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41 AEM
1) Военный термин: Air Efficiency Medal, Missile Tender, accelerated evaluation method, advance engineering memorandum, advance evaluation note, air effectiveness measurements2) Техника: Association of Equipment Manufactureres (Ассоциация производителей оборудования), Auger-electron microscopy, acoustical emission monitoring, airborne electromagnetism, analytical electronic microscope3) Сокращение: (type abbreviation) Missile support ship, Applied Electro Mechanics Inc. (USA), Aviation Engineering & Maintenance (UK)4) Электроника: Analytical Electron Microscopy5) Вычислительная техника: Automatic Emulation Management (Brother)7) Космонавтика: animal enclosure module( сокр.) (космический летательный аппарат с животными на борту), applications of explorer mission (сокр.) (применение исследовательского полёта)8) Геофизика: airborne electromagnetic bathymetry (сокр.) (аэроэлектромагнитная батиметрия), airborne electromagnetic method (электромагнитный аэрометод), электромагнитометрия9) Полимеры: этилен-акрилат-каучук, акриловый эластомер10) Программирование: Advertising Expenditure Measurement11) Микроскопия: Auger-electron microscopy( сокр.) (Оже-электронная микроскопия)12) Макаров: аналитическая электронная микроскопия13) Электротехника: advanced energy-management ( system) (сокр.) (прогрессивная система регулирования потребления электроэнергии)15) Единицы измерений: All Equal Metric -
42 human
1. adjectivethe human race — die menschliche Rasse
2. nounI'm only human — ich bin auch nur ein Mensch
Mensch, der* * *['hju:mən] 1. adjective(of, natural to, concerning, or belonging to, mankind: human nature; The dog was so clever that he seemed almost human.) menschlich2. noun(a person: Humans are not as different from animals as we might think.) der Mensch- humanly- human being
- human resources* * *hu·man[ˈhju:mən]I. n Mensch mII. adj behaviour, skeleton menschlichto form a \human chain eine Menschenkette bildento be beyond \human power nicht in der Macht des Menschen liegen\human relationships/sexuality die Beziehungen/die Sexualität des Menschen* * *['hjuːmən]1. adjmenschlich; health, brain, part of the body des Menschennot fit for human consumption — zum Verzehr (durch den Menschen) ungeeignet
these footprints certainly aren't human — diese Fußspuren sind or stammen sicher nicht von Menschen
2. nMensch m* * *human [ˈhjuːmən]1. menschlich, Menschen…:I am only human ich bin auch nur ein Mensch;they’re only human too die kochen auch nur mit Wasser;that’s only human das ist doch menschlich;human being Mensch m;human chain Menschenkette f;human counter Human Counter m (der Strahlenschutzüberwachung dienendes Messgerät zur Bestimmung der vom menschlichen Körper aufgenommenen und wieder abgegebenen Strahlung);human dignity Menschenwürde f;human engineering Human Engineering n, Anthropotechnik f (Teilgebiet der Industrieanthropologie, das sich mit der Anpassung technischer Einrichtungen und Abläufe an die physischen, psychischen und sozialen Erfordernisse des Menschen befasst);human error menschliches Versagen;human flesh Menschenfleisch n;human history die Geschichte der Menschheit;human immunodeficiency virus MED humanes Immunschwächevirus;human-interest story ergreifende oder ein menschliches Schicksal behandelnde Geschichte;human medicine Humanmedizin f;human nature die menschliche Natur;it’s only human nature to do sth es ist nur allzu menschlich oder es liegt ganz einfach in der menschlichen Natur, etwas zu tun;human race Menschengeschlecht n;a) zwischenmenschliche Beziehungen,b) Human Relations, Kontaktpflege f;human rights Menschenrechte;human rights activist Menschenrechtler(in);human rights organization Menschenrechtsorganisation f;B s Mensch m* * *1. adjective 2. nounMensch, der* * *adj.human adj.menschlich adj. -
43 ♦ degree
♦ degree /dɪˈgri:/n.1 grado ( quasi in ogni senso): to a high (o large) degree, in sommo grado; to what degree?, fino a che punto?; to such a degree that …, tanto che (o da) …: He suffers to such a degree that he can't sleep, soffre tanto da non poter dormire; to a ( certain) degree, fino a un certo punto; in una certa misura; a cousin in the second degree, un cugino di secondo grado; (med.) third-degree burns, ustioni di terzo grado; degree of inability, grado d'invalidità; (mat.) equation of the second degree, equazione di secondo grado; (mat.) a 45-degree angle, un angolo di 45 gradi; (geogr.) degree of latitude, grado di latitudine; ten degrees below zero, dieci gradi sotto zero; (gramm.) comparative degree, grado comparativo NOTA D'USO: - grades o degrees?-2 diploma universitario ( equivalente alla laurea in Italia): He did a degree in history, si è laureato in storia; She's doing a degree at Cambridge University, fa un corso di laurea all'università di Cambridge; to get a degree, laurearsi; a degree in engineering (o an engineering degree) una laurea in ingegneria; honorary degree, laurea honoris causa; a first degree, un diploma universitario di primo livello ( equivalente alla laurea triennale in Italia); a higher degree, un diploma universitario di secondo livello ( equivalente alla laurea magistrale o specialistica in Italia); (in GB) a first-class honours degree, una laurea con voti alti; DIALOGO → - Qualifications- I've got a degree in Business Studies, ho una laurea in amministrazione aziendale NOTE DI CULTURA: ► BA, MA, PhD3 (leg.) grado; gravità: murder in the first degree (o first-degree murder) omicidio di primo grado ( con circostanze aggravanti, come la premeditazione); murder in the second degree (o second-degree murder) omicidio di secondo grado ( senza circostanze aggravanti)● by degrees, per gradi, poco alla volta: to advance by degrees, avanzare per gradi; The town is dying by degrees, la città sta morendo poco alla volta □ degree ceremony [certificate, course], cerimonia [certificato, corso] di laurea □ degree day, giorno delle lauree □ in some degree, in una certa misura. -
