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81 Isd
1) Военный термин: Individual Soldier Detector, Industrial Support Detachment, Intelligence Security Division, Intelligence Support Detachment, Intelligence Support Division, Internal Security Division, in-service date, information service division, information systems division, infrared suppression device, initial ship design, installation start date, installation supply division, instructional systems development, internal symbol dictionary2) Техника: instructional system design3) Телекоммуникации: Information Services Division, International Standard Dial4) Сокращение: International Subscriber Dialing, intrinsic sphincter deficiency, Image Section Descriptor5) Университет: Instructional Support Department, Instructional Systems Design6) Электроника: Interface State Density7) Вычислительная техника: Interface Summary Design, Integrated Sensor Device (Wacom, LCD)8) Нефть: individual equipment shutdown9) Космонавтика: Information Systems Division (INTELSAT)10) Геофизика: Intermediate Storage Device11) Транспорт: Interim Simulation Display12) Деловая лексика: Investment Services Directive13) Глоссарий компании Сахалин Энерджи: Industrial Safety Declaration14) Образование: Independent School District, Intermediate School District15) Медицинская техника: interscan delay16) Расширение файла: Initial Selection Done, Spelling Checker dictionary (RapidFile)17) Космогония и космология: межзвёздная пыль (interstellar dust)18) Ценные бумаги: Директива об инвестиционных услугах19) Фантастика Imperial Star Destroyer20) Имена и фамилии: Ian Stuart Donaldson21) Правительство: Income Support Division22) Программное обеспечение: Integrated Solutions Division -
82 close ended preferences
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83 domain
1. n владения; территория2. n владение, имение, поместье3. n мат. область4. n мат. интервалtime domain — временная область; временной интервал
5. n физ. домен6. n вчт. проблемная областьdata domain — область определения данных; предметная область
application domain — область приложения; область применения
elastic domain — область упругой работы, упругая область
Синонимический ряд:1. empire (noun) empire; kingdom; principality; realm2. field (noun) area; bailiwick; champaign; demesne; dominion; estate; field; margin; operation; precinct; province; range; region; scope; specialty; sphere; terrain; territory; walk -
84 measuring
1. n измерение, обмер2. n мера; дозировкаmeasuring tank — мерный бак, мерник
Синонимический ряд:1. determining (verb) bounding; delimiting; demarcating; determining; limiting; mark out; marking out2. gauging (verb) gauging; scaling -
85 open-ended preferences
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86 reverse preferences
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87 scheme of preferences
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88 trade preferences
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89 measuring
измерение, замер -
90 Emigration
Traditionally, Portugal has been a country with a history of emigration to foreign lands, as well as to the overseas empire. During the early centuries of empire, only relatively small numbers of Portuguese emigrated to reside permanently in its colonies. After the establishment of the second, largely Brazilian empire in the 17th century, however, greater numbers of Portuguese left to seek their fortunes outside Europe. It was only toward the end of the 19th century, however, that Portuguese emigration became a mass movement, at first, largely to Brazil. While Portuguese-speaking Brazil was by far the most popular destination for the majority of Portuguese emigrants in early modern and modern times, after 1830, the United States and later Venezuela also became common destinations.Portuguese emigration patterns have changed in the 20th century and, as the Portuguese historian and economist Oliveira Martins wrote before the turn of the century, Portuguese emigration rates are a kind of national barometer. Crises and related social, political, and economic conditions within Portugal, as well as the presence of established emigrant communities in various countries, emigration laws, and the world economy have combined to shape emigration rates and destinations.After World War II, Brazil no longer remained the favorite destination of the majority of Portuguese emigrants who left Portugal to improve their lives and standards of living. Beginning in the 1950s, and swelling into a massive stream in the 1960s and into the 1970s, most