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1 radio engineering industry
Макаров: радиотехническая промышленностьУниверсальный англо-русский словарь > radio engineering industry
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2 radio engineering industry
Politics english-russian dictionary > radio engineering industry
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3 industry
nto convert the industry to peaceful production — конвертировать военную промышленность (на товары массового спроса)
to relocate one's industries — переносить свои предприятия в другое место
to restore industry — возрождать / восстанавливать промышленность
- aerospace industryto sell off an industry — продавать частным владельцам / денационализировать отрасль промышленности
- agricultural industry
- aircraft industry
- allied industries
- ancillary industries
- armaments industry
- arms industry
- atomic industry
- auto industry
- automobile industry
- auxiliary industry
- baby industries
- basic industries
- building industry
- capital goods industries
- capital-intensive industry
- chemical industry
- cinematographic industry
- construction industry
- consumer goods industry
- cottage industry
- craft industry
- defense industries
- defense-related industries
- development of national industry
- diversified industry
- domestic industry
- efficient industry
- electric-power industry
- electronics industry
- electrotechnical industry
- energy industry
- engineering industry
- entertainment industry
- export industries
- export-promoting industries
- extractive industry
- fabricating industry
- farming industry
- ferrous metal industry
- film industry
- food industry
- food-processing industry
- forest industry
- fuel and power industries
- fuel industry
- heavy industry
- high tech industry
- highly developed industries
- home industry
- import-substituting industries
- import-substitution industries
- industries with non-stop production
- infant industry
- instruction industry
- instrument-making industry
- iron and steel industry
- key industry
- labor-consuming industries
- labor-intensive industries
- large-scale industry
- leisure-time industries
- light industry
- local industry
- machine-building industry
- machine-tool industry
- manufacturing industry
- maritime industry
- metal-working industry
- mining industry
- monopolistic industry
- monopolized industry
- motor-car industry
- national industry
- nationalized industry
- nuclear industry
- nuclear-power industry
- oil industry
- oil-extracting industry
- petrochemical industry
- petroleum industry
- power industry
- primary industry
- printing industry
- priority industries
- processing industries
- public industries
- publicly-owned industries
- radio engineering industry
- regional industry
- rural industry
- science-consuming industry
- science-intensive industry
- secondary industry
- service industries
- service-producing industries
- shipbuilding industry
- small-scale industries
- state industry
- state-controlled industry
- state-owned industry
- steel industry
- sunrise industry
- sunset industry
- technically advanced industry
- technology industry
- technology-intensive industry
- tourist industry
- trade industry
- traditional industries
- travel industry
- uneconomic industries
- up-to-date industry
- user industries
- vital industries
- war industry
- weapon industry -
4 ♦ engineering
♦ engineering /ɛndʒɪˈnɪərɪŋ/A n. [u]1 ingegneria: a degree in engineering, una laurea in ingegneria; a feat of engineering, un'impresa ingegneristica; un capolavoro dell'ingegneria; civil engineering, ingegneria civile; mechanical engineering, ingegneria meccanica3 engineering; progettazione d'impiantiB a.ingegneristico; di ingegneria: engineering department, ufficio tecnico; engineering firm, studio tecnico d'ingegneri; engineering industry, industria elettromeccanica; an engineering job, un lavoro come ingegnere● (ass.) engineering insurance, assicurazione contro i rischi del montaggio industriale □ (chim.) engineering resin, tecnopolimero; resina per l'ingegneria. -
5 engineering
1) машиностроение
2) инженерный
3) инженерский
4) инженерство
5) разработка
6) технический
7) инженерное дело
8) <engin.> техника
9) машиностроительный
10) инжиниринг
11) технология
– aeronautic engineering
– agricultural engineering
– civil engineering
– communication engineering
– development engineering
– electrical engineering
– engineering channel
– engineering cybernetics
– engineering design
– engineering development
– engineering drawing
– engineering factors
– engineering material
– engineering mock-up
– engineering plant
– engineering stage
– engineering structure
– engineering survey
– forestry engineering
– heat engineering
– heat-and-power engineering
– helicopter engineering
– highway engineering
– human engineering
– hydraulic engineering
– industrial engineering
– knowledge engineering
