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1 astronomical photography
1. астрономическая фотография, астрофотография
2. астросъемка, фотографирование астрономических объектовБольшой англо-русский и русско-английский словарь > astronomical photography
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2 astronomical photography
1) астрономическая фотография, астрофотография2) астросъёмка, фотографирование астрономических объектовАнгло-русский словарь технических терминов > astronomical photography
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3 astronomical photography
Универсальный англо-русский словарь > astronomical photography
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4 astronomical photography
< astron> ■ Sternfotografie f<astron.phot> ■ Astrofotografie f ; Himmelsfotografie fEnglish-german technical dictionary > astronomical photography
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5 astronomical photography
астрофотография, астрономическая фотографияEnglish-russian dictionary of physics > astronomical photography
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6 astronomical photography
English-russian astronautics dictionary > astronomical photography
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7 astronomical photography
n астрофотографіяEnglish-Ukrainian military dictionary > astronomical photography
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8 astronomical photography
1) астрономічна фотографія, астрофотографія2) астрозйомка, фотографування астрономічних об'єктівEnglish-Ukrainian dictionary of aviation terms > astronomical photography
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9 photography
2) фотосъёмка, фотографирование•- additive color photography -
advertising photography
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aerial photography from a kite
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aerial photography
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aerospace photography
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air-to-air photography
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amateur photography
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animated photography
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applied photography
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art photography
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astronomical photography
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ballistic photography
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black-and-white photography
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borehole photography
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bubble chamber photography
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celestial photography
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cine photography
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close-up photography
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color photography
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composite photography
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daylight photography
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deep-ocean photography
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direct photography
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earth-based lunar photography
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electronic photography
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electrostatic photography
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endoscopic photography
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engineering photography
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exoelectron photography
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fade-in photography
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fade-out photography
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flash photography
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frame-by-frame photography
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half-tone photography
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high-resolution photography
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high-speed photography
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identification photography
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imbibition color photography
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industrial photography
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infrared photography
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instantaneous photography
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integral photography
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interference color photography
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laser photography
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lensless photography
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long-distance photography
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lunar photography
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metric photography
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missile photography
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motion picture photography
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multispectral photography
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newsreel photography
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nuclear track photography
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oscilloscope photography
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panoramic photography
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process-camera photography
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professional photography
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reconnaissance photography
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reproduction photography
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satellite-borne photography
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schlieren photography
