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1 pipeline
['paɪplaɪn]in the pipeline — fig. [ change] in corso; [ product] in fase di produzione; [ novel] in cantiere
* * *noun (a long line of pipes used for conveying oil, gas, water etc: an oil pipeline across the desert.) conduttura, tubazione* * *pipeline /ˈpaɪplaɪn/n.1 condotta; conduttura; tubazione: the water pipelines, le condutture dell'acqua; gas pipeline, tubazione del gas; pipeline network, rete di tubazioni2 (fig.) canale diretto (per contattare q.); canale riservato ( di informazioni); tramite; mezzo di trasmissione4 gasdotto● (fig.) to be in the pipeline, essere in corso; essere in arrivo; essere in cantiere (o in preparazione); ( di una pratica, ecc.) seguire il suo iter □ methane pipeline, metanodotto □ oil pipeline, oleodotto.* * *['paɪplaɪn]in the pipeline — fig. [ change] in corso; [ product] in fase di produzione; [ novel] in cantiere
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2 pipeline
1) (см. тж. instruction pipeline, processor pipeline) - конвейер"сборочная линия" - цепочка параллельно работающих исполнительных устройств центрального процессора, на которой обработка команд разбивается на ряд небольших шагов, стадий или ступеней, выполняемых за один такт. Конвейер организован таким образом, что выходные данные одного устройства поступают на вход другого. Число стадий называется длиной конвейера. Использование конвейера позволяет начать исполнение следующей машинной команды в одном блоке до завершения предыдущей, т. е. с перекрытием по времени (различные стадии нескольких команд выполняются ЦП параллельно). Какова длина конвейера, столько команд одновременно он и может обрабатывать - и в идеале конвейеризация обеспечивает выигрыш в производительности (по сравнению с неконвейерными ЦП, non-pipelined processor), соответствующий числу ступеней конвейера. В современных процессорах конвейеры имеют длину до 20 стадий (Pentium 4). Однако параллельная обработка команд возможна не всегда, так как в программе часто встречаются команды условных переходов и ситуации, когда для исполнения команды требуется результат предшествующей команды. В таких случаях, чтобы предотвратить перезагрузку конвейера (см. pipeline break), применяются более сложные процессы: упреждающая обработка (предсказание переходов, branch prediction) или изменение порядка исполнения команд (out-of-order execution).The pipeline must be flushed before the CPU can respond to an interrupt. — Конвейер должен быть очищен перед тем как ЦП сможет реагировать на прерывание см. тж. balanced pipeline, branch delay slot, control-flow pipeline, execute phase, graphics pipeline, instruction pipeline, load delay slot, machine language, multipipeline processor, pipeline bubble, pipelined application, pipelined architecture, pipeline depth, pipeline diagram, pipeline error, pipeline processing, pipeline processor, pipeline scheduling, pipeline stall, stage, superpipelined, superscalar architecture, unbalanced pipeline
2) конвейеризировать, применять конвейерVector processors pipeline and parallelize the operations on the individual elements of a vector. — Векторные процессоры производят распараллеливание и конвейеризацию операций над индивидуальными элементами вектора см. тж. pipelining
3) конвейерныйАнгло-русский толковый словарь терминов и сокращений по ВТ, Интернету и программированию. > pipeline
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3 pipeline
1) конвейер || конвейерный- instruction pipeline
- N-stage pipeline
- processor pipeline
- speculative execution pipeline
- virtual pipelineEnglish-Russian dictionary of computer science and programming > pipeline
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4 execution unit
= EU IIисполнительный блок, исполнительное устройство1) часть процессора, предназначенная для выполнения операций (машинных команд). Делится на ALU и FPU. Иногда термин используется как синоним CPUсм. тж. control unit2) блок конвейера ( pipeline) ЦП, реализующий одну ступень (stage) исполнения командыАнгло-русский толковый словарь терминов и сокращений по ВТ, Интернету и программированию. > execution unit
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5 speculative execution pipeline
English-Russian dictionary of computer science and programming > speculative execution pipeline
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6 OEP
