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81 card
1) карточка (напр. учётная)2) карта; диаграмма3) формуляр; ярлык4) перфорационная карта, перфокарта- job card -
82 department
1) структурное подразделение, административный орган (министерство, департамент, управление, отдел)2) секция (в торговом предприятии)3) функциональный отдел (напр. кадров, финансов)4) факультет (университета) -
83 report
1) доклад; отчёт; сообщение || докладывать; отчитываться2) бирж. репорт, репортная сделка3) акт; отзыв -
84 clock
часы@astronomical clockастрономические часы@atomic clockатомные часы@crystal clockкварцевые часы@driving clock1.часовой механизм телескопа 2.регулятор хода часового механизма@gravity clockсм. gravity-driven clock@gravity-driven clock1.гиревые часы 2.гиревой часовой механизм@gravity-powered clockсм. gravity-driven clock@gravity-powered driving clockгиревой часовой механизм@free pendulum clockмаятниковые часы@observatory clockастрономические часы@pendulum clockмаятниковые часы@quartz(-crystal) clockкварцевые часы@sidereal clockзвездные часы@stop clockсекундомер@timekeeping clockчасы для хранения времени@time-marking clockчасы для отметок времени@time service clockчасы службы времени@universal time clockчасы, идущие по Всемирному времени@ -
85 time study
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86 report
1. n1) доклад; сообщение; отчет2) отзыв, заключение3) акт4) отсрочка расчета по фондовой сделке, контанго, репорт
- acceptance report
- acceptance test report
- accountant's report
- accounting report
- action report
- actuarial report
- advanced outstanding report
- adverse auditor's report
- annual report
- annual financial report
- appraisal report
- auditor's report
- average rate report
- base rate change history report
- bills outstanding report
- board of directors report
- branch balance report
- brokerage report
- budgetary control report
- bullish report
- business report
- call report
- cash report
- chairman's report
- claim report
- commercial report
- company report
- confidential report
- confirmed/unconfirmed deals report
- conflicting report
- consolidated report
- contract funds status report
- contract status report
- corporate report
- corporate profit report
- cost information report
- cost reduction report
- credit report
- credit agency report
- credits by customer report
- current industrial reports
- customs report
- customs surveyor report
- daily report
- daily cash report
- daily movement report
- damage report
- delinquency report
- direct report
- director's report
- directors' report
- draft report
- due diligence report
- earnings report
- end-of-day report
- establishment report
- evaluation report
- examination report
- examiners' report
- exchange report
- exchange rate warning report
- expense report
- expert's report
- factory inspection report
- failure report
- fault detection report
- feasibility report
- final report
- financial report
- fiscal report
- full report
- government report
- group report
- group limit report
- guarantee test report
- idle time report
- inaccurate report
- industry report
- inspection report
- interim report
- internal funding report
- intracompany report
- limit summary report
- liquidity report
- loan and deposit liquidity report
- loan facility usage report
- management report
- manufacturing report
- market report
- maturity deal warning report
- model audit report
- money report
- monthly report
- no instruction warning report
- nostro transfer report
- official report
- operating report
- operational report
- outturn report
- over-the-counter reports
- overlimit report
- past-repayment warning report
- performance report
- production report
- profit and loss report
- progress report
- provisional report
- qualified report
- quality control report
- quality survey report
- quarterly report
- receiving report
- research report
- returned stores report
- routine report
- sales report
- semi-annual report
- shared interest margin report
- shortage report
- situation report
- source and application of funds report
- standard narrative report
- statistical report
- status report
- statutory report
- stock market report
- stock status report
- summary report
- suspect loan report
- technical inspection report
- tentative balance-sheet report
- test report
- timekeeping report
- trade report
- trading activity report
- travel expense report
- travellers' cheque issued report
- trial balance reports
- undrawn commitment report
- yearly report
- report of condition
- report of experts' examination
- report on market conditions
- report on the market situation
- approve a report
- certify a report
- draw up a report
- file an annual report
- file periodical reports
- issue a financial report
- issue a test report
- make a report
- present a report
- submit a report2. v1) сообщать, информировать2) отчитываться3) подчиняться, находиться в подчиненииEnglish-russian dctionary of contemporary Economics > report
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87 get on someone's wick
expr BrE vulg slThe new dictionary of modern spoken language > get on someone's wick
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88 get on smb.'s wick
жарг.взбесить кого-л., вывести кого-л. из себя; действовать кому-л. на нервыThe boss gets on my wick with his everlasting complaints about timekeeping. And he thinks nothing of rolling up to the office at ten o'clock himself. (ODCIE) — Босс действует мне на нервы: все время жалуется, что все мы то и дело опаздываем. А сам каждый день является на работу в десять.
