-
1 part-continuous method
Большой англо-русский и русско-английский словарь > part-continuous method
-
2 part-continuous method
English-Russian dictionary of computer science and programming > part-continuous method
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3 method
1) метод; способ (см. тж. technique 1)2) ООП метод (функция - элемент определения класса (class) в языке Smalltalk, в C++ - см. member function)•- alphageometric method
- Amble's method
- ancestor method
- assembly method
- basic access method
- bibliography method
- bit-level method
- branch and bounds method
- buffering method
- building-block method
- chaining method
- checksum method
- coded pattern method
- conditional delay method
- constraint satisfaction method
- critical path method
- cut-and-try method
- cutset method
- dark-spot method
- data access method
- deductive method
- derivative approximation method
- diagonal method
- diagram method
- dichotomy method
- digital sorting method
- direct access method
- exhaustive method
- false position method
- finished method
- finitary method
- finite difference method
- flip-chip method
- flooding method
- flowgraph method
- frequency analysis method
- gradient method
- graphic access method
- heuristic method
- hierarchical access method
- hit-and-miss method
- Horner's method
- hunt-and-stick method
- index register method
- indexed-sequential access method
- inline-code method
- inverse power method
- inverse transformation method
- issue method
- iteration method
- least-squares method
- left-edge method
- lightweight formal method
- linkage method
- longest route method
- machine method
- maximum-likelihood method
- method of quickest descent
- method of selected point
- method of successive approximations
- Monte-Carlo method
- net method
- Newton's method
- nonrestoring method
- N-pass method
- numerical method
- operational method
- opposition method
- overlay method
- part-continuous method
- partitioned access method
- pencil-and-paper method
- perturbation method
- piezoelectric sensing method
- ping-pong method
- power method
- predictor-corrector method
- programming method
- progressive-part method
- proprietary method
- pure virtual method
- queued access method
- queued indexed sequential access method
- radial exploration method
- random-walk method
- recursive descendant method
- regular falsi method
- resetting method
- resident access method
- review article method
- row-by-row method
- rubber band method
- Runge-Kutta method
- saddle point method
- sampling method
- scale factor method
- scan-set method
- scheduling method
- scissors and paste method
- secant method
- sectioning method
- semigroup method
- sequential access method
- shortcut method
- shortcut multiplication method
- sieve method
- simplex method
- single-path instruction method
- sit-by-me instuction method
- state-space method
- steepest descent method
- step-by-step method
- stroke method
- subject profile method
- symbolic method
- symbolical method
- syntactic method
- synthetic method
- target method
- telecommunication access method
- temporal difference method
- time-domain method
- touch method with ten fingers
- trial-and-error method
- truth table method
- variable separation method
- variable-metric method
- variational method
- variation method
- V-brush method
- vernier pulse-timing method
- virtual method
- wire-wrap method
- zero-deflection methodEnglish-Russian dictionary of computer science and programming > method
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4 поэтапно-непрерывный метод
Большой англо-русский и русско-английский словарь > поэтапно-непрерывный метод
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5 erection
1) строительство; возведение (здания, сооружения)2) установка; сборка; монтаж; монтирование3) монтажный•erection by protrusion and floating — сооружение ( моста) путём продвигания пролётов на плаву
erection from "wheels" — монтаж "с колёс"
erection from transport vehicles — монтаж "с колёс"
erection procedure by partially confining the movement of elements to be mounted — ограниченно-свободный монтаж
- erection of embankment - erection of equipment - erection of formwork - erection of overhead line - erection of structural steel - erection of tower type structures or equipment by sliding its supporting part on rollers - balanced erection - building erection - cantilever erection - correct erection - crane erection - disruption of the schedule of erection works - overall erection - overhang erection - overhead erection - proper erection - rapid erection - schedule of erection works - site erection - span erection - split erection - steel erection - tank erection - trial erection - vertical erectionerection without scaffolding — сборка без подмостей, навесной монтаж ( пролётного строения моста)