– lighter-than-air engineering
– manufacturing engineering
– microprocessor engineering
– nuclear engineering
– physical & engineering
– power engineering
– process engineering
– program engineering
– propulsion engineering
– radio engineering
– reverse engineering
– road engineering
– safety engineering
– sanitary engineering
– shipyard engineering
– software engineering
– solar engineering
– windpower engineering
aviation engineering club — <aeron.> клуб авиатехнический
chemical engineering plant — химико-технологическая установка
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6 engineering
1. n техника; инженерное искусство; технологияenvironmental engineering — технология, учитывающая последствия для окружающей среды
2. n машиностроение3. n неодобр. махинации, интриги, проискиelection engineering — предвыборные махинации; фальсификация выборов
4. n инженерияknowledge engineering — когнитология, инженерия знаний
5. n разработка, проектирование6. a прикладной7. a технический; технологический8. a машиностроительныйСинонимический ряд:1. machinery (adj.) automotive; fabrication; machine; machinery; machining; mechanical; physics; production; tooled2. worming (verb) finagling; finessing; machinating; maneuvering; wangling; worming -
7 engineering
1. [͵endʒıʹnı(ə)rıŋ] n1. 1) техника; инженерное искусство; технологияenvironmental engineering - технология, учитывающая последствия для окружающей среды
engineering fee - вознаграждение /гонорар/ за технические услуги
2) машиностроение (тж. mechanical engineering)2. неодобр. махинации, интриги, проискиelection engineering - предвыборные махинации; фальсификация выборов
3. инженерияhuman engineering - а) психотехника; б) эргономика; в) инженерная психология
4. разработка, проектирование2. [͵endʒıʹnı(ə)rıŋ] aengineering time - а) время технического обслуживания, инженерное время; б) цикл разработки ( вычислительной системы)
1. прикладной ( о науке)2. технический; технологическийengineering cloth - а) ткань для спецодежды; б) техническая ткань
3. машиностроительный -
8 engineering
ˌendʒɪˈnɪərɪŋ техника;
инженерное искусство;
технология - radio * радиотехника - chemical * химическая технология - electrical * электротехника - environmental * технология, учитывающая последствия для окружающей среды - safety * техника безопасности - cinematograph * кинотехника - industrial * организация производства - development * разработка новых конструкций - * fee вознаграждение за технические услуги машиностроение (неодобрительно) махинации, интриги, происки - election * предвыборные махинации;
фальсификация выборов инженерия - social * социальная инженерия (изучает методы перестройки общества) - human * психотехника эргономика инженерная психология разработка, проектирование - * time время технического обслуживания, инженерное время цикл разработки( вычислительной системы) прикладной( о науке) технический;
технологический - * data технические данные - * library техническая библиотека - * cloth ткань для спецодежды техническая ткань машиностроительный - * industry машиностроение civil ~ гражданское строительство communication ~ техника связи computer ~ вычислительная техника computer-aided ~ машинное моделирование concurrent ~ комплексный подход к проектированию electronics ~ электроника electronics ~ электронная техника engineering pres. p. от engineer ~ инженерное искусство;
техника ~ разг. махинации, происки ~ машиностроение ~ прикладной (о науке) ~ attr. машиностроительный;
engineering plant машиностроительный завод;
engineering worker рабочий-машиностроитель ~ attr. машиностроительный;
engineering plant машиностроительный завод;
engineering worker рабочий-машиностроитель ~ attr. машиностроительный;
engineering plant машиностроительный завод;
engineering worker рабочий-машиностроитель genetic ~ генная инженерия human ~ инженерная психология knowledge ~ инженерия знаний mechanical ~ машиностроение mechanical: ~ машинный;
механический;
mechanical engineer инженер-механик;
mechanical engineering машиностроение quality ~ разработка методов обеспечения качества продукции quality ~ техническое обеспечение качества radio ~ радиотехника reliability ~ техника обеспечения надежности requirements ~ выработка требований software ~ вчт. программирование software ~ вчт. программотехника systems ~ вчт. системотехника systems ~ системотехникаБольшой англо-русский и русско-английский словарь > engineering
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9 lands used for industry, transport, communications, radio broadcasting, television, information technology, the support of space activities, power engineering and other purposes
Общая лексика: земли промышленности, транспорта, связи,Универсальный англо-русский словарь > lands used for industry, transport, communications, radio broadcasting, television, information technology, the support of space activities, power engineering and other purposes