Portuguese emigrated to find work in France and, after the change in U.S. immigration laws in the mid-1960s, a steady stream went to North America, including Canada. The emigration figures here indicate that the most intensive emigration years coincided with excessive political turmoil and severe draft (army conscription) laws during the First Republic (1912 was the high point), that emigration dropped during World Wars I and II and during economic downturns such as the Depression, and that the largest flow of Portuguese emigration in history occurred after the onset of the African colonial wars (1961) and into the 1970s, as Portuguese sought emigration as a way to avoid conscription or assignment to Africa.1887 17,0001900ca. 17,000 (mainly to Brazil)1910 39,0001912 88,000 (75,000 of these to Brazil)1930ca. 30,000 (Great Depression)1940ca. 8,8001950 41,0001955 57,0001960 67,0001965 131,0001970 209,000Despite considerable efforts by Lisbon to divert the stream of emigrants from Brazil or France to the African territories of Angola and Mozambique, this colonization effort failed, and most Portuguese who left Portugal preferred the better pay and security of jobs in France and West Germany or in the United States, Venezuela, and Brazil, where there were more deeply rooted Portuguese emigrant communities. At the time of the Revolution of 25 April 1974, when the military coup in Lisbon signaled the beginning of pressures for the Portuguese settlers to leave Africa, the total number of Portuguese resident in the two larger African territories amounted to about 600,000. In modern times, nonimperial Portuguese emigration has prevailed over imperial emigration and has had a significant impact on Portugal's annual budget (due to emigrants' remittances), the political system (since emigrants have a degree of absentee voting rights), investment and economy, and culture.A total of 4 million Portuguese reside and work outside Portugal as of 2009, over one-third of the country's continental and island population. It has also been said that more Portuguese of Azorean descent reside outside the Azores than in the Azores. The following statistics reflect the pattern of Portuguese emigrant communities in the world outside the mother country.Overseas Portuguese Communities Population Figures by Country of Residence ( estimates for 2002)Brazil 1,000,000France 650,000S. Africa 600,000USA 500,000Canada 400,000Venezuela 400,000W. Europe 175,000 (besides France and Germany)Germany 125,000Britain (UK) 60,000 (including Channel Islands)Lusophone Africa 50,000Australia 50,000Total: 4,010,000 (estimate) -
91 crown
crown [kraʊn]1 noun(a) (of monarch, martyr, made of flowers etc) couronne f;∎ to succeed to the crown accéder au trône;∎ she wears the crown c'est elle qui règne;∎ crown of thorns couronne f d'épines∎ she won the Wimbledon crown for the second year running elle a remporté le tournoi de Wimbledon pour la seconde année consécutive(c) (top → of hill, tree) sommet m, cime f; (→ of roof) faîte m; (→ of hat) fond m; (→ of road) bombement m; (→ of tooth) couronne f; Architecture (→ of arch) clef f;∎ the crown (of the head) le sommet de la tête(e) (outstanding achievement) couronnement m;∎ it was the crown of his career ce fut le couronnement de sa carrière(f) (paper size) couronne f(a) (confer a title on) couronner, sacrer;∎ she was crowned queen/champion elle fut couronnée reine/championne;∎ the crowned heads of Europe les têtes couronnées de l'Europe(b) (top) couronner; figurative (person's happiness) combler, couronner; (person's efforts) récompenser;∎ to crown a tooth couronner une dent;∎ the woods that crown the hill les bois qui couronnent la colline;∎ her election success crowned her career son succès aux élections a couronné sa carrière;∎ figurative and to crown it all, it started to rain et pour couronner le tout, il s'est mis à pleuvoir(c) (in draughts) damer;∎ to be crowned aller à dame∎ I'll crown you! (hit you) je vais te flanquer un de ces coups sur la tête!∎ the Crown la Couronne, l'État m (monarchique);►► Politics Crown Agent = fonctionnaire du ministère britannique du développement outre-mer chargé des pays étrangers et des organisations internationales;British crown cap capsule f (de bouteille);British crown colony colonie f de la Couronne;French Canadian Crown corporation société f d'État;Law Crown Court ≃ Cour f d'assises (en Angleterre et au pays de Galles);Ceramics Crown Derby = vaisselle de porcelaine fabriquée à Derby en Angleterre;crown estates terres fpl domaniales ou appartenant à la Couronne;crown green terrain m (de boules) bombé;Botany crown imperial couronne f impériale;crown jewels (crown, sceptre etc) joyaux mpl de la Couronne; very familiar humorous (man's genitals) bijoux mpl de famille;crown land terres fpl domaniales;Mining crown pillar stot m;crown prince prince m héritier;Crown rating system (for hotels) système m de classement (des hôtels britanniques);Cookery crown roast rôti m en couronne;Technology crown wheel and pinion couronne f d'entraînement;Law crown witness témoin m à charge -