44 Perkins, Jacob
[br]b. 9 July 1766 Newburyport, Massachusetts, USAd. 30 July 1849 London, England[br]American inventor of a nail-making machine and a method of printing banknotes, investigator of the use of steam at very high pressures.[br]Perkins's occupation was that of a gold-and silversmith; while he does not seem to have followed this after 1800, however, it gave him the skills in working metals which he would continue to employ in his inventions. He had been working in America for four years before he patented his nail-making machine in 1796. At the time there was a great shortage of nails because only hand-forged ones were available. By 1800, other people had followed his example and produced automatic nail-making machines, but in 1811 Perkins' improved machines were introduced to England by J.C. Dyer. Eventually Perkins had twenty-one American patents for a range of inventions in his name.In 1799 Perkins invented a system of engraving steel plates for printing banknotes, which became the foundation of modern siderographic work. It discouraged forging and was adopted by many banking houses, including the Federal Government when the Second United States Bank was inaugurated in 1816. This led Perkins to move to Philadelphia. In the intervening years, Perkins had improved his nail-making machine, invented a machine for graining morocco leather in 1809, a fire-engine in 1812, a letter-lock for bank vaults and improved methods of rolling out spoons in 1813, and improved armament and equipment for naval ships from 1812 to 1815.It was in Philadelphia that Perkins became interested in the steam engine, when he met Oliver Evans, who had pioneered the use of high-pressure steam. He became a member of the American Philosophical Society and conducted experiments on the compressibility of water before a committee of that society. Perkins claimed to have liquified air during his experiments in 1822 and, if so, was the real discoverer of the liquification of gases. In 1819 he came to England to demonstrate his forgery-proof system of printing banknotes, but the Bank of England was the only one which did not adopt his system.While in London, Perkins began to experiment with the highest steam pressures used up to that time and in 1822 took out his first of nineteen British patents. This was followed by another in 1823 for a 10 hp (7.5 kW) engine with only 2 in. (51 mm) bore, 12 in. (305 mm) stroke but a pressure of 500 psi (35 kg/cm2), for which he claimed exceptional economy. After 1826, Perkins abandoned his drum boiler for iron tubes and steam pressures of 1,500 psi (105 kg/cm2), but the materials would not withstand such pressures or temperatures for long. It was in that same year that he patented a form of uniflow cylinder that was later taken up by L.J. Todd. One of his engines ran for five days, continuously pumping water at St Katherine's docks, but Perkins could not raise more finance to continue his experiments.In 1823 one his high-pressure hot-water systems was installed to heat the Duke of Wellington's house at Stratfield Saye and it acquired a considerable vogue, being used by Sir John Soane, among others. In 1834 Perkins patented a compression ice-making apparatus, but it did not succeed commercially because ice was imported more cheaply from Norway as ballast for sailing ships. Perkins was often dubbed "the American inventor" because his inquisitive personality allied to his inventive ingenuity enabled him to solve so many mechanical challenges.[br]Further ReadingHistorical Society of Pennsylvania, 1943, biography which appeared previously as a shortened version in the Transactions of the Newcomen Society 24.D.Bathe and G.Bathe, 1943–5, "The contribution of Jacob Perkins to science and engineering", Transactions of the Newcomen Society 24.D.S.L.Cardwell, 1971, From Watt to Clausius. The Rise of Thermodynamics in the Early Industrial Age, London: Heinemann (includes comments on the importance of Perkins's steam engine).A.F.Dufton, 1940–1, "Early application of engineering to warming of buildings", Transactions of the Newcomen Society 21 (includes a note on Perkins's application of a high-pressure hot-water heating system).RLH -
45 works
wə:ks сущ. завод, фабрика Syn: factory, mill pl работающие части механизма - the * of a clock часовой механизм машина( об организме человека) технические сооружения строительные работы( военное) укрепления - defensive * оборонительные сооружения > to give smb., smth. the * (американизм) (сленг) сделать все, что полагается;
сообщить кому-л. все сведения;
задать кому-л. жару;
избить или убить кого-л. > the barber gave him the * парикмахер сделал ему все, что полагается (постриг, побрил и т. п.) > we've given our house the * мы произвели полный ремонт нашего дома > to get the * оказаться убитым или избитым;
