/Special:FilePath/Burjdubaiaug92007.jpg?width=200 "[[Burj Khalifa]], in [[Dubai]], the [[world's tallest building]], shown under construction in 2007 (since completed)")
![Earthquake-proof pyramid [[El Castillo, Chichen Itza]]](https://commons.wikimedia.org/wiki/Special:FilePath/Chichen Itza 3.jpg?width=200 "Earthquake-proof pyramid [[El Castillo, Chichen Itza]]")
![[[Galileo Galilei]] published the book ''[[Two New Sciences]]'' in which he examined the failure of simple structures.](https://commons.wikimedia.org/wiki/Special:FilePath/Galileo Galilei by Ottavio Leoni Marucelliana (cropped).jpg?width=200 "[[Galileo Galilei]] published the book ''[[Two New Sciences]]'' in which he examined the failure of simple structures.")
![[[Leonhard Euler]] developed the theory of [[buckling]] of columns.](https://commons.wikimedia.org/wiki/Special:FilePath/Leonhard Euler 2.jpg?width=200 "[[Leonhard Euler]] developed the theory of [[buckling]] of columns.")
![The McDonnell Planetarium by [[Gyo Obata]] in [[St Louis, Missouri]], USA, a concrete shell structure](https://commons.wikimedia.org/wiki/Special:FilePath/McDonnell-Planetarium.jpg?width=200 "The McDonnell Planetarium by [[Gyo Obata]] in [[St Louis, Missouri]], USA, a concrete shell structure")
![[[Millennium Dome]] in London, UK, by [[Richard Rogers]] and [[Buro Happold]]](https://commons.wikimedia.org/wiki/Special:FilePath/Millennium Dome (zakgollop) version.jpg?width=200 "[[Millennium Dome]] in London, UK, by [[Richard Rogers]] and [[Buro Happold]]")
![Design of missile needs in depth understanding of [[Structural Analysis]]](https://commons.wikimedia.org/wiki/Special:FilePath/Patriot missile launch b.jpg?width=200 "Design of missile needs in depth understanding of [[Structural Analysis]]")
![Roman]] era aqueduct circa 19 BC](https://commons.wikimedia.org/wiki/Special:FilePath/Pont du Gard BLS.jpg?width=200 "Roman]] era aqueduct circa 19 BC")
![laws of motion]].](https://commons.wikimedia.org/wiki/Special:FilePath/Sir Isaac Newton by Sir Godfrey Kneller, Bt.jpg?width=200 "laws of motion]].")
![Ove Arup & Partners]]](https://commons.wikimedia.org/wiki/Special:FilePath/Sydney Opera House Sails edit02.jpg?width=200 "Ove Arup & Partners]]")
![''Little Belt'']]: a [[truss bridge]] in [[Denmark]]](https://commons.wikimedia.org/wiki/Special:FilePath/The Little Belt Bridge (1935).jpeg?width=200 "''Little Belt'']]: a [[truss bridge]] in [[Denmark]]")
SUB-DISCIPLINE OF CIVIL ENGINEERING DEALING WITH THE CREATION OF MAN MADE STRUCTURES
Structural design; Structural Engineering; Structure (engineering); Structural Design; Simply supported; Engineering structure; Mechanical structure
Structural engineering is a sub-discipline of civil engineering in which structural engineers are trained to design the 'bones and muscles' that create the form and shape of man-made structures. Structural engineers also must understand and calculate the stability, strength, rigidity and earthquake-susceptibility of built structures for buildingsFAO online publication and nonbuilding structures.
structural engineering
SUB-DISCIPLINE OF CIVIL ENGINEERING DEALING WITH THE CREATION OF MAN MADE STRUCTURES
Structural design; Structural Engineering; Structure (engineering); Structural Design; Simply supported; Engineering structure; Mechanical structure
¦ noun the branch of civil engineering concerned with large modern buildings and similar structures.
Derivatives
structural engineer noun
Slab
WIKIMEDIA DISAMBIGUATION PAGE
Slab (computer science); Slabs; Slab (disambiguation); SLAB; Slab (computing)
·adj Thick; viscous.
II. Slab ·noun The slack part of a sail.
III. Slab ·noun The Wryneck.
IV. Slab ·noun That which is slimy or viscous; moist earth; mud; also, a puddle.
V. Slab ·noun An outside piece taken from a log or timber in sawing it into boards, planks, ·etc.
VI. Slab ·noun A thin piece of anything, especially of marble or other stone, having plane surfaces.
slab
WIKIMEDIA DISAMBIGUATION PAGE
Slab (computer science); Slabs; Slab (disambiguation); SLAB; Slab (computing)
I. a.
Thick, viscous, slimy.
II. n.
Slime, puddle, mud.
Википедия
Slab allocation
Slab allocation is a memory management mechanism intended for the efficient memory allocation of objects. In comparison with earlier mechanisms, it reduces fragmentation caused by allocations and deallocations. This technique is used for retaining allocated memory containing a data object of a certain type for reuse upon subsequent allocations of objects of the same type. It is analogous to an object pool, but only applies to memory, not other resources.
Slab allocation was first introduced in the Solaris 2.4 kernel by Jeff Bonwick. It is now widely used by many Unix and Unix-like operating systems including FreeBSD and Linux.