92 Ayrton, William Edward
[br]b. 14 September 1847 London, Englandd. 8 November 1908 London, England[br]English physicist, inventor and pioneer in technical education.[br]After graduating from University College, London, Ayrton became for a short time a pupil of Sir William Thomson in Glasgow. For five years he was employed in the Indian Telegraph Service, eventually as Superintendent, where he assisted in revolutionizing the system, devising methods of fault detection and elimination. In 1873 he was invited by the Japanese Government to assist as Professor of Physics and Telegraphy in founding the Imperial College of Engineering in Tokyo. There he created a teaching laboratory that served as a model for those he was later to organize in England and which were copied elsewhere. It was in Tokyo that his joint researches with Professor John Perry began, an association that continued after their return to England. In 1879 he became Professor of Technical Physics at the City and Guilds Institute in Finsbury, London, and later was appointed Professor of Physics at the Central Institution in South Kensington.The inventions of Avrton and Perrv included an electric tricycle in 1882, the first practicable portable ammeter and other electrical measuring instruments. By 1890, when the research partnership ended, they had published nearly seventy papers in their joint names, the emphasis being on a mathematical treatment of subjects including electric motor design, construction of electrical measuring instruments, thermodynamics and the economical use of electric conductors. Ayrton was then employed as a consulting engineer by government departments and acted as an expert witness in many important patent cases.[br]Principal Honours and DistinctionsFRS 1881. President, Physical Society 1890–2. President, Institution of Electrical Engineers 1892. Royal Society Royal Medal 1901.Bibliography28 April 1883, British patent no. 2,156 (Ayrton and Perry's ammeter and voltmeter). 1887, Practical Electricity, London (based on his early laboratory courses; 7 edns followed during his lifetime).1892, "Electrotechnics", Journal of the Institution of Electrical Engineers 21, 5–36 (for a survey of technical education).Further ReadingD.W.Jordan, 1985, "The cry for useless knowledge: education for a new Victorian technology", Proceedings of the Institution of Electrical Engineers, 132 (Part A): 587– 601.G.Gooday, 1991, History of Technology, 13: 73–111 (for an account of Ayrton and the teaching laboratory).GW -
93 Ellington, Edward Bayzard
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 2 August 1845 London, Englandd. 10 November 1914 London, England[br]English hydraulic engineer who developed a direct-acting hydraulic lift.[br]Ellington was educated at Denmark Hill Grammar School, London, after which he became articled to John Penn of Greenwich. He stayed there until 1868, working latterly in the drawing office after a period of erecting plant and attending trials on board ship. For some twelve months he superintended the erection of Glengall Wharf, Old Kent Road, and the machinery used therein.In 1869 he went into partnership with Bryan Johnson of Chester, the company being known as Johnson \& Ellington, manufacturing mining and milling machinery. Under Ellington's influence, the firm specialized in the manufacture of hydraulic machinery. In 1874 the company acquired the right to manufacture the Brotherhood three-cylinder hydraulic engine; the company became the Hydraulic Engineering Company Ltd of Chester. Ellington developed a direct-acting hydraulic lift with a special balance arrangement that was smooth-acting and economical in water. He described the lift in a paper that was read to the Institution of Mechanical Engineers (IMechE) in 1882.Soon after Ellington joined the Chester firm, an Act of Parliament was passed, mainly due to his efforts, for the distribution of water under high pressure for the working of passenger and goods lifts and other hydraulic machinery in large towns. In 1872 he initiated the first hydraulic mains company at Hull, thus