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screen photography
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short distance photography
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silver photography
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slow-motion photography
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space photography
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spark photography
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speckle photography
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spectral zonal photography
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squeezed photography
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stellar photography
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stereoscopic photography
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still photography
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stroboscopic photography
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studio photography
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subtractive color photography
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technical photography
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three-color photography
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three-dimensional photography
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time-lapse photography
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traveling-matte photography
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two-color photography
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unconventional photography
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underwater photography
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X-ray photography -
10 photography
фотография; фотографирование@aerial photographyаэро(фото)съемка@airborne photographyаэрофотосъемка@applied photographyприкладная фотография@astronomical photographyастрофотография@celestial photographyастрофотография@color photographyцветная фотография@direct photographyпрямое фотографирование@high-resolution photographyфотографирование с высоким разрешением@infrared photographyинфракрасная фотография@lunar photographyфотографирование Луны@rocket photographyфотографирование с (борта) ракеты@shadow photographyфотографирование теневым методом@spectrozonal photographyспектрозональная фотосъемка@stellar photographyфотографирование звезд@X-ray photographyрентгеновская фотосъемка@ -
11 photography
n•- aerial photography from a kite - aerospace photography - astronomical photography - oblique aerial photography - satellite-borne photography - space photography - strip aerial photography - vertical aerial photographyEnglish-Ukrainian dictionary of aviation terms > photography
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12 астрономическая фотография
Большой англо-русский и русско-английский словарь > астрономическая фотография
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13 астрономическая фотография
astrophotography, astronomical photographyАнгло-русский словарь технических терминов > астрономическая фотография
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14 Abney, William de Wiveleslie
SUBJECT AREA: Photography, film and optics[br]b. 24 July 1843 Englandd. 2 December 1920 England[br]English photographic scientist, inventor and author.[br]Abney began his career as an officer in the Army and was an instructor in chemistry in the Royal Engineers at Chatham, where he made substantial use of photography as a working tool. He retired from the Army in 1877 and joined the Science and Art Department at South Kensington. It was at Abney's suggestion that a collection of photographic equipment and processes was established in the South Kensington Museum (later to become the Science Museum Photography Collection).Abney undertook significant researches into the nature of gelatine silver halide emulsions at a time when they were being widely adopted by photographers. Perhaps his most important practical innovations were the introduction of hydroquinone as a developing agent in 1880 and silver gelatine citrochloride emulsions for printing-out paper (POP) in 1882. However, Abney was at the forefront of many aspects of photographic research during a period of great innovation and change in photography. He devised new techniques of photomechanical printing and conducted significant researches in the fields of photochemistry and spectral analysis. Abney published throughout his career for both the specialist scientist and the more general photographic practitioner.[br]Principal Honours and DistinctionsKCB 1900. FRS 1877. Served at different times as President of the Royal Astronomical, Royal Photographic and Physical Societies. Chairman, Royal Society of Arts.Further ReadingObituary, 1921, Proceedings of the Royal Society (Series A) 99. J.M.Eder, 1945, History of Photography, trans. E.Epstein, New York.JWBiographical history of technology > Abney, William de Wiveleslie
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15 Steinheil, Carl August von
[br]b. 1801 Roppoltsweiler, Alsaced. 1870 Munich, Germany[br]German physicist, founder of electromagnetic telegraphy in Austria, and photographic innovator and lens designer.[br]Steinheil studied under Gauss at Göttingen and Bessel at Königsberg before jointing his parents at Munich. There he concentrated on optics before being appointed Professor of Physics and Mathematics at the University of Munich in 1832. Immediately after the announcement of the first practicable photographic processes in 1839, he began experiments on photography in association with another professor at the University, Franz von Kobell. Steinheil is reputed to have made the first daguerreotypes in Germany; he certainly constructed several cameras of original design and suggested minor improvements to the daguerreotype process. In 1849 he was employed by the Austrian Government as Head of the Department of Telegraphy in the Ministry of Commerce. Electromagnetic telegraphy was an area in which Steinheil had worked for several years previously, and he was now appointed to supervise the installation of a working telegraphic system for the Austrian monarchy. He