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10 Association
- Association for Information Systems Professionals
- Association for Machine Translation and Computational Linguistics
- Association for Systems Management - American Software Association
- American Standards Association - Data Processing Management Association - National Association of Broadcast Engineers and Technicians
- National Association of Communication System Engineers
- National Association of Radio and Television Broadcasters
- National Association of Securities Dealers - Radio Manufactures Association
- Recording Industry Association of America - Systems and Procedures Association
- Telecommunication Industry Association -
11 Association
в соч.- American Communication Association
- American Radio Association
- American Radio-Telegraphists Association
- American Software Association
- American Standards Association
- Association for Computing Machinery
- Association for Information Systems Professionals
- Association for Machine Translation and Computational Linguistics
- Association for Systems Management
- Association for Women in Computing
- Association of Cinematograph and Television Technicians
- Association of Computer Users
- Association of Data Processing Service Organizations
- Association of Machine Translation and Computational Linguistics
- Association of Microelectronic Professionals
- British Engineering Standards Association
- British Robot Association
- British Videogram Association
- Canadian Standards Association
- Cellular Telecommunication Industry Association
- Computer and Business Equipment Manufacturers Association
- Data Interchange Standards Association
- Data Processing Management Association
- Electronic Engineering Association
- Electronic Industries Association of Japan
- Electronic Industries Association
- Electronic Messaging Association
- European Computer Manufactures Association
- Exchange Carriers Standards Association
- Fiber Channel Association
- Independent Computer Consultants Association
- Information Systems Security Association
- Infrared Data Association
- Interactive Multimedia Association
- International Communication Association
- International Computer Facsimile Association
- International Computer Security Association
- International Standards Association
- International Trademark Association
- Japan Electronic Industry Development Association
- Japanese Industrial Robot Association
- Message-Oriented Middleware Association
- MIDI Manufacturer's Association
- Multimedia Telecommunications Association
- National Association of Broadcast Engineers and Technicians
- National Association of Broadcasters
- National Association of Communication System Engineers
- National Association of Radio and Television Broadcasters
- National Association of Securities Dealers
- National Cable Television Association
- National Computer Graphics Association
- National Computer Security Association
- National Electrical Manufacturers Association
- National Electronics Distributors Association
- Optical Storage Technology Association
- Personal Computer Memory Card International Association
- Radio and Electronics Engineering Association
- Radio Manufactures Association
- Radio-Electronics-Television Manufacturers Association
- Recording Industry Association of America
- Scientific Apparatus Manufacturers Association
- SCSI Trade Association
- Semiconductor Industry Association
- Special Libraries Association
- Surface Mount Equipment Manufactures Association
- Systems and Procedures Association
- Telecommunication Industry Association
- Trans-European Research and Education Networking Association
- Video Electronic Standard AssociationThe New English-Russian Dictionary of Radio-electronics > Association
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12 Jenkins, Charles Francis
[br]b. 1867 USAd. 1934 USA[br]American pioneer of motion pictures and television.[br]During the early years of the motion picture industry, Jenkins made many innovations, including the development in 1894 of his own projector, the "Phantoscope", which was widely used for a number of years. In the same year he also suggested the possibility of electrically transmitting pictures over a distance, an interest that led to a lifetime of experimentation. As a result of his engineering contributions to the practical realization of moving pictures, in 1915 the National Motion Picture Board of Trade asked him to chair a committee charged with establishing technical standards for the industry. This in turn led to his proposing the creation of a professional society for those engineers in the industry, and the following year the Society of Motion Picture Engineers (later to become the Society of Motion Picture and Television Engineers) was formed, with Jenkins as its first President. Soon after this he began experiments with mechanical television, using both the Nipkow hole-spiral disc and a low-definition system of his own, based on rotating bevelled glass discs (his so-called "prismatic rings") and alkali-metal photocells. In the 1920s he gave many demonstrations of mechanical television, including a cable transmission of a crude silhouette of President Harding from Washington, DC, to Philadelphia in 1923 and a radio broadcast from Washington in 1928. The following year he formed the Jenkins Television Company to make television transmitters and receivers, but it soon went into debt and was acquired by the de Forest Company, from whom RCA later purchased the patents.