memory+development

СОБОЛЕЗНОВАНИЯ

Выражение соболезнования требует от переводчика особых усилий и бдительности, поскольку перепутать имя или должность покойного — ошибка, которая не прощается.

***

Делегация Украины выражает глубокое соболезнование правительству и народу Мексики в связи со стихийным бедствием, сильным землетрясением, повлекшим многочисленные человеческие жертвы и большие разрушения.

The delegation of Ukraine expresses its deepest (not deep) sympathy/sincere (not profound) condolences to the government and people of Mexico on/in connection with the natural disaster, the major/violent earthquake which has resulted in/caused great loss of life/numerous casualties and destruction of property/considerable damage.

Прежде чем перейти к повестке дня сегодняшнего утреннего заседания, позвольте мне от имени всех членов комитета выразить наше самое искреннее соболезнование правительству и народу Х-а в связи с трагической гибелью людей и серьезным материальным ущербом в результате недавних стихийных бедствий, обрушившихся на эту страну.

Before taking up the items on our agenda for this morning, may I, on behalf of all the members of the committee, extend our deepest sympathy to the Government and people of X on the tragic loss of life and extensive material damage caused by the recent natural disasters which have struck this country. May I also express the hope that the international community will show its solidarity and respond promptly and generously to any requests for help.

Мы понесли тяжелую/невосполнимую утрату.

We have suffered a terrible/tragic/irrevocable loss.

Я должен выполнить печальную обязанность и известить нашу Ассамблею о безвременной кончине Главы государства Республики X Его Превосходительства Н.Н. Известие о кончине Н.Н.-а, всегда стоявшего за дело мира и взаимопонимания — то есть за дело нашей организации, — вызвало у меня чувство глубокой скорби. От нашего имени я прошу представителя Х'а передать наши соболезнования правительству и народу Х'а и семье покойного. Прошу членов нашей Ассамблеи встать и почтить память Н.Н. минутой молчания.

It is my sad duty to inform our Assembly of the untimely death of the Head of State of the Republic of X, His Excellency N.N. It is with deep sorrow that I have learned of the death of N.N., who always stood for the cause of peace and understanding and for self-determination and development, that is, for the cause of our organization. On behalf of all of us I request the representative of X to convey our condolences to the government and people of X and to the bereaved family. I now invite members of this Assembly to stand/ rise and observe a minute of silence in tribute to the memory of N.N.

***

Ответ на соболезнования и выражения сочуствия:

Наша делегация искренне благодарна всем представителям, высказавшим во время сессии Комиссии сочувствие.

Our delegation is sincerely/deeply/ most grateful/expresses its profound appreciation to all those representatives/speakers who have expressed/voiced/conveyed their sympathy during this session of the Commission.

***

- Я вам искренне соболезную
- Разрешите выразить вам искренние соболезнования
- Я тебе сочувствую

время

time

время высвечивания

luminescence decay time

время жизни

1.lifetime 2.life

время задержки

delay time

время запоминания

memory time

время затухания

die-away time

время интегрирования

integration time

время использования телескопа для наблюдений

telescope time

время наблюдения

1.time of observation 2.observation time (duration of observations)

время наблюдения центрального лепестка интерференционной картины

time of central maximum

время накопления информации

storage time

время пролета

time of flight (of artificial Earth’s satellite)

время проявления

development time

время разрешения

resolving time

время расширения Вселенной

Hubble time

время релаксации

relaxation time

время спада сигнала

discharge time

время срабатывания

pickup time

время существования

life time

время усреднения

averaging time

время фиксирования

fixation time

время экспозиции

exposure time

абсолютное время

Newtonian time

астрономическое время

astronomical time

атлантическое стандартное время

Atlantic Standard time

атомное время

atomic time

восточноевропейское время

Eastern European time

восточное поясное время

Eastern standard time (USA)

Всемирное время

1.Universal Time (UT) 2.Zulu or Z-time (in USA)

Всемирное координированное время

Coordinated Universal Time (UTC)

геомагнитное время

geomagnetic time

гражданское время

civil time

гринвичское время

Greenwich

гринвичское гражданское время

Greenwich mean (from midnight)

гринвичское истинное

Greenwich apparent (time)

гринвичское среднее время

Greenwich mean (time)

декретное время

legal time

дипольное время

dipole time

звездное время

1.sidereal hour angle 2.astronomical time

звездное время в среднюю полночь

sidereal time in midnight

звездное местное время

local sidereal time

истекшее время

elapsed time

истинное время

1.apparent time 2.true time 3.real time

истинное местное время

local apparent time

истинное солнечное время

1.apparent solar time 2.astronomical time

летнее время

British summer time

международное атомное время

Time Atomic International (TAI)