proving the practicability of the system of a high-pressure water-mains supply. Ellington remained as engineer to the Hull company until he was appointed a director in 1875. He was general manager and engineer of the General Hydraulic Power Company, which operated in London and had subsidiaries in Liverpool (opened in 1889), Manchester (1894) and Glasgow (1895). He maintained an interest in all these companies, as general manager and engineer, until his death.In 1895 he read another paper, "On hydraulic power in towns", to the Institution of Mechanical Engineers. In 1911 he became President of the IMechE; his Presidential Address was on the education of young engineers. In 1913 he delivered the Thomas Hawksley Lecture on "Water as a mechanical agent". He was Chairman of the Building Committee during the extension of the Institution's headquarters. Ellington was also a Member of Council of the Institution of Civil Engineers, a member of the Société des Ingé-nieurs Civils de France and a Governor of Imperial College of Science and Technology.[br]Principal Honours and DistinctionsMember of the Institution of Mechanical Engineers 1875; Member of Council 1898– 1903; President 1911–12.IMcNBiographical history of technology > Ellington, Edward Bayzard
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94 Jablochkoff, Paul
[br]b. 14 September 1847 Serdobsk, Russiad. April 1894 St Petersburg, Russia[br]Russian military engineer and inventor of an electric "candle", the invention of which gave an immense impetus to electric lighting in the 1870s.[br]Jablochkoff studied at the Military Engineering College in St Petersburg. Having a scientific bent, he was sent to the Military Galvano Technical School. At the end of his military service in 1871 he was appointed Director General of the Moscow-Kursk telegraph lines for the Midi Railway Company. At this time he began to develop an interest in electric lighting, and in 1875 he left the Imperial Telegraph Service to devote his time exclusively to scientific pursuits. He found employment at the workshop of M Bréguet in Paris, where Gramme dynamos and Serrin arc lamps were being constructed. After some experimentation he found a means of producing a carbon arc that regulated itself without any mechanism. This lamp, the Jablochkoff candle, with two carbon rods placed parallel to each other and so close that an arc formed at the ends, could continue to burn until the rods were consumed. Plaster of Paris was used to separate the two electrodes and crumbled away as the carbon burned, thus exposing fresh carbon. These lamps were used in May 1878 in Paris to illuminate the avenue de l'Opéra, and later in Rome and London, and in essence were the first practical electric street lighting. Since there was no regulating mechanism, several candles could be placed in a single circuit. Despite inherent defects, such as the inability to restart the lamps after they were extinguished by wind or interruption of supply, they remained in use for some purposes for several years on account of their simplicity and cheapness. In 1877 Jablochkoff obtained the earliest patent to employ transformers to distribute current in an alternating-current circuit.[br]Bibliography11 September 1876, British patent no. 3,552 (Jablochkoff's candle).22 May 1877, British patent no. 1,996 (transformer or induction coil distribution).Further ReadingW.J.King, 1962, The Development of Electrical Technology in the 19th Century, Washington, DC: Smithsonian Institution, Paper 30, pp. 393–407 (a detailed account). W.E.Langdon, 1877, "On a new form of electric light", Journal of the Society ofTelegraph Engineers 6:303–19 (an early report on Jablochkoffs system).Engineering (1878) 26:125–7.GW -
95 Nobel, Immanuel
[br]b. 1801 Gävle, Swedend. 3 September 1872 Stockholm, Sweden[br]Swedish inventor and industrialist, particularly noted for his work on mines and explosives.