* * *монтаж, монтажные работы, возведение ( сооружений)- erection of cranes
- balanced cantilever erection
- bridge erection
- bridge erection on falsework
- building erection
- cantilever erection
- high-rise erection
- steelwork erection
- structural steel erection
- structure erection
- vertical erection -
6 Paul, Lewis
SUBJECT AREA: Textiles[br]d. April 1759 Brook Green, London, England[br]English inventor of hand carding machines and partner with Wyatt in early spinning machines.[br]Lewis Paul, apparently of French Huguenot extraction, was quite young when his father died. His father was Physician to Lord Shaftsbury, who acted as Lewis Paul's guardian. In 1728 Paul made a runaway match with a widow and apparently came into her property when she died a year later. He must have subsequently remarried. In 1732 he invented a pinking machine for making the edges of shrouds out of which he derived some profit.Why Paul went to Birmingham is unknown, but he helped finance some of Wyatt's earlier inventions. Judging by the later patents taken out by Paul, it is probable that he was the one interested in spinning, turning to Wyatt for help in the construction of his spinning machine because he had no mechanical skills. The two men may have been involved in this as early as 1733, although it is more likely that they began this work in 1735. Wyatt went to London to construct a model and in 1736 helped to apply for a patent, which was granted in 1738 in the name of Paul. The patent shows that Paul and Wyatt had a number of different ways of spinning in mind, but contains no drawings of the machines. In one part there is a description of sets of rollers to draw the cotton out more finely that could have been similar to those later used by Richard Arkwright. However, it would seem that Paul and Wyatt followed the other main method described, which might be called spindle drafting, where the fibres are drawn out between the nip of a pair of rollers and the tip of the spindle; this method is unsatisfactory for continuous spinning and results in an uneven yarn.The spinning venture was supported by Thomas Warren, a well-known Birmingham printer, Edward Cave of Gentleman's Magazine, Dr Robert James of fever-powder celebrity, Mrs Desmoulins, and others. Dr Samuel Johnson also took much interest. In 1741 a mill powered by two asses was equipped at the Upper Priory, Birmingham, with, machinery for spinning cotton being constructed by Wyatt. Licences for using the invention were sold to other people including Edward Cave, who established a mill at Northampton, so the enterprise seemed to have great promise. A spinning machine must be supplied with fibres suitably prepared, so carding machines had to be developed. Work was in hand on one in 1740 and in 1748 Paul took out another patent for two types of carding device, possibly prompted by the patent taken out by Daniel Bourn. Both of Paul's devices were worked by hand and the carded fibres were laid onto a strip of paper. The paper and fibres were then rolled up and placed in the spinning machine. In 1757 John Dyer wrote a poem entitled The Fleece, which describes a circular spinning machine of the type depicted in a patent taken out by Paul in 1758. Drawings in this patent show that this method of spinning was different from Arkwright's. Paul endeavoured to have the machine introduced into the Foundling Hospital, but his death in early 1759 stopped all further development. He was buried at Paddington on 30 April that year.[br]Bibliography1738, British patent no. 562 (spinning machine). 1748, British patent no. 636 (carding machine).1758, British patent no. 724 (circular spinning machine).Further ReadingG.J.French, 1859, The Life and Times of Samuel Crompton, London, App. This should be read in conjunction with R.L.Hills, 1970, Power in the Industrial Revolution, Manchester, which shows that the roller drafting system on Paul's later spinning machine worked on the wrong principles.A.P.Wadsworth and J.de L.Mann, 1931, The Cotton Trade and Industrial Lancashire, 1600–1780, Manchester (provides good coverage of the partnership of Paul and Wyatt and the early mills).E.Baines, 1835, History of the Cotton Manufacture in Great Britain, London (this publication must be mentioned, but is now out of date).A.Seymour-Jones, 1921, "The invention of roller drawing in cotton spinning", Transactions of the Newcomen Society 1 (a more modern account).RLH -
7 redundancy
- физическое резервирование
- резервные компоненты
- резервирование источника бесперебойного питания
- резервирование (дублирование)
- резервирование
- избыточность резервирование
- избыточность (кодирования)
- избыточность
- избыток
- долговременная маркировка
избыточность
Существование средств в дополнение к средствам, которые могут быть достаточны функциональному блоку для выполнения требуемой операции, данным для представления информации.