попасть в переделку употр. с гл. в ед. и мн. ч.: завод, фабрика, мастерские - a gas * газовый завод building and construction ~ строительные работы building ~ строительные работы capital ~ основные работы civil engineering ~ строительные работы collected ~ собрание сочинений ex ~ (EXW) с завода ex ~ (EXW) франко-завод machinery ~ машиностроительный завод maintenance ~ поддержание в исправном состоянии maintenance ~ текущий ремонт maintenance ~ техническое обслуживание note printing ~ фабрика по печатанию банкнот printing ~ печатные труды public ~ общественные работы relief ~ общественные работы для безработных remittance ~ операции по переводу денег sewage ~ станция очистки сточных вод tendering public ~ заявка на общественные работы upper ~ pl надводная часть судна works завод ~ мастерская ~ общественные работы ~ строительные работы ~ технические сооружения ~ фабрика ~ завод, фабрика -
46 basic
1) основной
2) базисный
3) начальный
4) <chem.> основный
5) основополагающий
6) основоположный
7) фундаментальный
8) базирующий
9) главный
10) щелочной
– basic brick
– basic capacity
– basic cell
– basic concept
– basic converter
– basic dye
– basic dyeing
– basic engine
– basic equation
– basic flux
– basic formula
– basic foundation
– basic frequency
– basic hearth
– basic hole
– basic lining
– basic meaning
– basic model
– basic note
– basic oxide
– basic part
– basic refractory
– basic rock
– basic salt
– basic slag
– basic steel
– basic stock
– basic tolerance
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47 IEN
1) Техника: Internet experiment note2) Шутливое выражение: Imperial Elven Navy3) Вычислительная техника: Internet Engineering Notes, Internet Experiment Notebook (Vorlaeufer, RFC)4) Сетевые технологии: Integrated Enterprise Network, интегрированная сеть масштаба предприятия -
48 bachelor
'bæ ələ(an unmarried man: He's a confirmed bachelor (= he has no intention of ever marrying); (also adjective) a bachelor flat (= a flat suitable for one person).) soltero, casadero- Bachelor of Education
- Bachelor of Engineering
- Bachelor of Fine Arts
- Bachelor of Science
bachelor n solterotr['bæʧələSMALLr/SMALL]1 soltero\SMALLIDIOMATIC EXPRESSION/SMALLconfirmed bachelor solterón nombre masculinobachelor flat piso de solteroBachelor of Arts licenciado,-a en letrasBachelor of Science licenciado,-a en cienciasBachelor of Law licenciado,-a en derechobachelor ['bæʧələr] n1) : soltero m2) : licenciado m, -da fbachelor of arts degree: licenciatura en filosofía y letrasn.• licenciado (Universitario) s.m.n.• bachiller s.m.• celibato s.m.• mancebo s.m.• soltero s.m.'bætʃələr, 'bætʃələ(r)1) ( single man) soltero m; (before n)bachelor apartment o (BrE) flat — departamento m or (Esp) piso m de soltero
bachelor pad — noun (colloq) apartamento m de soltero, departamento m de soltero (AmL), piso m de soltero (Esp), bulín m (RPl fam)
2) ( Educ) licenciado, -da m,f['bætʃǝlǝ(r)]Bachelor of Arts/Science — ( degree) licenciatura f en Filosofía y Letras/en Ciencias
1. N1) (=unmarried man) soltero m2) (Univ)Bachelor of Arts/Science — (=degree) licenciatura f en Filosofía y Letras/Ciencias; (=person) licenciado(-a) m / f en Filosofía y Letras/Ciencias
See:see cultural note DEGREE in degree2.CPDbachelor flat N — piso m or (LAm) departamento m de soltero
bachelor girl N — (US) soltera f
Bachelor of Arts degree N — Licenciatura f en Filosofía y Letras
Bachelor of Science degree N — Licenciatura f en Ciencias
bachelor pad N — piso m or (LAm) departamento m de soltero
bachelor party N — fiesta f para solteros
* * *['bætʃələr, 'bætʃələ(r)]1) ( single man) soltero m; (before n)bachelor apartment o (BrE) flat — departamento m or (Esp) piso m de soltero
bachelor pad — noun (colloq) apartamento m de soltero, departamento m de soltero (AmL), piso m de soltero (Esp), bulín m (RPl fam)
2) ( Educ) licenciado, -da m,fBachelor of Arts/Science — ( degree) licenciatura f en Filosofía y Letras/en Ciencias
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49 bachelor
['bætʃələ(r)]1) (single man) scapolo m., celibe m.2) Bachelor univ.Bachelor of Arts, Law etc. — (degree) = (diploma di) dottore in discipline umanistiche e altre materie, in giurisprudenza (conseguito con un corso di studi di tre o quattro anni)
* * *['bæ ələ](an unmarried man: He's a confirmed bachelor (= he has no intention of ever marrying); ( also adjective) a bachelor flat (= a flat suitable for one person).) scapolo- Bachelor of Education
- Bachelor of Engineering
- Bachelor of Fine Arts
- Bachelor of Science* * *bachelor /ˈbætʃələ(r)/n.1 celibe; scapolo: a confirmed bachelor, uno scapolo impenitente; uno scapolone; an eligible bachelor, un buon partito2 laureato ( con laurea di primo grado): Bachelor of Science, laureato in scienze; bachelor's (degree), laurea di primo grado NOTE DI CULTURA: ► BA4 (zool.) mammifero o uccello maschio senza compagna ( perché il maschio dominante gli impedisce di accoppiarsi): bachelor seal, foca maschio senza compagna● ( USA) bachelor apartment, monolocale □ (bot.) bachelor's buttons, ( Ranunculus acris) ranuncolo comune, botton d'oro; ( Bellis perennis) margheritina; ( Centaurea cyanus) fiordaliso □ bachelor girl, giovane donna che fa vita indipendente; single (f.) indipendente □ ( USA) bachelor mother, ragazza madre □ bachelor pad, appartamentino da scapolo □ ( USA) bachelor party, festa di addio al celibato □ (iron.) bachelor's wife, donna idealebachelorhoodn. [u]celibato.* * *['bætʃələ(r)]1) (single man) scapolo m., celibe m.2) Bachelor univ.Bachelor of Arts, Law etc. — (degree) = (diploma di) dottore in discipline umanistiche e altre materie, in giurisprudenza (conseguito con un corso di studi di tre o quattro anni)