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89 Bain, Alexander
[br]b. October 1810 Watten, Scotlandd. 2 January 1877 Kirkintilloch, Scotland[br]Scottish inventor and entrepreneur who laid the foundations of electrical horology and designed an electromagnetic means of transmitting images (facsimile).[br]Alexander Bain was born into a crofting family in a remote part of Scotland. He was apprenticed to a watchmaker in Wick and during that time he was strongly influenced by a lecture on "Heat, sound and electricity" that he heard in nearby Thurso. This lecture induced him to take up a position in Clerkenwell in London, working as a journeyman clockmaker, where he was able to further his knowledge of electricity by attending lectures at the Adelaide Gallery and the Polytechnic Institution. His thoughts naturally turned to the application of electricity to clockmaking, and despite a bitter dispute with Charles Wheatstone over priority he was granted the first British patent for an electric clock. This patent, taken out on 11 January 1841, described a mechanism for an electric clock, in which an oscillating component of the clock operated a mechanical switch that initiated an electromagnetic pulse to maintain the regular, periodic motion. This principle was used in his master clock, produced in 1845. On 12 December of the same year, he patented a means of using electricity to control the operation of steam railway engines via a steam-valve. His earliest patent was particularly far-sighted and anticipated most of the developments in electrical horology that occurred during the nineteenth century. He proposed the use of electricity not only to drive clocks but also to distribute time over a distance by correcting the hands of mechanical clocks, synchronizing pendulums and using slave dials (here he was anticipated by Steinheil). However, he was less successful in putting these ideas into practice, and his electric clocks proved to be unreliable. Early electric clocks had two weaknesses: the battery; and the switching mechanism that fed the current to the electromagnets. Bain's earth battery, patented in 1843, overcame the first defect by providing a reasonably constant current to drive his clocks, but unlike Hipp he failed to produce a reliable switch.The application of Bain's numerous patents for electric telegraphy was more successful, and he derived most of his income from these. They included a patent of 12 December 1843 for a form of fax machine, a chemical telegraph that could be used for the transmission of text and of images (facsimile). At the receiver, signals were passed through a moving band of paper impregnated with a solution of ammonium nitrate and potassium ferrocyanide. For text, Morse code signals were used, and because the system could respond to signals faster than those generated by hand, perforated paper tape was used to transmit the messages; in a trial between Paris and Lille, 282 words were transmitted in less than one minute. In 1865 the Abbé Caselli, a French engineer, introduced a commercial fax service between Paris and Lyons, based on Bain's device. Bain also used the idea of perforated tape to operate musical wind instruments automatically. Bain squandered a great deal of money on litigation, initially with Wheatstone and then with Morse in the USA. Although his inventions were acknowledged, Bain appears to have received no honours, but when towards the end of his life he fell upon hard times, influential persons in 1873 secured for him a Civil List Pension of £80 per annum and the Royal Society gave him £150.[br]Bibliography1841, British patent no. 8,783; 1843, British patent no. 9,745; 1845, British patent no.10,838; 1847, British patent no. 11,584; 1852, British patent no. 14,146 (all for electric clocks).1852, A Short History of the Electric Clocks with Explanation of Their Principles andMechanism and Instruction for Their Management and Regulation, London; reprinted 1973, introd. W.Hackmann, London: Turner \& Devereux (as the title implies, this pamphlet was probably intended for the purchasers of his clocks).Further ReadingThe best account of Bain's life and work is in papers by C.A.Aked in Antiquarian Horology: "Electricity, magnetism and clocks" (1971) 7: 398–415; "Alexander Bain, the father of electrical horology" (1974) 9:51–63; "An early electric turret clock" (1975) 7:428–42. These papers were reprinted together (1976) in A Conspectus of Electrical Timekeeping, Monograph No. 12, Antiquarian Horological Society: Tilehurst.J.Finlaison, 1834, An Account of Some Remarkable Applications of the Electric Fluid to the Useful Arts by Alexander Bain, London (a contemporary account between Wheatstone and Bain over the invention of the electric clock).J.Munro, 1891, Heroes of the Telegraph, Religious Tract Society.J.Malster \& M.J.Bowden, 1976, "Facsimile. A Review", Radio \&Electronic Engineer 46:55.D.J.Weaver, 1982, Electrical Clocks and Watches, Newnes.T.Hunkin, 1993, "Just give me the fax", New Scientist (13 February):33–7 (provides details of Bain's and later fax devices).See also: Bakewell, Frederick C.DV / KF -