Пример
Примерами избыточности являются дублирование функциональных компонентов и добавление битов четности.
Примечания
1. Избыточность используется в первую очередь для повышения надежности или работоспособности.
2. Определение в МЭС 191-15-01 является менее полным [ИСО/МЭК 2382-14-01-12].
[ ГОСТ Р МЭК 61508-4-2007]Тематики
EN
избыточность (кодирования)
Характеристика кодирования информации, обеспечивающая повышение вероятности безошибочного считывания штрихового кода или передачи информации.
Примечание
В символе штрихового кода высота штрихов обеспечивает вертикальную избыточность, допуская существование множества возможных путей поперечного сканирования символа, из которых теоретически достаточно лишь одного для полного декодирования символа.
[ ГОСТ 30721-2000]
[ ГОСТ Р 51294.3-99]Тематики
EN
DE
FR
избыточность резервирование
Наличие в объекте более чем одного средства, необходимого для выполнения требуемой функции.
[Разработка типовых структурных схем микропроцессорных устройств РЗА на объектах ОАО "ФКС ЕЭС". Пояснительная записка. Новосибирск 2006 г.]EN
redundancy
in an item, the existence of more than one means for performing a required function
[SOURCE: 191-15-01]
[IEV ref 448-12-08]FR
redondance
existence, dans une entité, de plus d'un moyen pour accomplir une fonction requise
[SOURCE: 191-15-01]
[IEV ref 448-12-08]Тематики
EN
DE
- Redundanz, f
FR
резервирование
Применение дополнительных устройств и систем или элементов устройств и систем оборудования для того, чтобы в случае отказа одного из них выполнять требуемую функцию в распоряжении имелось другое устройство (или элемент устройства), готовое выполнять эту функцию.
[ГОСТ ЕН 1070-2003]
резервирование
Способ обеспечения надежности объекта за счет использования дополнительных средств и (или) возможностей, избыточных по отношению к минимально необходимым для выполнения требуемых функции.
[ ГОСТ 27.002-89]
[ОСТ 45.153-99]
[СО 34.21.307-2005]
резервирование
Использование более чем одного устройства или системы, или одной части (узла) устройства или системы для того, чтобы в случае возможного отказа одного из них в ходе выполнения своей функции в распоряжении находился другой, для обеспечения продолжения вышеупомянутой функции.
[ ГОСТ Р МЭК 60204-1-2007]В первый период эксплуатации при постепенном росте нагрузки допускается установка одного трансформатора при условии обеспечения резервирования питания потребителей по сетям низшего напряжения.
Однотрансформаторные подстанции могут быть также применены для питания электроприемников II категории, если обеспечивается требуемая степень резервирования питания по стороне низшего напряжения при отключении трансформатора
[НТП ЭПП-94]Тематики
- безопасность в целом
- безопасность гидротехнических сооружений
- надежность средств электросвязи
- надежность, основные понятия
- электробезопасность
Действия
Сопутствующие термины
- 100 %-ное резервирование
- взаимное резервирование
- объем резервирования
- степень резервирования
EN
DE
FR
резервирование (дублирование)
(ITIL Service Design)
Использование одной или нескольких конфигурационных едениц для обеспечения отказоустойчивости.
[Словарь терминов ITIL версия 1.0, 29 июля 2011 г.]EN
redundancy
(ITIL Service Design)
Use of one or more additional configuration items to provide fault tolerance. The term also has a generic meaning of obsolescence, or no longer needed.
[Словарь терминов ITIL версия 1.0, 29 июля 2011 г.]Тематики
EN
резервирование ИБП
Методы построения системы бесперебойного питания, направленные на обеспечение бесперебойного электроснабжения нагрузки даже при возникновении неисправности ИБП или какой-либо его функциональной части. ИБП может иметь резервированные внутренние блоки (модульный ИБП) или резервирование достигается благодаря использованию нескольких ИБП, включаемых параллельно или последовательно
[ http://www.radistr.ru/misc/document423.phtml с изменениями]EN
redundancy
A method based on using one or more extra backup modules, which enable normal system performance even in case of system failures. For example, redundancy is achieved by feeding a consumer of 1KVA by means of two 1KVA rated UPS systems connected in parallel, hence single unit failure does not affect load performance.