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50 shift for oneself
обходиться без посторонней помощи, действовать самостоятельноAlf was studying engineering at the University when his father came to him, gave him a five pound note and said he must shift for himself. (K. S. Prichard, ‘The Roaring Nineties’, ch. XI) — Альф еще учился в университете (он мечтал стать инженером), когда к нему явился отец, дал ему пять фунтов и сказал, чтобы Альф впредь на него не рассчитывал.
When their father died the children had to shift for themselves. (ALD) — После смерти отца детям пришлось жить самостоятельно.
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51 Davidson, Robert
[br]b. 18 April 1804 Aberdeen, Scotlandd. 16 November 1894 Aberdeen, Scotland[br]Scottish chemist, pioneer of electric power and builder of the first electric railway locomotives.[br]Davidson, son of an Aberdeen merchant, attended Marischal College, Aberdeen, between 1819 and 1822: his studies included mathematics, mechanics and chemistry. He subsequently joined his father's grocery business, which from time to time received enquiries for yeast: to meet these, Davidson began to manufacture yeast for sale and from that start built up a successful chemical manufacturing business with the emphasis on yeast and dyes. About 1837 he started to experiment first with electric batteries and then with motors. He invented a form of electromagnetic engine in which soft iron bars arranged on the periphery of a wooden cylinder, parallel to its axis, around which the cylinder could rotate, were attracted by fixed electromagnets. These were energized in turn by current controlled by a simple commutaring device. Electric current was produced by his batteries. His activities were brought to the attention of Michael Faraday and to the scientific world in general by a letter from Professor Forbes of King's College, Aberdeen. Davidson declined to patent his inventions, believing that all should be able freely to draw advantage from them, and in order to afford an opportunity for all interested parties to inspect them an exhibition was held at 36 Union Street, Aberdeen, in October 1840 to demonstrate his "apparatus actuated by electro-magnetic power". It included: a model locomotive carriage, large enough to carry two people, that ran on a railway; a turning lathe with tools for visitors to use; and a small printing machine. In the spring of 1842 he put on a similar exhibition in Edinburgh, this time including a sawmill. Davidson sought support from railway companies for further experiments and the construction of an electromagnetic locomotive; the Edinburgh exhibition successfully attracted the attention of the proprietors of the Edinburgh 585\& Glasgow Railway (E \& GR), whose line had been opened in February 1842. Davidson built a full-size locomotive incorporating his principle, apparently at the expense of the railway company. The locomotive weighed 7 tons: each of its two axles carried a cylinder upon which were fastened three iron bars, and four electromagnets were arranged in pairs on each side of the cylinders. The motors he used were reluctance motors, the power source being zinc-iron batteries. It was named Galvani and was demonstrated on the E \& GR that autumn, when it achieved a speed of 4 mph (6.4 km/h) while hauling a load of 6 tons over a distance of 1 1/2 miles (2.4 km); it was the first electric locomotive. Nevertheless, further support from the railway company was not forthcoming, although to some railway workers the locomotive seems to have appeared promising enough: they destroyed it in Luddite reaction. Davidson staged a further exhibition in London in 1843 without result and then, the cost of battery chemicals being high, ceased further experiments of this type. He survived long enough to see the electric railway become truly practicable in the 1880s.[br]Bibliography1840, letter, Mechanics Magazine, 33:53–5 (comparing his machine with that of William Hannis Taylor (2 November 1839, British patent no. 8,255)).Further Reading1891, Electrical World, 17:454.J.H.R.Body, 1935, "A note on electro-magnetic engines", Transactions of the Newcomen Society 14:104 (describes Davidson's locomotive).F.J.G.Haut, 1956, "The early history of the electric locomotive", Transactions of the Newcomen Society 27 (describes Davidson's locomotive).A.F.Anderson, 1974, "Unusual electric machines", Electronics \& Power 14 (November) (biographical information).—1975, "Robert Davidson. Father of the electric locomotive", Proceedings of the Meeting on the History of Electrical Engineering Institution of Electrical Engineers, 8/1–8/17 (the most comprehensive account of Davidson's work).A.C.Davidson, 1976, "Ingenious Aberdonian", Scots Magazine (January) (details of his life).PJGR / GW -
52 Eiffel, Alexandre Gustave