90 Burgi, Jost
SUBJECT AREA: Horology[br]b. 28 February 1552 Lichtensteig, Switzerlandd. 31 January 1632 Kassel, Germany[br]Swiss clockmaker and mathematician who invented the remontoire and the cross-beat escapement, also responsible for the use of exponential notation and the calculation of tables of anti-logarithms.[br]Burgi entered the service of Duke William IV of Hesse in 1579 as Court Clockmaker, although he also assisted William with his astronomical observations. In 1584 he invented the cross-beat escapement which increased the accuracy of spring-driven clocks by two orders of magnitude. During the last years of the century he also worked on the development of geometrical and astronomical instruments for the Royal Observatory at Kassel.On the death of Duke Wilhelm in 1603, and with news of his skills having reached the Holy Roman Emperor Rudolph II, in 1604 he went to Prague to become Imperial Watchmaker and to assist in the creation of a centre of scientific activity, subsequently becoming Assistant to the German astronomer, Johannes Kepler. No doubt this association led to an interest in mathematics and he made significant contributions to the concept of decimal fractions and the use of exponential notation, i.e. the use of a raised number to indicate powers of another number. It is likely that he was developing the idea of logarithms at the same time (or possibly even before) Napier, for in 1620 he made his greatest contribution to mathematics, science and, eventually, engineering, namely the publication of tables of anti-logarithms.At Prague he continued the series of accurate clocks and instruments for astronomical measurements that he had begun to produce at Kassel. At that period clocks were very poor timekeepers since the controller, the foliot or balance, had no natural period of oscillation and was consequently dependent on the driving force. Although the force of the driving weight was constant, irregularities occurred during the transmission of the power through the train as a result of the poor shape and quality of the gearing. Burgi attempted to overcome this directly by superb craftsmanship and indirectly by using a remontoire. This device was wound at regular intervals by the main driving force and fed the power directly to the escape wheel, which impulsed the foliot. He also introduced the crossbeat escapement (a variation on the verge), which consisted of two coupled foliots that swung in opposition to each other. According to contemporary evidence his clocks produced a remarkable improvement in timekeeping, being accurate to within a minute a day. This improvement was probably a result of the use of a remontoire and the high quality of the workmanship rather than a result of the cross-beat escapement, which did not have a natural period of oscillation.Burgi or Prague clocks, as they were known, were produced by very few other makers and were supplanted shortly afterwards by the intro-duction of the pendulum clock. Burgi also produced superb clockwork-driven celestial globes.[br]Principal Honours and DistinctionsEnnobled 1611.BibliographyBurgi only published one book, and that was concerned with mathematics.Further ReadingL.von Mackensen, 1979, Die erste Sternwarte Europas mit ihren Instrumenten and Uhren—400 Jahre Jost Burgi in Kassel, Munich.K.Maurice and O.Mayr (eds), 1980, The Clockwork Universe, Washington, DC, pp. 87– 102.H.A.Lloyd, 1958, Some Outstanding Clocks Over 700 Years, 1250–1950, London. E.T.Bell, 1937, Men of Mathematics, London: Victor Gollancz.See also: Briggs, HenryKF / DV -
91 Graham, George
SUBJECT AREA: Horology[br]b. c.1674 Cumberland, Englandd. 16 November 1751 London, England[br]English watch-and clockmaker who invented the cylinder escapement for watches, the first successful dead-beat escapement for clocks and the mercury compensation pendulum.[br]Graham's father died soon after his birth, so he was raised by his brother. In 1688 he was apprenticed to the London clockmaker Henry Aske, and in 1695 he gained his freedom. He was employed as a journeyman by Tompion in 1696 and later married his niece. In 1711 he formed a partnership with Tompion and effectively ran the business in Tompion's declining years; he took over the business after Tompion died in 1713. In addition to his horological interests he also made scientific instruments, specializing in those for astronomical use. As a person, he was well respected and appears to have lived up to the epithet "Honest George Graham". He befriended John Harrison when he first went to London and lent him money to further his researches at a time when they might have conflicted with his own interests.The two common forms of escapement in use in Graham's time, the anchor escapement for