[br]Principal Honours and DistinctionsFirst President, Society of Motion Picture Engineers 1916.Bibliography1923, "Radio photographs, radio movies and radio vision", Transactions of the Society of Motion Picture Engineers 16:78.1923, "Recent progress in the transmission of motion pictures by radio", Transactions ofthe Society of Motion Picture Engineers 17:81.1925, "Radio movies", Transactions of the Society of Motion Picture Engineers 21:7. 1930, "Television systems", Journal of the Society of Motion Picture Engineers 15:445. 1925. Vision by Radio.Further ReadingJ.H.Udelson, 1982, The Great Television Race: A History of the American Television Industry, 1925–41: University of Alabama Press.R.W.Hubbell, 1946, 4,000 Years of Television, London: G.Harrap \& Sons.1926. "The Jenkins system", Wireless World 18: 642 (contains a specific account of Jenkins's work).KFBiographical history of technology > Jenkins, Charles Francis
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13 Armstrong, Edwin Howard
[br]b. 18 December 1890 New York City, New York, USAd. 31 January 1954 New York City, New York, USA[br]American engineer who invented the regenerative and superheterodyne amplifiers and frequency modulation, all major contributions to radio communication and broadcasting.[br]Interested from childhood in anything mechanical, as a teenager Armstrong constructed a variety of wireless equipment in the attic of his parents' home, including spark-gap transmitters and receivers with iron-filing "coherer" detectors capable of producing weak Morse-code signals. In 1912, while still a student of engineering at Columbia University, he applied positive, i.e. regenerative, feedback to a Lee De Forest triode amplifier to just below the point of oscillation and obtained a gain of some 1,000 times, giving a receiver sensitivity very much greater than hitherto possible. Furthermore, by allowing the circuit to go into full oscillation he found he could generate stable continuous-waves, making possible the first reliable CW radio transmitter. Sadly, his claim to priority with this invention, for which he filed US patents in 1913, the year he graduated from Columbia, led to many years of litigation with De Forest, to whom the US Supreme Court finally, but unjustly, awarded the patent in 1934. The engineering world clearly did not agree with this decision, for the Institution of Radio Engineers did not revoke its previous award of a gold medal and he subsequently received the highest US scientific award, the Franklin Medal, for this discovery.During the First World War, after some time as an instructor at Columbia University, he joined the US Signal Corps laboratories in Paris, where in 1918 he invented the superheterodyne, a major contribution to radio-receiver design and for which he filed a patent in 1920. The principle of this circuit, which underlies virtually all modern radio, TV and radar reception, is that by using a local oscillator to convert, or "heterodyne", a wanted signal to a lower, fixed, "intermediate" frequency it is possible to obtain high amplification and selectivity without the need to "track" the tuning of numerous variable circuits.Returning to Columbia after the war and eventually becoming Professor of Electrical Engineering, he made a fortune from the sale of his patent rights and used part of his wealth to fund his own research into further problems in radio communication, particularly that of receiver noise. In 1933 he filed four patents covering the use of wide-band frequency modulation (FM) to achieve low-noise, high-fidelity sound broadcasting, but unable to interest RCA he eventually built a complete broadcast transmitter at his own expense in 1939 to prove the advantages of his system. Unfortunately, there followed another long battle to protect and exploit his patents, and exhausted and virtually ruined he took his own life in 1954, just as the use of FM became an established technique.