SUBJECT AREA: Civil engineering[br]b. 15 December 1832 Dijon, Franced. 27 December 1923 Paris, France[br]French engineer, best known for the famous tower in Paris that bears his name.[br]During his long life Eiffel, together with a number of architects, was responsible for the design and construction of a wide variety of bridges, viaducts, harbour installations, exhibition halls, galleries and department stores; he set up his own firm in 1867 to handle such construction. Of particular note were his great arched bridges, such as the 530 ft (162 m) span arch over the River Douro at Oporto in Portugal (1877–9) and the 550 ft (168 m) span of the Pont de Garabit over the Truyère in France (1880–4). He was responsible in 1884 for the protective iron-work for the Statue of Liberty in New York and, a year later, for the great dome over the Nice Observatory. In 1876 he had collaborated with Boileau to build the Bon Marché department store in Paris. The predominant material for all these structures was iron, and, in some cases glass was important. The famous Eiffel Tower in Paris is entirely of wrought iron, and the legs are supported on masonry piers that are each set into concrete beneath the ground. The idea of the tower was first conceived in 1884 by Maurice Koechlin and Emile Nougier, and Eiffel won a competition for the commission to built the structure. His imaginative and practical scheme was for a strong lightweight construction 984 ft (300 m) high, with its 12,000 sections to be prefabricated and riveted together largely before erection; the open, perforated design reduced the problems of wind resistance. The tower was constructed on schedule by 1889 to commemorate the centenary of the outbreak of the French Revolution and was the tallest structure in the world until the erection of the Empire State Building in New York in 1930–2.[br]Further ReadingJ.Harriss, 1975, The Tallest Tower: Eiffel and the Belle Epoque, Boston: Hough ton Mifflin.F.Poncetton, 1939, Eiffel: Le Magicien du Fer, Paris: Tournelle.DYBiographical history of technology > Eiffel, Alexandre Gustave
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53 Williams, Sir Frederic Calland
SUBJECT AREA: Electronics and information technology[br]b. 26 June 1911 Stockport, Cheshire, Englandd. 11 August 1977 Prestbury, Cheshire, England[br]English electrical engineer who invented the Williams storage cathode ray tube, which was extensively used worldwide as a data memory in the first digital computers.[br]Following education at Stockport Grammar School, Williams entered Manchester University in 1929, gaining his BSc in 1932 and MSc in 1933. After a short time as a college apprentice with Metropolitan Vickers, he went to Magdalen College, Oxford, to study for a DPhil, which he was awarded in 1936. He returned to Manchester University that year as an assistant lecturer, gaining his DSc in 1939. Following the outbreak of the Second World War he worked for the Scientific Civil Service, initially at the Bawdsey Research Station and then at the Telecommunications Research Establishment at Malvern, Worcestershire. There he was involved in research on non-incandescent amplifiers and diode rectifiers and the development of the first practical radar system capable of identifying friendly aircraft. Later in the war, he devised an automatic radar system suitable for use by fighter aircraft.After the war he resumed his academic career at Manchester, becoming Professor of Electrical Engineering and Director of the University Electrotechnical Laboratory in 1946. In the same year he succeeded in developing a data-memory device based on the cathode ray tube, in which the information was stored and read by electron-beam scanning of a charge-retaining target. The Williams storage tube, as it became known, not only found obvious later use as a means of storing single-frame, still television images but proved to be a vital component of the pioneering Manchester University MkI digital computer. Because it enabled both data and program instructions to be stored in the computer, it was soon used worldwide in the development of the early stored-program computers.[br]Principal Honours and DistinctionsKnighted 1976. OBE 1945. CBE 1961. FRS 1950. Hon. DSc Durham 1964, Sussex 1971, Wales 1971. First Royal Society of Arts Benjamin Franklin Medal 1957. City of Philadelphia John Scott Award 1960. Royal Society Hughes Medal 1963. Institution of Electrical Engineers Faraday Medal 1972. Institute of Electrical and Electronics Engineers Pioneer Award 1973.BibliographyWilliams contributed papers to many scientific journals, including Proceedings of the Royal Society, Proceedings of the Cambridge Philosophical Society, Journal of the Institution of Electrical Engineers, Proceedings of the Institution of Mechanical Engineers, Wireless Engineer, Post Office Electrical Engineers' Journal. Note especially: 1948, with J.Kilburn, "Electronic digital computers", Nature 162:487; 1949, with J.Kilburn, "A storage system for use with binary digital computing machines", Proceedings of the Institution of Electrical Engineers 96:81; 1975, "Early computers at Manchester University", Radio \& Electronic Engineer 45:327. Williams also collaborated in the writing of vols 19 and 20 of the MIT RadiationLaboratory Series.Further ReadingB.Randell, 1973, The Origins of Digital Computers, Berlin: Springer-Verlag. M.R.Williams, 1985, A History of Computing Technology, London: Prentice-Hall. See also: Stibitz, George R.; Strachey, Christopher.KFBiographical history of technology > Williams, Sir Frederic Calland
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54 AEM