clocks and the verge escapement for watches, shared the same weakness: they interfered severely with the free oscillation of the pendulum and the balance, and thus adversely affected the timekeeping. Tompion's two frictional rest escapements, the dead-beat for clocks and the horizontal for watches, had provided a partial solution by eliminating recoil (the momentary reversal of the motion of the timepiece), but they had not been successful in practice. Around 1720 Graham produced his own much improved version of the dead-beat escapement which became a standard feature of regulator clocks, at least in Britain, until its supremacy was challenged at the end of the nineteenth century by the superior accuracy of the Riefler clock. Another feature of the regulator clock owed to Graham was the mercury compensation pendulum, which he invented in 1722 and published four years later. The bob of this pendulum contained mercury, the surface of which rose or fell with changes in temperature, compensating for the concomitant variation in the length of the pendulum rod. Graham devised his mercury pendulum after he had failed to achieve compensation by means of the difference in expansion between various metals. He then turned his attention to improving Tompion's horizontal escapement, and by 1725 the cylinder escapement existed in what was virtually its final form. From the following year he fitted this escapement to all his watches, and it was also used extensively by London makers for their precision watches. It proved to be somewhat lacking in durability, but this problem was overcome later in the century by using a ruby cylinder, notably by Abraham Louis Breguet. It was revived, in a cheaper form, by the Swiss and the French in the nineteenth century and was produced in vast quantities.[br]Principal Honours and DistinctionsFRS 1720. Master of the Clockmakers' Company 1722.BibliographyGraham contributed many papers to the Philosophical Transactions of the Royal Society, in particular "A contrivance to avoid the irregularities in a clock's motion occasion'd by the action of heat and cold upon the rod of the pendulum" (1726) 34:40–4.Further ReadingBritten's Watch \& Clock Maker's Handbook Dictionary and Guide, 1978, rev. Richard Good, 16th edn, London, pp. 81, 84, 232 (for a technical description of the dead-beat and cylinder escapements and the mercury compensation pendulum).A.J.Turner, 1972, "The introduction of the dead-beat escapement: a new document", Antiquarian Horology 8:71.E.A.Battison, 1972, biography, Biographical Dictionary of Science, ed. C.C.Gillespie, Vol. V, New York, 490–2 (contains a résumé of Graham's non-horological activities).DV -
92 Harrison, John
[br]b. 24 March 1693 Foulby, Yorkshire, Englandd. 24 March 1776 London, England[br]English horologist who constructed the first timekeeper of sufficient accuracy to determine longitude at sea and invented the gridiron pendulum for temperature compensation.[br]John Harrison was the son of a carpenter and was brought up to that trade. He was largely self-taught and learned mechanics from a copy of Nicholas Saunderson's lectures that had been lent to him. With the assistance of his younger brother, James, he built a series of unconventional clocks, mainly of wood. He was always concerned to reduce friction, without using oil, and this influenced the design of his "grasshopper" escapement. He also invented the "gridiron" compensation pendulum, which depended on the differential expansion of brass and steel. The excellent performance of his regulator clocks, which incorporated these devices, convinced him that they could also be used in a sea dock to compete for the longitude prize. In 1714 the Government had offered a prize of £20,000 for a method of determining longitude at sea to within half a degree after a voyage to the West Indies. In theory the longitude could be found by carrying an accurate timepiece that would indicate the time at a known longitude, but the requirements of the Act were very exacting. The timepiece would have to have a cumulative error of no more than two minutes after a voyage lasting six weeks.In 1730 Harrison went to London with his proposal for a sea clock, supported by examples of his grasshopper escapement and his gridiron pendulum. His proposal received sufficient encouragement and financial support, from George Graham and others, to enable him to return to Barrow and construct his first sea clock, which he completed five years later. This was a large and complicated machine that was made out of brass but retained the wooden wheelwork and the grasshopper escapement of the regulator clocks. The two balances were interlinked to counteract the rolling of the vessel and were controlled by helical springs operating in tension. It was the first timepiece with a balance to have temperature compensation. The effect of temperature change on the timekeeping of a balance is more pronounced than