[ http://www.upsonnet.com/UPS-Glossary/]Тематики
Синонимы
EN
резервные компоненты
Резервные компоненты, используемые для обеспечения бесперебойной работы устройства или системы. При выходе из строя основного модуля, его функции автоматически берет на себя резервный.
[ http://www.lexikon.ru/dict/net/index.html]Тематики
EN
физическое резервирование
—
[А.С.Гольдберг. Англо-русский энергетический словарь. 2006 г.]Тематики
EN
3.4 избыточность (redundancy): Наличие средств в дополнение к средствам, которые могут быть достаточны функциональному блоку, для выполнения требуемой операции или данным для представления информации.
ПРИМЕР - Примерами избыточности являются дублирование функциональных компонентов и добавление битов четности.
Источник: ГОСТ Р 53195.4-2010: Безопасность функциональная связанных с безопасностью зданий и сооружений систем. Часть 4. Требования к программному обеспечению оригинал документа
7.1. Резервирование
Redundancy
Способ обеспечения надежности объекта за счет использования дополнительных средств и (или) возможностей, избыточных по отношению к минимально необходимым для выполнения требуемых функции
Источник: ГОСТ 27.002-89: Надежность в технике. Основные понятия. Термины и определения оригинал документа
3.15 резервирование (redundancy): Использование альтернативных (одинаковых или неодинаковых) конструкций, систем и элементов таким образом, чтобы все они могли выполнять требующуюся функцию независимо от эксплуатационного состояния или отказа любого из них.
(Глоссарий МАГАТЭ по вопросам безопасности:2007)
Источник: ГОСТ Р МЭК 61226-2011: Атомные станции. Системы контроля и управления, важные для безопасности. Классификация функций контроля и управления оригинал документа
3.7 резервирование (redundancy): Использование альтернативных (одинаковых или неодинаковых) конструкций, систем или элементов таким образом, чтобы все они могли выполнять требующуюся функцию независимо от эксплуатационного состояния или отказа любого из них.
(МАГАТЭ NS-G-1.3)
Источник: ГОСТ Р МЭК 60709-2011: Атомные станции. Системы контроля и управления, важные для безопасности. Разделение оригинал документа
3.29 резервирование (redundancy): Использование альтернативных (одинаковых или неодинаковых) конструкций, систем или компонентов таким образом, чтобы все они могли выполнять требующуюся функцию независимо от эксплуатационного состояния или выхода из строя любого из них.
[Глоссарий МАГАТЭ NS-G-1.3]
Источник: ГОСТ Р МЭК 60880-2010: Атомные электростанции. Системы контроля и управления, важные для безопасности. Программное обеспечение компьютерных систем, выполняющих функции категории А оригинал документа
3.3.10 избыточность (redundancy): Существование средств в дополнение к средствам, которые могут быть достаточны функциональному блоку для выполнения требуемой операции, данным для представления информации.
ПРИМЕР - Примерами избыточности являются дублирование функциональных компонентов и добавление битов четности.
Примечания
1. Избыточность используется в первую очередь для повышения надежности или работоспособности.
2. Определение в МЭС 191-15-01 является менее полным [ИСО/МЭК 2382-14-01-12].
Источник: ГОСТ Р МЭК 61508-4-2007: Функциональная безопасность систем электрических, электронных, программируемых электронных, связанных с безопасностью. Часть 4. Термины и определения оригинал документа
3.49 резервирование (redundancy): Способ обеспечения надежности объекта за счет использования дополнительных средств и/или возможностей, избыточных по отношению к минимально необходимым для выполнения требуемых функций.