[lang name="English"]AEM, accelerated evaluation method————————[lang name="English"]AEM, advance engineering memorandum————————[lang name="English"]AEM, advance evaluation note————————[lang name="English"]AEM, air effectiveness measurements (program)————————[lang name="English"]AEM, Бр Air Efficiency Medalмедаль "За отличную службу в ВВС"English-Russian dictionary of planing, cross-planing and slotting machines > AEM
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55 works
[wə:ks]building and construction works строительные работы building works строительные работы capital works основные работы civil engineering works строительные работы collected works собрание сочинений ex works (EXW) с завода ex works (EXW) франко-завод machinery works машиностроительный завод maintenance works поддержание в исправном состоянии maintenance works текущий ремонт maintenance works техническое обслуживание note printing works фабрика по печатанию банкнот printing works печатные труды public works общественные работы relief works общественные работы для безработных remittance works операции по переводу денег sewage works станция очистки сточных вод tendering public works заявка на общественные работы upper works pl надводная часть судна works завод works мастерская works общественные работы works строительные работы works технические сооружения works фабрика works завод, фабрика -
56 PDM
- широтно-импульсная модуляция
- фазоразностная модуляция
- управление данными об изделии
- поверхностная акустическая волна
- модуляция по длительности импульса
- модуль распределения питания
модуль распределения питания
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[Интент]
Рис. APC
Модуль для подачи питания на трехфазную нагрузку
Рис. APC
Модуль для подачи питания на однофазные нагрузкиПараллельные тексты EN-RU
Factory assembled and tested Power Distribution Modules include circuit breaker, power cord, power connection, and circuit monitoring.
Собранные и проверенные на заводе-изготовиетеле модули распределения питания включают в себя автоматический выключатель, кабель, кабельную розетку и средства контроля состояния линии питания.
A variety of breaker and connector options can be chosen to supply either three-phase or single-phase power to the load.
Широкий выбор автоматических выключателей и кабельных розеток позволяет легко подобрать нужный модуль для подачи питания на трехфазные и однофазные нагрузки.
When demand rises and expansion becomes necessary, simply plug in new Power Distribution Modules. The factory-assembled modules, which include circuit breaker, power cord, and power connection, can be installed in mere minutes. There are multiple power ratings and power cord lengths for low to high power, guaranteeing compatibility and quick, easy, and convenient installation.
[APC]Когда потребляемая мощность увеличивается и необходимо расширение системы бесперебойного питания, то достаточно просто вставить новые модули распределения питания. Собранные на заводе-изготовителе модули, состоящие из автоматического выключателя, кабеля и кабельной розетки, можно установить за несколько минут. Модули поставляются на различные номинальные токи и с кабелями различной длины, что позволяет легко подобрать нужный модуль, быстро и без особого труда его установить.
[Перевод Интент]
How to install the PDM
Note: Some Power Distribution Units have filler plates installed. When a PDM is to be installed, the filler plate must be removed from the busbar.
1 Press down on the clip.
2 Pull out the plate from the unit. (Do not throw away the filler plate. Keep it for potential later use).3 Verify that all the breakers are in the OFF position.
4 Press the red button to release the latch.
5 Pull open the latch.Vertical Rack Distribution Panel
Horizontal Rack Distribution Panel
6 Feed the cable(s) up through the top opening in the enclosure and into the cable power troughs (if applicable) on top of enclosures.
How to install a PDM circuit breaker handle tie1 Locate the handle tie above the circuit breaker handles aligning the two tabs between the three handles.
2 Push the handle tie towards the circuit breaker handles until it snaps into position. Check to make sure that the handle tie is secure.
3 The handle tie can be removed by pulling it from the circuit breaker handles.Тематики
- НКУ (шкафы, пульты,...)
- источники и системы электропитания
EN
модуляция по длительности импульса
широтно-импульсная модуляция
ШИМ
—
[Е.С.Алексеев, А.А.Мячев. Англо-русский толковый словарь по системотехнике ЭВМ. Москва 1993]Тематики
Синонимы
EN
управление данными об изделии
Системы PDM обобщают такие технологии, как:
EDM (engineering data management) - управление инженерными данными,
PIM (product information management) - управление информацией об изделии,
TDM (technical data management) - управление техническими данными,
TIM (technical information management) - управление технической информацией,
а также другие системы, которые используются для манипулирования информацией, всесторонне определяющей конкретное изделие. Короче говоря, любая информация, необходимая на том или ином этапе жизненного цикла изделия, может управляться системой PDM, которая предоставляет корректные данные всем пользователям и всем промышленным информационным системам по мере надобности. Наряду с данными, PDM управляет и проектом - процессом разработки изделия, контролируя собственно информацию об изделии - "продукте", о состоянии объектов данных, об утверждении вносимых изменений, осуществляя авторизацию и другие операции, которые влияют на данные об изделии и режимы доступа к ним каждого конкретного пользователя.