it is for a pendulum, as two effects are involved: the change in the size of the balance; and the change in the elasticity of the balance spring. Harrison compensated for both effects by using a gridiron arrangement to alter the tension in the springs. This timekeeper performed creditably when it was tested on a voyage to Lisbon, and the Board of Longitude agreed to finance improved models. Harrison's second timekeeper dispensed with the use of wood and had the added refinement of a remontoire, but even before it was tested he had embarked on a third machine. The balance of this machine was controlled by a spiral spring whose effective length was altered by a bimetallic strip to compensate for changes in temperature. In 1753 Harrison commissioned a London watchmaker, John Jefferys, to make a watch for his own personal use, with a similar form of temperature compensation and a modified verge escapement that was intended to compensate for the lack of isochronism of the balance spring. The time-keeping of this watch was surprisingly good and Harrison proceeded to build a larger and more sophisticated version, with a remontoire. This timekeeper was completed in 1759 and its performance was so remarkable that Harrison decided to enter it for the longitude prize in place of his third machine. It was tested on two voyages to the West Indies and on both occasions it met the requirements of the Act, but the Board of Longitude withheld half the prize money until they had proof that the timekeeper could be duplicated. Copies were made by Harrison and by Larcum Kendall, but the Board still continued to prevaricate and Harrison received the full amount of the prize in 1773 only after George III had intervened on his behalf.Although Harrison had shown that it was possible to construct a timepiece of sufficient accuracy to determine longitude at sea, his solution was too complex and costly to be produced in quantity. It had, for example, taken Larcum Kendall two years to produce his copy of Harrison's fourth timekeeper, but Harrison had overcome the psychological barrier and opened the door for others to produce chronometers in quantity at an affordable price. This was achieved before the end of the century by Arnold and Earnshaw, but they used an entirely different design that owed more to Le Roy than it did to Harrison and which only retained Harrison's maintaining power.[br]Principal Honours and DistinctionsRoyal Society Copley Medal 1749.Bibliography1767, The Principles of Mr Harrison's Time-keeper, with Plates of the Same, London. 1767, Remarks on a Pamphlet Lately Published by the Rev. Mr Maskelyne Under theAuthority of the Board of Longitude, London.1775, A Description Concerning Such Mechanisms as Will Afford a Nice or True Mensuration of Time, London.Further ReadingR.T.Gould, 1923, The Marine Chronometer: Its History and Development, London; reprinted 1960, Holland Press.—1978, John Harrison and His Timekeepers, 4th edn, London: National Maritime Museum.H.Quill, 1966, John Harrison, the Man who Found Longitude, London. A.G.Randall, 1989, "The technology of John Harrison's portable timekeepers", Antiquarian Horology 18:145–60, 261–77.J.Betts, 1993, John Harrison London (a good short account of Harrison's work). S.Smiles, 1905, Men of Invention and Industry; London: John Murray, Chapter III. Dictionary of National Biography, Vol. IX, pp. 35–6.DV -
93 Richard of Wallingford, Abbot
SUBJECT AREA: Horology[br]b. 1291/2 Wallingford, Englandd. 23 May 1336 St Albans, Hertfordshire, England[br]English cleric, mathematician and astronomer who produced the earliest mechanical clock of which there is detailed knowledge.[br]Richard, the son of a blacksmith, was adopted by the Prior of Wallingford when his father died and educated at Oxford. He then joined the monastery at St Albans and was ordained as a priest in 1317. After a further period at Oxford studying mathematics and astronomy he returned to St Albans as Abbot in 1327. Shortly after he had been elected Abbot he started work on a very elaborate astronomical clock. The escapement and the striking mechanism of this clock were unusual. The former was a variation on the verge escapement, and the hour striking (up to twenty-four) was controlled by a series of pins laid out in a helical pattern on a drum. However, timekeeping was of secondary importance as the main purpose of the clock was to show the motion of the Sun, Moon and planets (the details of the planet mechanism are lost) and to demonstrate eclipses. This was achieved in a very precise manner by a series of ingenious mechanisms, such as the elliptical wheel that was used to derive the variable motion of the sun.Richard died of leprosy, which he had contracted during a visit to obtain papal confirmation of his appointment, and the clock was completed after his death. The last recorded reference to it was made by John Leyland, shortly before the dissolution of the monasteries. It is now known only from incomplete manuscript copies of Richard's treatise. A modern reconstruction has been made based upon J.D.North's interpretation of the manuscript.