1) Американизм: Office of Emergency Preparedness2) Военный термин: Office of Emergency Planning, officer educational program, operational employment plan, outside engineering personnel, overseas employment program3) Сельское хозяйство: маслоэкстракционный завод (МЭЗ)4) Юридический термин: obtained employment purchase5) Сокращение: Office of Emergency Preparedness (USA)6) Университет: Optometric Extension Program Foundation, Optometry Extension Program7) Вычислительная техника: Operand Execution Pipelines (Motorola, CPU)8) Иммунология: original endotoxin protein9) Транспорт: Oil Extra Pressure, Office Emergency Preparedness (US)10) Фирменный знак: Original Engineered Products, Inc.11) Деловая лексика: Onyx Employee Portal12) Полимеры: oil-extended polymer13) Океанография: Office of Environmental Policy14) Макаров: optimized effective potential15) Расширение файла: Operand Execution Pipeline -
7 POEP
Вычислительная техника: Primary Operand Execution Pipeline (Motorola, CPU) -
8 SOEP
2) Вычислительная техника: Secondary Operand Execution Pipeline (Motorola, CPU) -
9 computer
1) компьютер; вычислительная машина; ЭВМ; вычислительное устройство; вычислитель; редк. процессор2) редк. счётная машина (см. тж calculator, machine)•- adaptive computer
- airborne computer
- all-applications computer
- all-purpose computer
- alternating-current analog computer
- analog computer
- analog-digital computer
- arbitrary sequence computer
- associative computer
- asynchronous computer
- automotive computer
- baby-sized computer
- back-end computer
- batch-oriented computer
- battery-operated computer
- binary computer
- binary-transfer computer
- board computer
- boutique computer
- brand-name computer
- breadboard computer
- buffered computer
- business computer
- business-oriented computer
- byte computer
- byte-organized computer
- byte-oriented computer
- cassette-based computer
- census computer
- central computer
- character-oriented computer
- chemical-based computer
- chess computer
- CISC computer
- commercial computer
- commodity computer
- communication computer
- communications oriented computer
- compatible computer
- complete-instruction-set computer
- concurrent computer
- consecutive computer
- consecutive sequence computer
- continuously acting computer
- control computer
- control flow computer
- correlation computer
- coupled computers
- cryogenic computer
- cryotron computer
- custom computer
- database computer
- data-flow computer
- decimal computer
- dedicated computer
- desk computer
- desk-size computer
- desk-top computer
- dialing set computer
- dial set computer
- digital computer
- direct execution computer
- direct-analogy computer
- direct-current computer
- diskless computer
- distributed logic computer
- drum computer
- dual-processor computer
- education computer
- electromechanical analog computer
- electronic tube computer
- electron tube computer
- electronic computer
- end-user computer
- ever-faster computer
- externally programmed computer
- fault-tolerant computer
- fifth-generation computer
- file computer
- first-generation computer
- fixed word-length computer
- fixed-point computer
- fixed-program computer
- flat screen computer
- floating-point computer
- fluid computer
- four-address computer
- fourth-generation computer
- fractional computer
- front-end computer
- gateway computer
- general-purpose computer
- giant computer
- giant-powered computer
- giant-scale computer
- giant-size computer
- gigacycle computer
- gigahertz computer
- guidance computer
- handheld computer
- high-end computer
- high-function computer
- high-level language computer
- high-level computer
- highly parallel computer
- high-performance computer
- high-speed computer
- hobby computer
- home banking computer
- home computer
- host computer
- hybrid computer
- IBM-compatible computer
- IC computer
- incompatible computer
- incremental computer
- industrial computer
- integrated circuit computer
- interface computer
- interim computer
- intermediate computer
- internally programmed computer
- Internet computer
- keyboard computer
- kid computer
- laptop computer
- large computer
- large-powered computer
- large-scale computer
- large-scale integration circuit computer
- large-size computer
- laser computer
- linkage computer
- local computer
- logical computer
- logic computer
- logic-controlled sequential computer
- logic-in-memory computer
- low-end computer
- low-profile computer
- low-speed computer
- LSI computer
- mainframe computer
- massively parallel computer
- master computer
- mechanical computer
- medium computer
- medium-powered computer