[МАГАТЭ 50-SG-D8]
Источник: ГОСТ Р МЭК 61513-2011: Атомные станции. Системы контроля и управления, важные для безопасности. Общие требования оригинал документа
3.15 резервирование (redundancy): Использование альтернативных (одинаковых или неодинаковых) конструкций, систем и элементов таким образом, чтобы все они могли выполнять требующуюся функцию независимо от эксплуатационного состояния или отказа (выхода из строя) любого из них.
[Глоссарий безопасности МАГАТЭ, Версия 2.0,2006]
Источник: ГОСТ Р МЭК 62385-2012: Атомные станции. Контроль и управление, важные для безопасности. Методы оценки рабочих характеристик измерительных каналов систем безопасности оригинал документа
04.02.27 долговременная маркировка [ permanent marking]: Изображение, полученное с помощью интрузивного или неинтрузивного маркирования, которое должно оставаться различимым, как минимум, в течение установленного срока службы изделия.
Сравнить с терминологической статьей «соединение» по ИСО/МЭК19762-11).
______________
1)Терминологическая статья 04.02.27 не связана с указанной терминологической статьей.
<2>4 Сокращения
ECI интерпретация в расширенном канале [extended channel interpretation]
DPM прямое маркирование изделий [direct part marking]
BWA коррекция ширины штриха [bar width adjustment]
BWC компенсация ширины штриха [barwidth compensation]
CPI число знаков на дюйм [characters per inch]
PCS сигнал контраста печати [print contrast signal]
ORM оптический носитель данных [optically readable medium]
FoV поле обзора [field of view]
Алфавитный указатель терминов на английском языке
(n, k)symbology
04.02.13
add-on symbol
03.02.29
alignment pattern
04.02.07
aperture
02.04.09
auto discrimination
02.04.33
auxiliary character/pattern
03.01.04
background
02.02.05
bar
02.01.05
bar code character
02.01.09
bar code density
03.02.14
barcode master
03.02.19
barcode reader
02.04.05
barcode symbol
02.01.03
bar height
02.01.16
bar-space sequence
02.01.20
barwidth
02.01.17
barwidth adjustment
03.02.21
barwidth compensation
03.02.22
barwidth gain/loss
03.02.23
barwidth increase
03.02.24
barwidth reduction
03.02.25
bearer bar
03.02.11
binary symbology
03.01.10
characters per inch
03.02.15
charge-coupled device
02.04.13
coded character set
02.01.08
column
04.02.11
compaction mode
04.02.15
composite symbol
04.02.14
contact scanner
02.04.07
continuous code
03.01.12
corner marks
03.02.20
data codeword
04.02.18
data region
04.02.17
decodability
02.02.28
decode algorithm
02.02.01
defect
02.02.22
delineator
03.02.30
densitometer
02.02.18
depth of field (1)
02.04.30
depth of field (2)
02.04.31
diffuse reflection
02.02.09
direct part marking
04.02.24
discrete code
03.01.13
dot code
04.02.05
effective aperture
02.04.10
element
02.01.14
erasure
04.02.21
error correction codeword
04.02.19
error correction level
04.02.20
even parity
03.02.08
field of view
02.04.32
film master
03.02.18
finder pattern
04.02.08
fixed beam scanner
02.04.16
fixed parity
03.02.10
fixed pattern
04.02.03
flat-bed scanner
02.04.21
gloss
02.02.13
guard pattern
03.02.04
helium neon laser
02.04.14
integrated artwork
03.02.28
intercharacter gap
03.01.08
intrusive marking
04.02.25
label printing machine
02.04.34
ladder orientation
03.02.05
laser engraver
02.04.35
latch character
02.01.24
linear bar code symbol
03.01.01
magnification factor
03.02.27
matrix symbology
04.02.04
modular symbology
03.01.11
module (1)
02.01.13
module (2)
04.02.06
modulo
03.02.03
moving beam scanner
02.04.15
multi-row symbology
04.02.09
non-intrusive marking
04.02.26
odd parity
03.02.07
omnidirectional
03.01.14
omnidirectional scanner
02.04.20
opacity
02.02.16
optically readable medium
02.01.01
optical throw
02.04.27
orientation
02.04.23
orientation pattern
02.01.22
oscillating mirror scanner