[br]BibliographyFor the drafts of Richard's Treatise on the Clock, with translation and commentary, see J.D.North, 1976, Richard of Wallingford, 3 vols, Oxford.Further ReadingSee J.D.North's definitive work above: for biographical information see Vol. 2, pp. 1–16. Most of the shorter accounts appeared before the publication of North's treatise and are therefore of more limited use.G.White, 1978, "Evolution of the epicyclic gear—part 2", Chartered Mechanical Engineer (April): 85–8 (an account of Richard's use of epicyclic gearing).DVBiographical history of technology > Richard of Wallingford, Abbot
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94 Shortt, William Hamilton
SUBJECT AREA: Horology[br]b. 28 September 1881d. 4 February 1971[br]British railway engineer and amateur horologist who designed the first successful free-pendulum clock.[br]Shortt entered the Engineering Department of the London and South Western Railway as an engineering cadet in 1902, remaining with the company and its successors until he retired in 1946. He became interested in precision horology in 1908, when he designed an instrument for recording the speed of trains; this led to a long and fruitful collaboration with Frank HopeJones, the proprietor of the Synchronome Company. This association culminated in the installation of a free-pendulum clock, with an accuracy of the order of one second per year, at Edinburgh Observatory in 1921. The clock's performance was far better than that of existing clocks, such as the Riefler, and a slightly modified version was produced commercially by the Synchronome Company. These clocks provided the time standard at Greenwich and many other observatories and scientific institutions across the world until they were supplanted by the quartz clock.The period of a pendulum is constant if it swings freely with a constant amplitude in a vacuum. However, this ideal state cannot be achieved in a clock because the pendulum must be impulsed to maintain its amplitude and the swings have to be counted to indicate time. The free-pendulum clock is an attempt to approach this ideal as closely as possible. In 1898 R.J. Rudd used a slave clock, synchronized with a free pendulum, to time the impulses delivered to the free pendulum. This clock was not successful, but it provided the inspiration for Shortt's clock, which operates on the same principle. The Shortt clock used a standard Synchronome electric clock as the slave, and its pendulum was kept in step with the free pendulum by means of the "hit and miss" synchronizer that Shortt had patented in 1921. This allowed the pendulum to swing freely (in a vacuum), apart from the fraction of a second in which it received an impulse each half-minute.[br]Principal Honours and DistinctionsMaster of the Clockmakers' Company 1950. British Horological Society Gold Medal 1931. Clockmakers' Company Tompion Medal 1954. Franklin Institute John Price Wetherill Silver Medal.Bibliography1929, "Some experimental mechanisms, mechanical and otherwise, for the maintenance of vibration of a pendulum", Horological Journal 71:224–5.Further ReadingObituary, 1971, Proceedings of the Institution of Civil Engineers 56:396–7.F.Hope-Jones, 1949, Electrical Timekeeping, 2nd edn, London (a detailed but not entirely impartial account of the development of the free-pendulum clock).See also: Marrison, Warren AlvinDVBiographical history of technology > Shortt, William Hamilton
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95 RTC
- часы реального времени
- устройство для отсчета текущего времени
- регулирование времени пребывания
- региональный центр подготовки
- концентратор удаленных терминалов
- генератор импульсов истинного времени
генератор импульсов истинного времени
—
[Я.Н.Лугинский, М.С.Фези-Жилинская, Ю.С.Кабиров. Англо-русский словарь по электротехнике и электроэнергетике, Москва, 1999 г.]Тематики
- электротехника, основные понятия
EN
концентратор удаленных терминалов
—
[Е.С.Алексеев, А.А.Мячев. Англо-русский толковый словарь по системотехнике ЭВМ. Москва 1993]Тематики
EN
региональный центр подготовки
(напр. специалистов для АЭС)
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
регулирование времени пребывания
(напр. тепловыделяющего элемента в активной зоне ядерного реактора, частиц угля в зоне горения топки котла и др.)
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
устройство для отсчета текущего времени
внутренние часы
Прибор для отсчета текущего времени, являющийся частью конструкции СИ, используемый при применении методов измерений показателей КЭ, установленных в настоящем стандарте.
Примечание. Взаимосвязь между текущим временем СИ и временем "Национальной шкалы координированного времени Российской Федерации UTC (SU)" (см. 3.2) установлена в 4.6.