[br]Principal Honours and DistinctionsInstitution of Radio Engineers Medal of Honour 1917. Franklin Medal 1937. IERE Edison Medal 1942. American Medal for Merit 1947.Bibliography1922, "Some recent developments in regenerative circuits", Proceedings of the Institute of Radio Engineers 10:244.1924, "The superheterodyne. Its origin, developments and some recent improvements", Proceedings of the Institute of Radio Engineers 12:549.1936, "A method of reducing disturbances in radio signalling by a system of frequency modulation", Proceedings of the Institute of Radio Engineers 24:689.Further ReadingL.Lessing, 1956, Man of High-Fidelity: Edwin Howard Armstrong, pbk 1969 (the only definitive biography).W.R.Maclaurin and R.J.Harman, 1949, Invention \& Innovation in the Radio Industry.J.R.Whitehead, 1950, Super-regenerative Receivers.A.N.Goldsmith, 1948, Frequency Modulation (for the background to the development of frequency modulation, in the form of a large collection of papers and an extensive bibliog raphy).KFBiographical history of technology > Armstrong, Edwin Howard
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14 Zworykin, Vladimir Kosma
[br]b. 30 July 1889 Mourum (near Moscow), Russiad. 29 July 1982 New York City, New York, USA[br]Russian (naturalized American 1924) television pioneer who invented the iconoscope and kinescope television camera and display tubes.[br]Zworykin studied engineering at the Institute of Technology in St Petersburg under Boris Rosing, assisting the latter with his early experiments with television. After graduating in 1912, he spent a time doing X-ray research at the Collège de France in Paris before returning to join the Russian Marconi Company, initially in St Petersburg and then in Moscow. On the outbreak of war in 1917, he joined the Russian Army Signal Corps, but when the war ended in the chaos of the Revolution he set off on his travels, ending up in the USA, where he joined the Westinghouse Corporation. There, in 1923, he filed the first of many patents for a complete system of electronic television, including one for an all-electronic scanning pick-up tube that he called the iconoscope. In 1924 he became a US citizen and invented the kinescope, a hard-vacuum cathode ray tube (CRT) for the display of television pictures, and the following year he patented a camera tube with a mosaic of photoelectric elements and gave a demonstration of still-picture TV. In 1926 he was awarded a PhD by the University of Pittsburgh and in 1928 he was granted a patent for a colour TV system.In 1929 he embarked on a tour of Europe to study TV developments; on his return he joined the Radio Corporation of America (RCA) as Director of the Electronics Research Group, first at Camden and then Princeton, New Jersey. Securing a budget to develop an improved CRT picture tube, he soon produced a kinescope with a hard vacuum, an indirectly heated cathode, a signal-modulation grid and electrostatic focusing. In 1933 an improved iconoscope camera tube was produced, and under his direction RCA went on to produce other improved types of camera tube, including the image iconoscope, the orthicon and image orthicon and the vidicon. The secondary-emission effect used in many of these tubes was also used in a scintillation radiation counter. In 1941 he was responsible for the development of the first industrial electron microscope, but for most of the Second World War he directed work concerned with radar, aircraft fire-control and TV-guided missiles.After the war he worked for a time on high-speed memories and medical electronics, becoming Vice-President and Technical Consultant in 1947. He "retired" from RCA and was made an honorary vice-president in 1954, but he retained an office and continued to work there almost up until his death; he also served as Director of the Rockefeller Institute for Medical Research from 1954 until 1962.[br]Principal Honours and DistinctionsZworykin received some twenty-seven awards and honours for his contributions to television engineering and medical electronics, including the Institution of Electrical Engineers Faraday Medal 1965; US Medal of Science 1966; and the US National Hall of Fame 1977.Bibliography29 December 1923, US patent no. 2,141, 059 (the original iconoscope patent; finally granted in December 1938!).13 July 1925, US patent no. 1,691, 324 (colour television system).1930, with D.E.Wilson, Photocells and Their Applications, New York: Wiley. 1934, "The iconoscope. A modern version of the electric eye". Proceedings of theInstitute of Radio Engineers 22:16.1946, Electron Optics and the Electron Microscope.1940, with G.A.Morton, Television; revised 1954.1949, with E.G.Ramberg, Photoelectricity and Its Applications. 1958, Television in Science and Industry.Further ReadingJ.H.Udelson, 1982, The Great Television Race: History of the Television Industry 1925– 41: University of Alabama Press.KFBiographical history of technology > Zworykin, Vladimir Kosma
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15 Alexanderson, Ernst Frederik Werner