[br]The son of a barber-surgeon who deserted his family to serve in the Swedish army, Nobel showed little interest in academic pursuits as a child and was sent to sea at the age of 16, but jumped ship in Egypt and was eventually employed as an architect by the pasha. Returning to Sweden, he won a scholarship to the Stockholm School of Architecture, where he studied from 1821 to 1825 and was awarded a number of prizes. His interest then leaned towards mechanical matters and he transferred to the Stockholm School of Engineering. Designs for linen-finishing machines won him a prize there, and he also patented a means of transforming rotary into reciprocating movement. He then entered the real-estate business and was successful until a fire in 1833 destroyed his house and everything he owned. By this time he had married and had two sons, with a third, Alfred (of Nobel Prize fame; see Alfred Nobel), on the way. Moving to more modest quarters on the outskirts of Stockholm, Immanuel resumed his inventions, concentrating largely on India rubber, which he applied to surgical instruments and military equipment, including a rubber knapsack.It was talk of plans to construct a canal at Suez that first excited his interest in explosives. He saw them as a means of making mining more efficient and began to experiment in his backyard. However, this made him unpopular with his neighbours, and the city authorities ordered him to cease his investigations. By this time he was deeply in debt and in 1837 moved to Finland, leaving his family in Stockholm. He hoped to interest the Russians in land and sea mines and, after some four years, succeeded in obtaining financial backing from the Ministry of War, enabling him to set up a foundry and arms factory in St Petersburg and to bring his family over. By 1850 he was clear of debt in Sweden and had begun to acquire a high reputation as an inventor and industrialist. His invention of the horned contact mine was to be the basic pattern of the sea mine for almost the next 100 years, but he also created and manufactured a central-heating system based on hot-water pipes. His three sons, Ludwig, Robert and Alfred, had now joined him in his business, but even so the outbreak of war with Britain and France in the Crimea placed severe pressures on him. The Russians looked to him to convert their navy from sail to steam, even though he had no experience in naval propulsion, but the aftermath of the Crimean War brought financial ruin once more to Immanuel. Amongst the reforms brought in by Tsar Alexander II was a reliance on imports to equip the armed forces, so all domestic arms contracts were abruptly cancelled, including those being undertaken by Nobel. Unable to raise money from the banks, Immanuel was forced to declare himself bankrupt and leave Russia for his native Sweden. Nobel then reverted to his study of explosives, particularly of how to adapt the then highly unstable nitroglycerine, which had first been developed by Ascanio Sobrero in 1847, for blasting and mining. Nobel believed that this could be done by mixing it with gunpowder, but could not establish the right proportions. His son Alfred pursued the matter semi-independently and eventually evolved the principle of the primary charge (and through it created the blasting cap), having taken out a patent for a nitroglycerine product in his own name; the eventual result of this was called dynamite. Father and son eventually fell out over Alfred's independent line, but worse was to follow. In September 1864 Immanuel's youngest son, Oscar, then studying chemistry at Uppsala University, was killed in an explosion in Alfred's laboratory: Immanuel suffered a stroke, but this only temporarily incapacitated him, and he continued to put forward new ideas. These included making timber a more flexible material through gluing crossed veneers under pressure and bending waste timber under steam, a concept which eventually came to fruition in the form of plywood.In 1868 Immanuel and Alfred were jointly awarded the prestigious Letterstedt Prize for their work on explosives, but Alfred never for-gave his father for retaining the medal without offering it to him.[br]Principal Honours and DistinctionsImperial Gold Medal (Russia) 1853. Swedish Academy of Science Letterstedt Prize (jointly with son Alfred) 1868.BibliographyImmanuel Nobel produced a short handwritten account of his early life 1813–37, which is now in the possession of one of his descendants. He also had published three short books during the last decade of his life— Cheap Defence of the Country's Roads (on land mines), Cheap Defence of the Archipelagos (on sea mines), and Proposal for the Country's Defence (1871)—as well as his pamphlet (1870) on making wood a more physically flexible product.Further ReadingNo biographies of Immanuel Nobel exist, but his life is detailed in a number of books on his son Alfred.CM -
96 Tizard, Sir Henry Thoms