местное время

local time

местное геомагнитное время

local geomagnetic time

местное гражданское время

local civil time

местное поясное время

local standard time

местное среднее время

local mean time

наблюдательное время

observation time

поясное время

1.standard time 2.zone time

рабочее время

operating time

равномерное звездное время

uniform sidereal time

расчетное время

1.estimated time 2.normal time

солнечное время

solar time

собственное время

1.proper time 2.intrinsic time

среднее время

1.mean time 2.average time

среднеевропейское время

Central European time

среднее время жизни

1.average life 2.mean life time

среднее звездное время

mean sidereal time

среднее солнечное время

mean solar time

текущее время

run(ning) time

тихоокеанское поясное время

Pacific standard time (USA)

усредненное время

averaged time

фактическое время

actual time

характеристическое время

characteristic time

центральное зимнее время между 90° и 105° з.д.

амер. Central winter time

центральное поясное время между 90° и 150° з.д.

амер. Central (standard) time

эфемеридное время

ephemeris time

замкнутый цикл

1. closed cycle

включать в замкнутый цикл — run in closed circuit with

цикл проявления — development cycle

цикл Кребса — tricarbonic acid cycle

цикл движения вперед — forward cycle

цикл накопления — accumulation cycle

цикл обновления — regeneration cycle

2. closed loop

цикл записи — write cycle

цикл запуска — cranking cycle

идеальный цикл — ideal cycle

итерационный цикл — iteration loop

выполнять итерационный цикл — traverse an iteration loop

цикл Карно — Carnot cycle

кинематический цикл — kinematic cycle

командный цикл — instruction cycle

криогенный цикл — cryogenic cycle

цикл лавы — wall cycle

магнитный цикл — magnetic cycle

магнитогидродинамический цикл — magnetohydrodynamic cycle

машинный цикл — machine cycle

цикл нагрева — heating cycle

цикл намагничивания — cycle of magnetization

цикл напряжений — stress cycle

незамкнутый цикл — open cycle

нейтронный цикл — neutron cycle

необратимый цикл — irreversible cycle

непрерывный цикл — uninterrupted cycle

обратимый цикл — reversible cycle

цикл обращения к памяти — memory cycle

окислительно-восстановительный цикл — oxidation-reduction cycle

основной цикл — basic cycle

охватывающий цикл — outer loon

цикл охлаждения — cooling cycle

пароводяной цикл — water-flow cycle; water-steam circuit

паровой цикл — vapour cycle

парогазовый цикл — supercharged boiler cycle

паросиловой цикл — steam power cycle

паротурбинный цикл — steam turbine cycle

цикл перемагничивания — cycle of magnetization

цикл плавки от выпуска до выпуска — tap-to-tap cycle

повторный цикл — recycle

цикл поиска — search cycle

предельный цикл — limit cycle

цикл программы — loop of instructions

протонный цикл — proton-proton chain

проходческий цикл — sinking cycle

цикл работы — operation period

завершение цикла — loop termination

объединение циклов — loop combining

цикл обратной связи — feedback loop

автозамыкание цикла — crossfade loop

развертывание цикла — loop unrolling

макетная плата

1. development board

плата двойной ширины — dual-height board

плотность компоновки плат — board density

соединительная плата — interconnect board

блок печатных плат — printed board assembly

заведомо исправная плата — known-good board

2. prototyping board

плата с двухсекционным краевым разъемом — dual-height board

плата памяти; плата запоминающего устройства — memory board

объемная печатная плата — right-angle printed circuit board

плата с шестисекционным краевым разъемом — hex-width board

тестер смонтированных печатных плат — loaded board tester

3. breadboard card

ячейка; типовой элемент замены; модуль платы — card module

плата управления степенью подвижности — joint control card

плата с последовательностной логикой — gate/flip-flop card

плата с электронными схемами интерфейсных шин — bus card

плата с дискретными элементами — discrete component card

Kemeny, John G.

SUBJECT AREA: Electronics and information technology

[br]

b. before 1939

[br]

American mathematician and systems programmer, jointly responsible with Thomas Kurtz for the development of the high-level computer language BASIC.