02.04.19
overhead
03.01.03
overprinting
02.04.36
pad character
04.02.22
pad codeword
04.02.23
permanent marking
04.02.27
photometer
02.02.19
picket fence orientation
03.02.06
pitch
02.04.26
pixel
02.04.37
print contrast signal
02.02.20
printability gauge
03.02.26
printability test
02.02.21
print quality
02.02.02
quiet zone
02.01.06
raster
02.04.18
raster scanner
02.04.17
reading angle
02.04.22
reading distance
02.04.29
read rate
02.04.06
redundancy
03.01.05
reference decode algorithm
02.02.26
reference threshold
02.02.27
reflectance
02.02.07
reflectance difference
02.02.11
regular reflection
02.02.08
resolution
02.01.15
row
04.02.10
scanner
02.04.04
scanning window
02.04.28
scan, noun (1)
02.04.01
scan, noun (2)
02.04.03
scan reflectance profile
02.02.17
scan, verb
02.04.02
self-checking
02.01.21
shift character
02.01.23
short read
03.02.12
show through
02.02.12
single line (beam) scanner
02.04.11
skew
02.04.25
slot reader
02.04.12
speck
02.02.24
spectral response
02.02.10
spot
02.02.25
stacked symbology
04.02.12
stop character/pattern
03.01.02
structured append
04.02.16
substitution error
03.02.01
substrate
02.02.06
symbol architecture
02.01.04
symbol aspect ratio
02.01.19
symbol character
02.01.07
symbol check character
03.02.02
symbol density
03.02.16
symbology
02.01.02
symbol width
02.01.18
tilt
02.04.24
transmittance (l)
02.02.14
transmittance (2)
02.02.15
truncation
03.02.13
two-dimensional symbol (1)
04.02.01
two-dimensional symbol (2)
04.02.02
two-width symbology
03.01.09
variable parity encodation
03.02.09
verification
02.02.03
verifier
02.02.04
vertical redundancy
03.01.06
void
02.02.23
wand
02.04.08
wide: narrow ratio
03.01.07
X dimension
02.01.10
Y dimension
02.01.11
Z dimension
02.01.12
zero-suppression
03.02.17
<2>Приложение ДА1)
______________
1)
Источник: ГОСТ Р ИСО/МЭК 19762-2-2011: Информационные технологии. Технологии автоматической идентификации и сбора данных (АИСД). Гармонизированный словарь. Часть 2. Оптические носители данных (ОНД) оригинал документа
Англо-русский словарь нормативно-технической терминологии > redundancy
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8 operation
[ɒpə'reɪʃn] noun1) (causing to work) (of machine) Bedienung, die; (of lever, brake) Betätigung, die; (of factory, mine, etc.) Betrieb, der; (of bus service etc.) Unterhaltung, die2) (way something works) Arbeitsweise, die3) (being operative)come into operation — [Gesetz, Gebühr usw.:] in Kraft treten
be in operation — [Maschine, Gerät usw.:] in Betrieb sein; [Service:] zur Verfügung stehen; [Gesetz:] in Kraft sein
be out of operation — [Maschine, Gerät usw.:] außer Betrieb sein
4) (performance) Tätigkeit, dierepeat the operation — das Ganze [noch einmal] wiederholen
5) (Med.) Operation, diehave an operation [on one's foot] — [am Fuß] operiert werden
6) (Mil.) Einsatz, der* * *1) (an action or process, especially when planned: a rescue operation.) das Unternehmen2) (the process of working: Our plan is now in operation.) der Betrieb3) (the act of surgically cutting a part of the body in order to cure disease: an operation for appendicitis.) die Operation4) ((often in plural) the movement, fighting etc of armies: The general was in command of operations in the north.) der Einsatz* * *op·era·tion[ˌɒpərˈeɪʃən, AM ˌɑ:pəˈreɪ-]nthe \operation of communism requires people to give up their individual identities der Kommunismus kann nur dann funktionieren, wenn die Menschen ihre Eigenständigkeit aufgebenthe \operation of gravity keeps us standing on the ground dank der Schwerkraft bleiben wir auf dem Boden stehenday-to-day [or everyday] \operation gewöhnlicher Betriebsablauf, Geschäftsgang mhours of \operation Geschäftszeiten plby \operation of law kraft Gesetzesdaily/hourly \operation täglicher/stündlicher Betriebthe bus service is in hourly \operation during off-peak times außerhalb der Stoßzeiten fahren die Busse stündlichto come into \operation machines in Gang kommen [o Betrieb genommen werden]; plan, rule, law in Kraft treten, wirksam werdento put sth into \operation machine etw in Betrieb nehmen; regulations etw anwenden; scheme, plan etw in die Tat umsetzenrepairing this old watch is a very delicate \operation das Reparieren dieser alten Uhr ist eine sehr diffizile Angelegenheitto undertake an \operation etwas vornehmen, an eine Sache herangehenhow is the \operation going these days? wie läuft denn der Betrieb jetzt so?the company's \operations in West Africa.. die Geschäfte der Firma in West Afrika...; MIL Operation f, Einsatz mO\operation Desert Storm Operation Wüstensturmrescue \operation Rettungsaktion fsecurity \operation Sicherheitsmaßnahmen pl, Einsatz m von Sicherheitskräftenhumanitarian \operation humanitärer Einsatzto launch an \operation mit einer Aktion beginnento start \operations on sth die Arbeit an etw dat aufnehmenheart/lung \operation Herz-/Lungenoperation fto perform an \operation eine Operation durchführen7. FIN [finanzielle] Transaktionmathematical \operation mathematische Operation, Rechenvorgang m* * *["ɒpə'reISən]n1) (= act of operating as in vi) (of machine, mechanism, system) Funktionieren nt; (of plan) Durchführung f; (of theory) Anwendung f; (= method of functioning) (of machine, organization) Arbeitsweise f; (of system, organ) Funktionsweise f; (of law) Wirkungsweise fto be in operation (machine) — in Betrieb sein; (law) in Kraft sein; (plan) durchgeführt werden
to be out of operation — außer Betrieb sein; ( fig : person ) nicht einsatzfähig sein
to come into operation (machine) — in Gang kommen; (law) in Kraft treten; (plan) zur Anwendung gelangen
2) (= act of operating as in vt) (of machine etc) Bedienung f, Handhabung f; (of small mechanism) Betätigung f; (of business) Betreiben nt, Führen nt; (of system, policy) Anwendung f; (of plan, law) Durchführung f; (of route) Bedienung f; (of bus service etc) Unterhaltung f; (of tours) Veranstaltung fto have a serious/heart operation — sich einer schweren Operation/einer Herzoperation unterziehen
4) (= enterprise) Unternehmen nt, Unternehmung f, Operation f; (= task, stage in undertaking) Arbeitsgang m; (MATH) Rechenvorgang m, Operation fto cease/resume operations — den Geschäftsverkehr einstellen/wieder aufnehmen
* * *on auf akk)by operation of law kraft Gesetzes;come into operation wirksam werden, in Kraft treten;be in operation in Kraft oder wirksam sein3. TECH Betrieb m, Tätigkeit f, Lauf m (einer Maschine etc):in operation in Betrieb;put ( oder set) in (out of) operation in (außer) Betrieb setzen; → academic.ru/60521/ready">ready A 1a) Wirkungs-, Arbeitsweise fb) Arbeits(vor)gang m, Verfahren n, (Arbeits)Prozess m:operation of thinking fig Denkvorgang, -prozess;chemical operation chemischer Prozess;operations scheduling Arbeitsvorbereitung f, zeitliche Arbeitsplanung5. TECH Inbetriebsetzung f, Handhabung f, Bedienung f (einer Maschine etc)6. Arbeit f:building operations Bauarbeiten7. WIRTSCHa) Betrieb m:continuous operation durchgehender (Tag- und Nacht)Betrieb;in operation in Betriebb) Unternehmen n, -nehmung f, Betrieb m:c) Geschäft n8. MATH Operation f, Ausführung f (einer Rechenvorschrift)9. MED Operation f, (chirurgischer) Eingriff:operation for appendicitis Blinddarmoperation;have an operation operiert werden;perform an operation (on sb) (an jemandem) einen (chirurgischen) Eingriff vornehmen;major (minor) operationa) größere (kleinere oder harmlose) Operation,b) umg große Sache, schwere Geburt (Kleinigkeit f)10. MIL Operation f, Einsatz m, Unternehmung f, (Angriffs)Unternehmen n:op. abk1. opera2. operation3. operator4. opposite5. optical opt.6. opus Op.* * *[ɒpə'reɪʃn] noun1) (causing to work) (of machine) Bedienung, die; (of lever, brake) Betätigung, die; (of factory, mine, etc.) Betrieb, der; (of bus service etc.) Unterhaltung, die2) (way something works) Arbeitsweise, diecome into operation — [Gesetz, Gebühr usw.:] in Kraft treten