SUBJECT AREA: Weapons and armour[br]b. 23 August 1885 Gillingham, Kent, Englandd. 9 October 1959 Fareham, Hampshire, England[br]English scientist and administrator who made many contributions to military technology.[br]Educated at Westminster College, in 1904 Tizard went to Magdalen College, Oxford, gaining Firsts in mathematics and chemistry. After a period of time in Berlin with Nernst, he joined the Royal Institution in 1909 to study the colour changes of indicators. From 1911 until 1914 he was a tutorial Fellow of Oriel College, Oxford, but with the outbreak of the First World War he joined first the Royal Garrison Artillery, then, in 1915, the newly formed Royal Flying Corps, to work on the development of bomb-sights. Successively in charge of testing aircraft, a lieutenant-colonel in the Ministry of Munitions and Assistant Controller of Research and Experiments for the Royal Air Force, he returned to Oxford in 1919 and the following year became Reader in Chemical Thermodynamics; at this stage he developed the use of toluene as an air-craft-fuel additive.In 1922 he was appointed an assistant secretary at the government Department of Industrial and Scientific Research, becoming Principal Assistant Secretary in 1922 and its Permanent Director in 1927; during this time he was also a member of the Aeronautical Research Committee, being Chairman of the latter in 1933–43. From 1929 to 1942 he was Rector of Imperial College. In 1932 he was also appointed Chairman of a committee set up to investigate possible national air-defence systems, and it was largely due to his efforts that the radar proposals of Watson-Watt were taken up and an effective system made operational before the outbreak of the Second World War. He was also involved in various other government activities aimed at applying technology to the war effort, including the dam-buster and atomic bombs.President of Magdalen College in 1942–7, he then returned again to Whitehall, serving as Chairman of the Advisory Council on Scientific Policy and of the Defence Research Policy Committee. Finally, in 1952, he became Pro-Chan-cellor of Southampton University.[br]Principal Honours and DistinctionsAir Force Cross 1918. CB 1927. KCB 1937. GCB 1949. American Medal of Merit 1947. FRS 1926. Ten British and Commonwealth University honorary doctorates. Hon. Fellowship of the Royal Aeronautical Society. Royal Society of Arts Gold Medal. Franklin Institute Gold Medal. President, British Association 1948. Trustee of the British Museum 1937–59.Bibliography1911, The sensitiveness of indicators', British Association Report (describes Tizard's work on colour changes in indicators).Further Reading1961, Biographical Memoirs of Fellows of the Royal Society VII, London: Royal Society.KFBiographical history of technology > Tizard, Sir Henry Thoms
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97 Yagi, Hidetsugu
[br]b. 28 January 1886 Osaka, Japand. January 1976 Osaka, Japan[br]Japanese engineer who, with his student Shintaro Uda, developed the directional ultra-high frequency (UHF) aerial array that bears his name.[br]Yagi studied engineering at Tokyo Imperial University (now Tokyo University), graduating in 1910. For the next four years he taught at Engineering High School in Sendai, Honshu, then in 1914 he was sent to study resonance phenomena under Barkhausen at Dresden University. When the First World War broke out he was touring Europe, so he travelled to London to study under Ambrose Fleming at University College, London. Continuing his travels, he then visited the USA, studying at Harvard under G.W. Pierce, before returning to his teaching post at Sendai Engineering High School, which in 1919 was absorbed into Tohoku University. There, in 1921, he obtained his doctorate, and some years later he was appointed Professor of Electrical Engineering. Having heard of the invention of the magnetron, he worked with a student, Kinjiro Okabe; in 1927 they produced microwave energy at a wavelength of a few tens of centimetres. However, he is best known for his development with another student, Shintaro Uda, of a directional, multi-element ultrahigh frequency aerial, which he demonstrated during a tour of the USA in 1928. During the Second World War Yagi worked on radar systems. After his retirement he became Professor Emeritus at Tohoku and Osaka universities and formed the Yagi Antenna Company.[br]Principal Honours and DistinctionsYagi received various honours, including the Japanese Cultural Order of Merit 1976, and the Valdemar Poulsen Gold Medal.Bibliography1928, "Beam transmission of ultra-short waves", Proceedings of the Institute of Radio Engineers 6:715 (describes the Yagi-Uda aerial).Further ReadingF.E.Terman, 1943, Radio Engineers' Handbook, New York: McGraw-Hill (provides a review of aerials, including the Yagi system).KF
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