- medium-size computer
- medium-speed computer
- medium-to-large scale computer
- mediun-scale computer
- megacycle computer
- megahertz computer
- microprogrammable computer
- microwave computer
- mid-range computer
- molecular computer
- monoprocessor computer
- multiaddress computer
- multi-MIPS computer
- multiple-access computer
- multiple-user computer
- multiprocessor computer
- multiprogrammed computer
- multipurpose computer
- multiradix computer
- navigation computer
- net node computer
- networked computer
- N-node computer
- no-address computer
- node computer
- nonsequential computer
- nonstop computer
- non-von Neumann computer
- notebook computer
- object computer
- office computer
- off-the-shelf computer
- one-address computer
- one-and-half-address computer
- one-on-one computer
- one-purpose computer
- optical computer
- optical path computer
- original computer
- palm-size computer - parallel-processing computer
- parallel-serial computer
- parametric-electronic computer
- parametron computer
- pen-based computer
- pentop computer
- perihperal support computer
- peripheral computer
- personal computer
- pictorial computer
- pipeline computer
- plugboard computer
- plug-compatible computer
- plugged program computer
- pneumatic computer
- pocket computer
- Polish-string computer
- polynomial computer
- portable computer
- process control computer
- production control computer
- professional computer
- professional personal computer
- program-compatible computer
- program-controlled computer
- programmed computer
- punch-card computer
- rack-size computer
- radix two computer
- real-time computer
- recovering computer
- reduced instruction set computer
- reduction computer
- remote computer
- repetitive computer
- RISC computer
- satellite computer
- scientific computer
- second-generation computer
- secondhand computer
- self-adapting computer
- self-organizing computer
- self-programming computer
- self-repairing computer
- self-repair computer
- sensor-based computer
- sequence-controlled computer
- sequenced computer
- sequential computer
- serial computer
- service computer
- service-oriented computer
- SIMD computer
- simultaneous-operation computer
- simultaneous computer
- single-address computer
- single-board computer
- single-purpose computer
- single-user computer
- slave computer
- small computer
- small-powered computer
- small-scale computer
- small-size computer
- soft-compatible computer
- solid-state computer
- SOS computer
- source computer
- space computer
- spaceborne computer
- special-purpose computer
- special computer
- square-root computer
- stack-oriented computer
- standby computer
- statistical computer
- steering computer
- stored-program computer
- subscriber computer
- super computer
- superconductive computer
- superhigh-speed computer
- superpersonal computer
- superspeed computer
- supervisory computer
- switch-control computer
- switching computer
- symbolic computer
- synchronous computer
- synchronous tracking computer
- tagged computer
- talking computer
- target computer
- technical computer
- technical personal computer
- terminal computer
- terminal control computer
- ternary-transfer computer
- tessellated computer
- thermal computer
- thin-film memory computer
- third-generation computer
- three-address computer
- three-dimensional analog computer
- timeshared computer
- top level computer
- top-of-the-line computer
- toy computer
- training computer
- transformation computer
- transistorized computer
- transistor computer
- translating computer
- tridimensional analog computer
- trip computer
- truth-table computer
- Turing-type computer
- two-address computer
- ultrafast computer
- underlying computer
- user computer
- vacuum tube computer
- variable word-length computer
- very-high-speed computer
- video-and-cassette-based computer
- virtual computer
- von Neumann computer
- wearable computer
- weather computer
- wired-program computer
- word-oriented computer
- workgroup computer
- X-computer
- zero-address computerEnglish-Russian dictionary of computer science and programming > computer
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10 Bateman, John Frederick La Trobe