be in operation — [Maschine, Gerät usw.:] in Betrieb sein; [Service:] zur Verfügung stehen; [Gesetz:] in Kraft sein
be out of operation — [Maschine, Gerät usw.:] außer Betrieb sein
4) (performance) Tätigkeit, dierepeat the operation — das Ganze [noch einmal] wiederholen
5) (Med.) Operation, diehave an operation [on one's foot] — [am Fuß] operiert werden
6) (Mil.) Einsatz, der* * *(surgery) n.Operation (Chirurgie) f. n.Arbeitsablauf m.Arbeitsgang m.Bedienung f.Betrieb -e m.Gang ¨-e m.Operation f.Tätigkeit f.Verfahren n. -
9 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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10 Staite, William Edwards
[br]b. 19 April 1809 Bristol, Englandd. 26 September 1854 Caen, France[br]English inventor who did much to popularize electric lighting in early Victorian England and demonstrated the first self-regulating arc lamp.[br]Before devoting the whole of his attention to the electric light, Staite was a partner in a business of iron merchants and patented a method of obtaining extracts and essences. From 1834 he attempted to produce a continuous light by electricity. The first public exhibition of Staite's arc lamp incorporating a fixed-rate clockwork mechanism was given in 1847 to the Sunderland Literary and Philosophical Society. He also demonstrated an incandescent lamp with an iridioplatinum filament. Sir Joseph Wilson Swan recorded that it was attending lectures by Staite in Sunderland, Newcastle and Carlisle that started him on the quest which many years later was to lead to his incandescent lamp.In association with William Petrie (1821–1904), Staite made an important advance in the development of arc lamps by introducing automatic regulation of the carbon rods by way of an electromagnet. This was the first of many self-regulating arc lamps that were invented during the nineteenth century employing this principle. A contributory factor in the success of Staite's lamp was the semi enclosure of the arc in a transparent vessel that reduced the consumption of carbons, a feature not used again until the 1890s. His patents included processes for preparing carbons and the construction of primary cells for arc lighting. An improved lamp used by Staite in a theatrical production at Her Majesty's Theatre, London, in April 1849 may be considered the first commercial success of the electric light in England. In spite of the limitations imposed by the use of primary cells as the only available source of power, serious interest in this system of electric lighting was shown by railway companies and dock authorities. However, after he had developed a satisfactory arc lamp, an end to these early experiments was brought about by Staite's death.[br]BibliographyJuly 1847, British patent no. 1,1783 (electromagnetic regulation of an arc lamp).His manuscript "History of electric light" is in the Institution of Electrical Engineers archives.Further ReadingJ.J.Fahie, 1902, "Staite and Petrie's electric light 1846–1853", Electrical Engineer 30:297–301, 337–40, 374–6 (a detailed reliable account).G.Woodward, 1989, "Staite and Petrie: pioneers of electric lighting", Proceedings of the Institution of Electrical Engineers 136 (Part A): 290–6 GWBiographical history of technology > Staite, William Edwards
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