[ ГОСТ Р 51317.4.30-2008 (МЭК 61000-4-30:2008)]EN
Real-Time Clock
RTC
local timekeeping device used for implementing certain methods in this standard.
NOTE The relationship between the real-time clock and UTC is defined in 4.6.
[IEC 61000-4-30, ed. 2.0 (2008-10)]FR
Horloge Temps Réel
RTC
système d’horloge locale utilise pour implémenter certaines méthodes dans cette norme
NOTE La relation entre l’horloge temps réel et le temps UTC est défini en 4.6
[IEC 61000-4-30, ed. 2.0 (2008-10)]Тематики
- измерения неэлектр. величин прочие
Синонимы
EN
FR
часы реального времени
Микросхема, которая сообщает операционной системе отсчеты времени.
[ http://www.morepc.ru/dict/]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > RTC
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96 Real-Time Clock
устройство для отсчета текущего времени
внутренние часы
Прибор для отсчета текущего времени, являющийся частью конструкции СИ, используемый при применении методов измерений показателей КЭ, установленных в настоящем стандарте.
Примечание. Взаимосвязь между текущим временем СИ и временем "Национальной шкалы координированного времени Российской Федерации UTC (SU)" (см. 3.2) установлена в 4.6.
[ ГОСТ Р 51317.4.30-2008 (МЭК 61000-4-30:2008)]EN
Real-Time Clock
RTC
local timekeeping device used for implementing certain methods in this standard.
NOTE The relationship between the real-time clock and UTC is defined in 4.6.
[IEC 61000-4-30, ed. 2.0 (2008-10)]FR
Horloge Temps Réel
RTC
système d’horloge locale utilise pour implémenter certaines méthodes dans cette norme
NOTE La relation entre l’horloge temps réel et le temps UTC est défini en 4.6
[IEC 61000-4-30, ed. 2.0 (2008-10)]Тематики
- измерения неэлектр. величин прочие
Синонимы
EN
FR
часы реального времени
Микросхема, которая сообщает операционной системе отсчеты времени.
[ http://www.morepc.ru/dict/]Тематики
EN
Англо-русский словарь нормативно-технической терминологии > Real-Time Clock
См. также в других словарях:
timekeeping — UK US (also time keeping) /ˈtaɪmˌkiːpɪŋ/ noun [U] HR ► how good or bad someone is at arriving at work, at meetings, etc. at the agreed time: poor/bad timekeeping »He was threatened with the sack for poor timekeeping. »Analysts looked at… … Financial and business terms
timekeeping — [[t]ta͟ɪmkiːpɪŋ[/t]] 1) N UNCOUNT: poss N, adj N If you talk about someone s timekeeping, you are talking about how good they are at arriving in time for things. [BRIT] I am trying to improve my timekeeping... He was penalized for bad timekeeping … English dictionary
timekeeping — timekeeper ► NOUN 1) a person who records the amount of time taken by a process or activity. 2) a person regarded in terms of their punctuality. 3) a watch or clock regarded in terms of its accuracy. DERIVATIVES timekeeping noun … English terms dictionary
Timekeeping on Mars — Various schemes have been used or proposed to keep track of time and date on the planet Mars independently of Earth time and calendars. Mars has an axial tilt and a rotation period similar to those of Earth. Thus it experiences seasons of spring … Wikipedia
timekeeping — noun see timekeeper … New Collegiate Dictionary
timekeeping — See timekeeper. * * * … Universalium
timekeeping — noun the measurement of time, or determining what the local time is. See Also: timekeeper … Wiktionary
timekeeping — Synonyms and related words: annalistic, calendar making, calendarial, calendric, chronogrammatic, chronographic, chronologic, chronology, chronoscopic, chronoscopy, clock making, clocking, dated, dating, dendrochronology, diaristic, horologic,… … Moby Thesaurus
timekeeping — time|keep|ing [ taım,kipıŋ ] noun uncount 1. ) the process or activity of recording how long something takes 2. ) BRITISH the ability to arrive on time … Usage of the words and phrases in modern English
timekeeping — n. keeping an account of hours worked by employees; act of ensuring that a game lasts the correct amount of time (Sports) … English contemporary dictionary
timekeeping — UK [ˈtaɪmˌkiːpɪŋ] / US [ˈtaɪmˌkɪpɪŋ] noun [uncountable] 1) British the ability to arrive on time 2) the process or activity of recording how long something takes … English dictionary