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1 recorded measurement
Техника: зарегистрированное измерение -
2 reading
reading n1 (skill, pastime) lecture f ; reading is one of my hobbies la lecture est l'un de mes passe-temps ; reading and writing la lecture et l'écriture ; his reading is poor il lit mal ;2 ( books) lecture f ; these texts are recommended/required reading la lecture de ces textes est recommandée/obligatoire ; her novels make light/heavy reading ses romans sont faciles/difficiles à lire ; a woman of wide reading une femme très cultivée ;3 ( recorded measurement) ( on meter) relevé m (on de) ; ( on instrument) indication f (on de) ; to take a reading faire or prendre un relevé ; gas reading relevé du gaz ; barometer reading indication barométrique ;4 ( interpretation) interprétation f (of de) ;5 ( spoken extract) lecture f (from de) ;6 (of will, banns) lecture f ;7 Bible lecture f (from de) ;8 GB Pol lecture f (of de) ; the bill was defeated at its second reading le projet de loi a été rejeté en deuxième lecture. -
3 record
<tech.gen> (outstanding achievement) ■ Rekord m<av> (thin plastic piece carrying recorded sound in grooves) ■ Schallplatte f ; Platte f coll ; Vinyl n coll< docu> ■ Beleg m< jur> ■ Protokoll nvt <av> (sound, video; on any medium) ■ aufzeichnen vt ; aufnehmen vtvt <av> (sound, video; on tape) ■ aufzeichnen vt ; aufnehmen vtvt < docu> (enter, e.g. measurement values in tables) ■ eintragen vt ; aufzeichnen vt ; registrieren vtvt <edp.i&c> ■ schreiben vtvt <i&c> (e.g. statistically) ■ erfassen vt ; aufzeichnen vtvt <i&c> ■ registrieren vt -
4 activity sampling
Opsa work measurement technique used to analyze the activities of employees, machines, or business operations. Activity sampling requires random observations of the amount of time spent on a given activity to be recorded over a fixed period. The results are used to predict the total time spent on each activity and to highlight areas in need of quality, efficiency, or effectiveness improvement. -
5 Hertz, Heinrich Rudolph
[br]b. 22 February 1857 Hamburg, Germanyd. 1 January 1894 Bonn, Germany[br]German physicist who was reputedly the first person to transmit and receive radio waves.[br]At the age of 17 Hertz entered the Gelehrtenschule of the Johaneums in Hamburg, but he left the following year to obtain practical experience for a year with a firm of engineers in Frankfurt am Main. He then spent six months at the Dresden Technical High School, followed by year of military service in Berlin. At this point he decided to switch from engineering to physics, and after a year in Munich he studied physics under Helmholtz at the University of Berlin, gaining his PhD with high honours in 1880. From 1883 to 1885 he was a privat-dozent at Kiel, during which time he studied the electromagnetic theory of James Clerk Maxwell. In 1885 he succeeded to the Chair in Physics at Karlsruhe Technical High School. There, in 1887, he constructed a rudimentary transmitter consisting of two 30 cm (12 in.) rods with metal balls separated by a 7.5 mm (0.3 in.) gap at the inner ends and metallic plates at the outer ends, the whole assembly being mounted at the focus of a large parabolic metal mirror and the two rods being connected to an induction coil. At the other side of his laboratory he placed a 70 cm (27½ in.) diameter wire loop with a similar air gap at the focus of a second metal mirror. When the induction coil was made to create a spark across the transmitter air gap, he found that a spark also occurred at the "receiver". By a series of experiments he was not only able to show that the invisible waves travelled in straight lines and were reflected by the parabolic mirrors, but also that the vibrations could be refracted like visible light and had a similar wavelength. By this first transmission and reception of radio waves he thus confirmed the theoretical predictions made by Maxwell some twenty years earlier. It was probably in his experiments with this apparatus in 1887 that Hertz also observed that the voltage at which a spark was able to jump a gap was significantly reduced by the presence of ultraviolet light. This so-called photoelectric effect was subsequently placed on a theoretical basis by Albert Einstein in 1905. In 1889 he became Professor of Physics at the University of Bonn, where he continued to investigate the nature of electric discharges in gases at low pressure until his death after a long and painful illness. In recognition of his measurement of radio and other waves, the international unit of frequency of an oscillatory wave, the cycle per second, is now universally known as the Hertz.[br]Principal Honours and DistinctionsRoyal Society Rumford Medal 1890.BibliographyMuch of Hertz's work, including his 1890 paper "On the fundamental equations of electrodynamics for bodies at rest", is recorded in three collections of his papers which are available in English translations by D.E.Jones et al., namely Electric Waves (1893), Miscellaneous Papers (1896) and Principles of Mechanics (1899).Further ReadingJ.G.O'Hara and W.Pricha, 1987, Hertz and the Maxwellians, London: Peter Peregrinus. J.Hertz, 1977, Heinrich Hertz, Memoirs, Letters and Diaries, San Francisco: San Francisco Press.R.Appleyard, 1930, Pioneers of Electrical Communication.See also: Heaviside, OliverKFBiographical history of technology > Hertz, Heinrich Rudolph
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6 Reason, Richard Edmund
SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering[br]b. 21 December 1903 Exeter, Devon, Englandd. 20 March 1987 Great Bowden, Leicestershire, England[br]English metrologist who developed instruments for measuring machined-surface roughness.[br]Richard Edmund Reason was educated at Tonbridge School and the Royal College of Science (Imperial College), where he studied under Professor A.F.C.Pollard, Professor of Technical Optics. After graduating in 1925 he joined Taylor, Taylor and Hobson Ltd, Leicester, manufacturers of optical, electrical and scientific instruments, and remained with that firm throughout his career. One of his first contributions was in the development, with E.F.Fincham, of the Fincham Coincidence Optometer. At this time the firm, under William Taylor, was mainly concerned with optical instruments and lens manufacture, but in the 1930s Reason was also engaged in developing means for measuring the roughness of machined surfaces. The need for establishing standards and methods of measurement of surface finish was called for when the subcontracting of aero-engine components became necessary during the Second World War. This led to the development by Reason of an instrument in which a stylus was moved across the surface and the profile recorded electronically. This was called the Talysurf and was first produced in 1941. Further development followed, and from 1947 Reason tackled the problem of measuring roundness, producing the first Talyrond machine in 1949. The technology developed for these instruments was used in the production of others such as the Talymin Comparator and the Talyvel electronic level. Reason was also associated with the development of optical projection systems to measure the profile of parts such as gear teeth, screw threads and turbine blades. He retired in 1968 but continued as a consultant to the company. He served for many years on committees of the British Standards Institution on surface metrology and was a representative of Britain at the International Standards Organization.[br]Principal Honours and DistinctionsOBE 1967. FRS 1971. Honorary DSc University of Birmingham 1969. Honorary DSc Leicester University 1971.Further ReadingD.J.Whitehouse, 1990, Biographical Memoirs of Fellows of the Royal Society 36, London, pp. 437–62 (an illustrated obituary notice listing Reason's eighty-nine British patents, published between 1930 and 1972, and his twenty-one publications, dating from 1937 to 1966).K.J.Hume, 1980, A History of Engineering Metrology, London, 113–21 (contains a shorter account of Reason's work).RTS -
7 Thomson, Elihu
SUBJECT AREA: Electricity[br]b. 29 March 1853 Manchester, Englandd. 13 March 1937 Swampscott, Massachusetts, USA[br]English (naturalized) American electrical engineer and inventor.[br]Thomson accompanied his parents to Philadelphia in 1858; he received his education at the Central High School there, and afterwards remained as a teacher of chemistry. At this time he constructed several dynamos after studying their design, and was invited by the Franklin Institute to give lectures on the subject. After observing an arc-lighting system operating commercially in Paris in 1878, he collaborated with Edwin J. Houston, a senior colleague at the Central High School, in working out the details of such a system. An automatic regulating device was designed which, by altering the position of the brushes on the dynamo commutator, maintained a constant current irrespective of the number of lamps in use. To overcome the problem of commutation at the high voltages necessary to operate up to forty arc lamps in a series circuit, Thomson contrived a centrifugal blower which suppressed sparking. The resulting system was efficient and reliable with low operating costs. Thomson's invention of the motor meter in 1882 was the first of many such instruments for the measurement of electrical energy. In 1886 he invented electric resistance welding using low-voltage alternating current derived from a transformer of his own design. Thomson's work is recorded in his technical papers and in the 700plus patents granted for his inventions.The American Electric Company, founded to exploit the Thomson patents, later became the Thomson-Houston Company, which was destined to be a leader in the electrical manufacturing industry. They entered the field of electric power in 1887, supplying railway equipment and becoming a major innovator of electric railways. Thomson-Houston and Edison General Electric were consolidated to form General Electric in 1892. Thomson remained associated with this company throughout his career.[br]Principal Honours and DistinctionsChevalier and Officier de la Légion d'honneur 1889. American Academy of Arts and Sciences Rumford Medal 1901. American Institute of Electrical Engineers Edison Medal 1909. Royal Society Hughes Medal 1916. Institution of Electrical Engineers Kelvin Medal 1923, Faraday Medal 1927.Bibliography1934, "Some highlights of electrical history", Electrical Engineering 53:758–67 (autobiography).Further ReadingD.O.Woodbury, 1944, Beloved Scientist, New York (a full biography). H.C.Passer, 1953, The Electrical Manufacturers: 1875–1900, Cambridge, Mass, (describes Thomson's industrial contribution).K.T.Compton, 1940, Biographical Memoirs of Elihu Thomson, Washington, DCovides an abridged list of Thomson's papers and patents).GW
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