[br]b. 25 January 1878 Uppsala, Swedend. ? May 1975 Schenectady, New York, USA[br]Swedish-American electrical engineer and prolific radio and television inventor responsible for developing a high-frequency alternator for generating radio waves.[br]After education in Sweden at the High School and University of Lund and the Royal Institution of Technology in Stockholm, Alexanderson took a postgraduate course at the Berlin-Charlottenburg Engineering College. In 1901 he began work for the Swedish C \& C Electric Company, joining the General Electric Company, Schenectady, New York, the following year. There, in 1906, together with Fessenden, he developed a series of high-power, high-frequency alternators, which had a dramatic effect on radio communications and resulted in the first real radio broadcast. His early interest in television led to working demonstrations in his own home in 1925 and at the General Electric laboratories in 1927, and to the first public demonstration of large-screen (7 ft (2.13 m) diagonal) projection TV in 1930. Another invention of significance was the "amplidyne", a sensitive manufacturing-control system subsequently used during the Second World War for controlling anti-aircraft guns. He also contributed to developments in electric propulsion and radio aerials.He retired from General Electric in 1948, but continued television research as a consultant for the Radio Corporation of America (RCA), filing his 321st patent in 1955.[br]Principal Honours and DistinctionsInstitution of Radio Engineers Medal of Honour 1919. President, IERE 1921. Edison Medal 1944.BibliographyPublications relating to his work in the early days of radio include: "Magnetic properties of iron at frequencies up to 200,000 cycles", Transactions of the American Institute of Electrical Engineers (1911) 30: 2,443."Transatlantic radio communication", Transactions of the American Institute of ElectricalEngineers (1919) 38:1,269.The amplidyne is described in E.Alexanderson, M.Edwards and K.Boura, 1940, "Dynamo-electric amplifier for power control", Transactions of the AmericanInstitution of Electrical Engineers 59:937.Further ReadingE.Hawkes, 1927, Pioneers of Wireless, Methuen (provides an account of Alexanderson's work on radio).J.H.Udelson, 1982, The Great Television Race: A History of the American Television Industry 1925–1941, University of Alabama Press (provides further details of his contribution to the development of television).KFBiographical history of technology > Alexanderson, Ernst Frederik Werner
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16 Council
-
17 Council
в соч.- Digital Audio-Video Interactive Council
- Federal Networking Council
- Joint Electron Tube Engineering Council
- Joint Electronic Devices Engineering Council
- Multimedia PC Marketing Council
- Radio Industry CouncilThe New English-Russian Dictionary of Radio-electronics > Council
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18 Burks, Arthur Walter
SUBJECT AREA: Electronics and information technology[br]b. 13 October 1915 Duluth, Minnesota, USA[br]American engineer involved in the development of the ENIAC and Whirlwind computers.[br]After obtaining his AB degree from De Pere University, Wisconsin (1937), and his AM and PhD from the University of Michigan (1938 and 1941, respectively), Burks carried out research at the Moore School of Engineering, University of Pennsylvania, during the Second World War, and at the same time taught philosophy in another department. There, with Herman Goldstine, he was involved in the construction of ENIAC (the Electronic Numerical Integrator and Computer).In 1946 he took a post as Assistant Professor of Engineering at Michigan University, and subsequently became Associate Professor (1948) and Full Professor (1954). Between 1946 and 1948 he was also associated with the computer activities of John von Neumann at the Institute of Advanced Studies, Princeton, and was involved in the development of the Whirlwind I computer (the first stored-program computer) by Jay Forrester at the Massachusetts Institute of Technology. From 1948 until 1954 he was a consultant for the Burroughs Corporation and also contributed to the Oak Ridge computer ORACLE. He was Chairman of the Michigan University Department of Communications Science in 1967–71 and at various times was Visiting Professor at Harvard University and the universities of Illinois and Stanford. In 1975 he became Editor of the Journal of Computer and System Sciences.[br]Bibliography1946. "Super electronic computing machine", Electronics Industry 62.1947. "Electronic computing circuits of the ENIAC", Proceedings of the Institute of Radio Engineers 35:756.1980, "From ENIAC to the stored program computer. Two revolutions in computing", in N.Metropolis, J.Hewlett \& G.-C.Rota (eds), A History of Computing in the 20th Century, London: Academic Press.Further ReadingJ.W.Corlada, 1987, Historical Dictionary of Data Processing (provides further details of Burk's career).KF
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