is considered to be the founder of electromagnetic telegraphy in Austria and went on to perform a similar role in Switzerland.Steinheil's son, Hugo Adolph, was educated in Munich and Augsburg but moved to Austria to be with his parents in 1850. Adolph completed his studies in Vienna and was appointed to the Telegraph Department, headed by his father, in 1851. Adolph returned to Munich in 1852, however, to concentrate on the study of optics. In 1855 the father and son established the optical workshop which was later to become the distinguished lens-manufacturing company C.A. Steinheil Söhne. At first the business confined itself almost entirely to astronomical optics, but in 1865 the two men took out a joint patent for a wide-angle photographic lens claimed to be free of distortion. The lens, called the "periscopic", was not in fact free from flare and not achromatic, although it enjoyed some reputation at the time. Much more important was the achromatic development of this lens that was introduced in 1866 and called the "Aplanet"; almost simultaneously a similar lens, the "Rapid Rentilinear", was introduced by Dallmeyer in England, and for many years lenses of this type were fitted as the standard objective on most photographic cameras. During 1866 the elder Steinheil relinquished his interest in lens manufacturing, and control of the business passed to Adolph, with administrative and financial affairs being looked after by another son, Edward. After Carl Steinheil's death Adolph continued to design and market a series of high-quality photographic lenses until his own death.[br]Further ReadingJ.M.Eder, 1945, History of Photography, trans. E.Epstean, New York (a general account of the Steinheils's work).Most accounts of photographic lens history will give details of the Steinheils's more important work. See, for example, Chapman Jones, 1904, Science and Practice of Photography, 4th edn, London: and Rudolf Kingslake, 1989, A History of the Photographic Lens, Boston.JWBiographical history of technology > Steinheil, Carl August von
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16 Galilei, Galileo
SUBJECT AREA: Photography, film and optics[br]b. 15 February 1564 Pisa, Italyd. 8 January 1642 Arcetri, near Florence, Italy[br]Italian mathematician, astronomer and physicist who established the principle of the pendulum and was first to exploit the telescope.[br]Galileo began studying medicine at the University of Pisa but soon turned to his real interests, mathematics, mechanics and astronomy. He became Professor of Mathematics at Pisa at the age of 25 and three years later moved to Padua. In 1610 he transferred to Florence. While still a student he discovered the isochronous property of the pendulum, probably by timing with his pulse the swings of a hanging lamp during a religious ceremony in Pisa Cathedral. He later designed a pendulum-controlled clock, but it was not constructed until after his death, and then not successfully; the first successful pendulum clock was made by the Dutch scientist Christiaan Huygens in 1656. Around 1590 Galileo established the laws of motion of falling bodies, by timing rolling balls down inclined planes and not, as was once widely believed, by dropping different weights from the Leaning Tower of Pisa. These and other observations received definitive treatment in his Discorsi e dimostrazioni matematiche intorno a due nuove scienzi attenenti alla, meccanica (Dialogues Concerning Two New Sciences…) which was completed in 1634 and first printed in 1638. This work also included Galileo's proof that the path of a projectile was a parabola and, most importantly, the development of the concept of inertia.In astronomy Galileo adopted the Copernican heliocentric theory of the universe while still in his twenties, but he lacked the evidence to promote it publicly. That evidence came with the invention of the telescope by the Dutch brothers Lippershey. Galileo heard of its invention in 1609 and had his own instrument constructed, with a convex object lens and concave eyepiece, a form which came to be known as the Galilean telescope. Galileo was the first to exploit the telescope successfully with a series of striking astronomical discoveries. He was also the first to publish the results of observations with the telescope, in his Sidereus nuncius (Starry Messenger) of 1610. All the discoveries told against the traditional view of the universe inherited from the ancient Greeks, and one in particular, that of the four satellites in orbit around Jupiter, supported the Copernican theory in that it showed that there could be another centre of motion in the universe besides the Earth: if Jupiter, why not the Sun? Galileo now felt confident enough to advocate the theory, but the advance of new ideas was opposed, not for the first or last time, by established opinion, personified in Galileo's time by the ecclesiastical authorities in Rome. Eventually he was forced to renounce the Copernican theory, at least in public, and turn to less contentious subjects such as the "two new sciences" of his last and most important work.[br]Bibliography1610, Sidereus nuncius (Starry Messenger); translation by A.Van Helden, 1989, Sidereus Nuncius, or the Sidereal Messenger; Chicago: University of Chicago Press.1623, Il Saggiatore (The Assayer).1632, Dialogo sopre i due massimi sistemi del mondo, tolemaico e copernicano (Dialogue Concerning the Two Chief World Systems, Ptolemaic and Copernican); translation, 1967, Berkeley: University of California Press.1638, Discorsi e dimostrazioni matematiche intorno a due nuove scienzi attenenti allameccanica (Dialogues Concerning Two New Sciences…); translation, 1991, Buffalo, New York: Prometheus Books (reprint).Further ReadingG.de Santillana, 1955, The Crime of Galileo, Chicago: University of Chicago Press; also 1958, London: Heinemann.H.Stillman Drake, 1980, Galileo, Oxford: Oxford Paperbacks. M.Sharratt, 1994, Galileo: Decisive Innovator, Oxford: Blackwell.J.Reston, 1994, Galileo: A Life, New York: HarperCollins; also 1994, London: Cassell.A.Fantoli, 1994, Galileo: For Copemicanism and for the Church, trans. G.V.Coyne, South Bend, Indiana: University of Notre Dame Press.LRD
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