[br]b. 30 May 1810 Lower Wyke, near Halifax, Yorkshire, Englandd. 10 June 1889 Moor Park, Farnham, Surrey, England[br]English civil engineer whose principal works were concerned with reservoirs, water-supply schemes and pipelines.[br]Bateman's maternal grandfather was a Moravian missionary, and from the age of 7 he was educated at the Moravian schools at Fairfield and Ockbrook. At the age of 15 he was apprenticed to a "civil engineer, land surveyor and agent" in Oldham. After this apprenticeship, Bateman commenced his own practice in 1833. One of his early schemes and reports was in regard to the flooding of the river Medlock in the Manchester area. He came to the attention of William Fairbairn, the engine builder and millwright of Canal Street, Ancoats, Manchester. Fairbairn used Bateman as his site surveyor and as such he prepared much of the groundwork for the Bann reservoirs in Northern Ireland. Whilst the reports on the proposals were in the name of Fairbairn, Bateman was, in fact, appointed by the company as their engineer for the execution of the works. One scheme of Bateman's which was carried forward was the Kendal Reservoirs. The Act for these was signed in 1845 and was implemented not for the purpose of water supply but for the conservation of water to supply power to the many mills which stood on the river Kent between Kentmere and Morecambe Bay. The Kentmere Head dam is the only one of the five proposed for the scheme to survive, although not all the others were built as they would have retained only small volumes of water.Perhaps the greatest monument to the work of J.F.La Trobe Bateman is Manchester's water supply; he was consulted about this in 1844, and construction began four years later. He first built reservoirs in the Longdendale valley, which has a very complicated geological stratification. Bateman favoured earth embankment dams and gravity feed rather than pumping; the five reservoirs in the valley that impound the river Etherow were complex, cored earth dams. However, when completed they were greatly at risk from landslips and ground movement. Later dams were inserted by Bateman to prevent water loss should the older dams fail. The scheme was not completed until 1877, by which time Manchester's population had exceeded the capacity of the original scheme; Thirlmere in Cumbria was chosen by Manchester Corporation as the site of the first of the Lake District water-supply schemes. Bateman, as Consulting Engineer, designed the great stone-faced dam at the west end of the lake, the "gothic" straining well in the middle of the east shore of the lake, and the 100-mile (160 km) pipeline to Manchester. The Act for the Thirlmere reservoir was signed in 1879 and, whilst Bateman continued as Consulting Engineer, the work was supervised by G.H. Hill and was completed in 1894.Bateman was also consulted by the authorities in Glasgow, with the result that he constructed an impressive water-supply scheme derived from Loch Katrine during the years 1856–60. It was claimed that the scheme bore comparison with "the most extensive aqueducts in the world, not excluding those of ancient Rome". Bateman went on to superintend the waterworks of many cities, mainly in the north of England but also in Dublin and Belfast. In 1865 he published a pamphlet, On the Supply of Water to London from the Sources of the River Severn, based on a survey funded from his own pocket; a Royal Commission examined various schemes but favoured Bateman's.Bateman was also responsible for harbour and dock works, notably on the rivers Clyde and Shannon, and also for a number of important water-supply works on the Continent of Europe and beyond. Dams and the associated reservoirs were the principal work of J.F.La Trobe Bateman; he completed forty-three such schemes during his professional career. He also prepared many studies of water-supply schemes, and appeared as professional witness before the appropriate Parliamentary Committees.[br]Principal Honours and DistinctionsFRS 1860. President, Institution of Civil Engineers 1878, 1879.BibliographyAmong his publications History and Description of the Manchester Waterworks, (1884, London), and The Present State of Our Knowledge on the Supply of Water to Towns, (1855, London: British Association for the Advancement of Science) are notable.Further ReadingObituary, 1889, Minutes of the Proceedings of the Institution of Civil Engineers 97:392– 8.Obituary, 1889, Proceedings of the Royal Society 46:xlii-xlviii. G.M.Binnie, 1981, Early Victorian Water Engineers, London.P.N.Wilson, 1973, "Kendal reservoirs", Transactions of the Cumberland and Westmorland Antiquarian and Archaeological Society 73.KM / LRDBiographical history of technology > Bateman, John Frederick La Trobe
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