Таким образом, речь идет о полном, централизованном и постоянном автоматизированном контроле за всей совокупностью данных, описывающих как само изделие, так и процессы его конструирования, производства, эксплуатации и утилизации.
[ http://www.morepc.ru/dict/]Тематики
EN
фазоразностная модуляция
—
[Л.Г.Суменко. Англо-русский словарь по информационным технологиям. М.: ГП ЦНИИС, 2003.]Тематики
EN
широтно-импульсная модуляция
ШИМ
Последовательный сигнал, информативным в котором является ширина импульса при постоянной частоте следования.
[ http://www.morepc.ru/dict/]
широтно-импульсная модуляция
-
[Я.Н.Лугинский, М.С.Фези-Жилинская, Ю.С.Кабиров. Англо-русский словарь по электротехнике и электроэнергетике, Москва]Тематики
- электротехника, основные понятия
Синонимы
EN
06.04.13 поверхностная акустическая волна [ surface acoustic wave; SAW]: Электроакустический эффект, используемый в системах автоматической идентификации, когда микроволновые радиосигналы малой мощности с помощью пьезоэлектрического кристалла в радиочастотной метке преобразуются в ультразвуковые поверхностные акустические волны.
Примечание - Информация об уникальной идентификации содержится в фазово-временных вариациях отраженного радиочастотной меткой сигнала.
<2>4 Сокращения
ARQ
Автоматический запрос повтора [Automatic Repeat Request]
ASK
Амплитудная манипуляция [Amplitude Shift Keying]
BPSK
Бинарная фазовая манипуляция [Binary Phase Shift Keying]
CDMA
Множественный доступ с кодовым разделением каналов [Code Division Multiple Access]
CSMA
Множественный доступ с анализом состояния канала передачи данных [Carrier Sense Multiple Access]
CSMA/CD
Множественный доступ с анализом состояния канала передачи данных и обнаружением конфликтов [Carrier Sense Multiple Access with Collision Detection]
DBPSK
Дифференциальная бинарная фазовая манипуляция [Differential binary phase shift keying]
DSSS
Широкополосная модуляция с непосредственной передачей псевдослучайной последовательности [Direct sequence spread spectrum modulation]
EIRP (ЭИИМ)
Эквивалентная изотропно-излучаемая мощность [Equivalent Isotropically Radiated Power]
EMI
Электромагнитная помеха [ElectroMagnetic Interference]
ETR
Технический отчет ETSI [European Telecommunications Report]
ETS
Телекоммуникационный стандарт ETSI [European Telecommunications Standard]
ETSI
Европейский институт по стандартизации в области телекоммуникаций [European Telecommunications Standards Institute]
FHSS
Широкополосная модуляция с дискретной перестройкой несущей частоты [Frequency Hopping Spread Spectrum]
FSK
Частотная манипуляция [Frequency Shift Keying]
GHz (ГГц)
Гигагерц [Gigahertz]
GMSK
Минимальная гауссовская манипуляция [Gaussian Minimum Shift Keying]
kHz (кГц)
Килогерц [Kilohertz]
MSK
Минимальнофазовая частотная манипуляция [Minimum shift keying]
MHz (МГц)
Мегагерц [Megahertz]
OBE
Навесное оборудование [On-Board Equipment]
PDM
Модуляция импульса по длительности, широтно-импульсная модуляция [Pulse Duration Modulation]
PM
Фазовая модуляция [Phase modulation]
PPM (ФИМ)
Фазоимпульсная модуляция [Modulation (pulse position)]
PSK
Фазовая манипуляция [Phase Shift Keying]
PWM
Широтно-импульсная модуляция [Pulse Width Modulation]
RF/DC
Обмен данными системы радиочастотной идентификации [Radio frequency data communication]
RFI
Радиопомеха [Radio frequency interference]
RSSI
Индикатор уровня принимаемого сигнала [Receiving Signal Strength Indicator]
S/N
Отношение сигнала к шуму [Signal/noise ratio]
SAW
Поверхностная акустическая волна [Surface Acoustic Wave]
SIN AD
Отношение сигнала к шуму и искажению [Signal to Noise & Distortion]
SRD
Устройство малого радиуса действия [Short Range Device]
TBR
Технические основы регулирования [Technical Basis for Regulation]
TDD
Дуплексная связь с временным разделением каналов [Time Division Duplexing]
TDM
Временное разделение каналов [Time Division Multiplexing]
<2>Библиография
[1]
МЭК 60050-713
(IEC 60050-713)
Международный электротехнический словарь. Часть 713. Радиосвязь: приемники, передатчики, сети и их режим работы
( International Electrotechnical Vocabulary - Part 713: Radiocommunications: transmitters, receivers, networks and operation)
[2]
МЭК 60050-705
(IEC 60050-705)
Международный электротехнический словарь. Глава 705: Распространение радиоволн ( International Electrotechnical Vocabulary - Chapter 705: Radio wave propagation)
[3]
МЭК 60050-702
(IEC 60050-702)
Международный электротехнический словарь. Глава 702: Колебания, сигналы и соответствующие устройства
( International Electrotechnical Vocabulary - Chapter 702: Oscillations, signals and related devices)
[4]
МЭК 60050-121
(IEC 60050-121)
Международный электротехнический словарь. Глава 121: Электромагнетизм ( International Electrotechnical Vocabulary - Part 121: Electromagnetism)
[5]
МЭК 60050-712
(IEC 60050-712)
Международный электротехнический словарь. Глава 712: Антенны ( International Electrotechnical Vocabulary - Chapter 712: Antennas)
[6]
МЭК 60050-221
(IEC 60050-221)
Международный электротехнический словарь. Глава 221: Магнитные материалы и компоненты
( International Electrotechnical Vocabulary - Chapter 221: Magnetic materials and components)
[7]
ИСО/МЭК 2382-9:1995
(ISO/IEC2382-9:1995)
Информационная технология. Словарь. Часть 9. Обмен данными ( Information technology - Vocabulary - Part 9: Data communication)
[8]
МЭК 60050-725
(IEC 60050-725)
Международный электротехнический словарь. Глава 725: Космическая радиосвязь ( International Electrotechnical Vocabulary - Chapter 725: Space radiocommunications)
[9]
МЭК 60050-714
(IEC 60050-714)
Международный электротехнический словарь. Глава 714: Коммутация и сигнализация в электросвязи
( International Electrotechnical Vocabulary - Chapter 714: Switching and signalling in telecommunications)
[10]
МЭК 60050-704
(IEC 60050-704)
Международный Электротехнический словарь. Глава 704. Техника передачи ( International Electrotechnical Vocabulary - Chapter 704: Transmission)
[11]
МЭК 60050-161
(IEC 60050-161)
Международный электротехнический словарь. Глава 161: Электромагнитная совместимость ( International Electrotechnical Vocabulary. Chapter 161: Electromagnetic compatibility)
[12]
ИСО/МЭК 8824-1
(ISO/IEC 8824-1)
Информационные технологии. Абстрактная синтаксическая нотация версии один
(АСН.1). Часть 1. Спецификация основной нотации
(Information technology - Abstract Syntax Notation One (ASN.1): Specification of basic notation)1)
[13]
ИСО/МЭК 9834-1
(ISO/IEC 9834-1)
Информационные технологии. Взаимосвязь открытых систем. Процедуры действий уполномоченных по регистрации ВОС. Часть 1. Общие процедуры и верхние дуги дерева идентификатора объекта АСН.1
( Information technology - Open Systems Interconnection - Procedures for the operation of OSI Registration Authorities: General procedures and top arcs of the ASN. 1 Object Identifier tree)
[14]
ИСО/МЭК 15962]
(ISO/IEC 15962)
Информационные технологии. Радиочастотная идентификация (RFID) для управления предметами. Протокол данных: правила кодирования данных и функции логической памяти
( Information technology - Radio frequency identification ( RFID) for item management - Data protocol: data encoding rules and logical memory functions)
[15]
ИСО/МЭК 19762-1
(ISO/IEC 19762-1)
Информационные технологии. Технологии автоматической идентификации и сбора данных (АИСД). Гармонизированный словарь. Часть 1. Общие термины в области АIDC ( Information technology - Automatic identification and data capture ( AIDC) techniques - Harmonized vocabulary - Part 1: General terms relating to AIDC)
[16]
ИСО/МЭК 19762-2
(ISO/IEC 19762-2)
Информационные технологии. Технологии автоматической идентификации и сбора данных (АИСД). Гармонизированный словарь. Часть 2. Оптические носители данных (ОНД)
( Information technology - Automatic identification and data capture ( AIDC) techniques - Harmonized vocabulary - Part 2: Optically readable media ( ORM))
[17]
ИСО/МЭК 19762-3
(ISO/IEC 19762-3)
Информационные технологии. Технологии автоматической идентификации и сбора данных (АИСД). Гармонизированный словарь. Часть 3. Радиочастотная идентификация (РЧИ)
( Information technology - Automatic identification and data capture ( AIDC) techniques - Harmonized vocabulary - Part 3: Radio frequency identification ( RFID))
[18]
ИСО/МЭК 19762-5
(ISO/IEC 19762-5)
Информационные технологии. Технологии автоматической идентификации и сбора данных (АИСД). Гармонизированный словарь. Часть 5. Системы определения места нахождения
( Information technology - Automatic identification and data capture ( AIDC) techniques - Harmonized vocabulary - Part 5: Locating systems)
[19]
ИСО/МЭК 18000-6
(ISO/IEC 18000-6)
Информационные технологии. Радиочастотная идентификация для управления предметами. Часть 6. Параметры радиоинтерфейса для диапазона частот 860 - 960 МГц ( Information technology - Radio frequency identification for item management - Part 6: Parameters for air interface communications at 860 MHz to 960 MHz)
_____________
1)В оригинале ИСО/МЭК 19762-4 стандарты [12] - [19] включены в раздел «Библиография», однако следует учитывать, что в основном тексте стандарта ссылок на них нет.
<2>
Источник: ГОСТ Р ИСО/МЭК 19762-4-2011: Информационные технологии. Технологии автоматической идентификации и сбора данных (АИСД). Гармонизированный словарь. Часть 4. Общие термины в области радиосвязи оригинал документа
Англо-русский словарь нормативно-технической терминологии > PDM
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