[br]

Kemeny entered the USA as an immigrant in 1939. He subsequently became a mathematics lecturer at Dartmouth College, Hanover, New Hampshire, and later became a professor and then Chairman of the Mathematics Department; finally, in 1971, he became President of the College. In 1964, with Thomas Kurtz, he developed the high-level computer language known as BASIC (Beginners All-purpose Symbolic Instruction Code). It was initially designed for use by students with a time-sharing minicomputer, but it soon became the standard language for microcomputers, frequently being embedded in the computer as "firmware" loaded into a read-only-memory (ROM) integrated circuit.

[br]

Bibliography

1963. Programming for a Digital Computer.

1964. with T.E.Kurtz, BASIC Instruction Manual.

1968, with T.E.Kurtz, "Dartmouth time-sharing", Science 223.

Further Reading

R.L.Wexelblat (ed.), 1981, History of Programming Languages, New York: Academic Press.

KF

Porta, Giovanni Battista (Giambattista) della

SUBJECT AREA: Steam and internal combustion engines

[br]

b. between 3 October and 15 November 1535 Vico Equense, near Naples, Italy

d. 4 February 1615 Naples, Italy

[br]

Italian natural philosopher who published many scientific books, one of which covered ideas for the use of steam.

[br]

Giambattista della Porta spent most of his life in Naples, where some time before 1580 he established the Accademia dei Segreti, which met at his house. In 1611 he was enrolled among the Oziosi in Naples, then the most renowned literary academy. He was examined by the Inquisition, which, although he had become a lay brother of the Jesuits by 1585, banned all further publication of his books between 1592 and 1598.

His first book, the Magiae Naturalis, which covered the secrets of nature, was published in 1558. He had been collecting material for it since the age of 15 and he saw that science should not merely represent theory and contemplation but must arrive at practical and experimental expression. In this work he described the hardening of files and pieces of armour on quite a large scale, and it included the best sixteenth-century description of heat treatment for hardening steel. In the 1589 edition of this work he covered ways of improving vision at a distance with concave and convex lenses; although he may have constructed a compound microscope, the history of this instrument effectively begins with Galileo. His theoretical and practical work on lenses paved the way for the telescope and he also explored the properties of parabolic mirrors.

In 1563 he published a treatise on cryptography, De Furtivis Liter arum Notis, which he followed in 1566 with another on memory and mnemonic devices, Arte del Ricordare. In 1584 and 1585 he published treatises on horticulture and agriculture based on careful study and practice; in 1586 he published De Humana Physiognomonia, on human physiognomy, and in 1588 a treatise on the physiognomy of plants. In 1593 he published his De Refractione but, probably because of the ban by the Inquisition, no more were produced until the Spiritali in 1601 and his translation of Ptolemy's Almagest in 1605. In 1608 two new works appeared: a short treatise on military fortifications; and the De Distillatione. There was an important work on meteorology in 1610. In 1601 he described a device similar to Hero's mechanisms which opened temple doors, only Porta used steam pressure instead of air to force the water out of its box or container, up a pipe to where it emptied out into a higher container. Under the lower box there was a small steam boiler heated by a fire. He may also have been the first person to realize that condensed steam would form a vacuum, for there is a description of another piece of apparatus where water is drawn up into a container at the top of a long pipe. The container was first filled with steam so that, when cooled, a vacuum would be formed and water drawn up into it. These are the principles on which Thomas Savery's later steam-engine worked.

[br]

Further Reading

Dictionary of Scientific Biography, 1975, Vol. XI, New York: C.Scribner's Sons (contains a full biography).

H.W.Dickinson, 1938, A Short History of the Steam Engine, Cambridge University Press (contains an account of his contributions to the early development of the steam-engine).

C.Singer (ed.), 1957, A History of Technology, Vol. III, Oxford University Press (contains accounts of some of his other discoveries).

I.Asimov (ed.), 1982, Biographical Encyclopaedia of Science and Technology, 2nd edn., New York: Doubleday.

G.Sarton, 1957, Six wings: Men of Science in the Renaissance, London: Bodley Head, pp. 85–8.

RLH / IMcN

Zuse, Konrad

SUBJECT AREA: Electronics and information technology

[br]

b. 22 June 1910 Berlin, Germany

[br]

German civil engineer who developed a series of computers before, during and after the Second World War.

[br]

Zuse grew up in Braunsberg, then in East Prussia, and attended the Technische Hochschule at Berlin-Charlottenburg to study civil engineering. In 1934 he became interested in calculatingmachines and the pursuit of a career in aeronautical engineering. Two years later, having taken a post as a statistician, in his spare time he built a mechanical computer, which he called Z1; for this he used two-state mechanical switches and punched-tape for the program input. This was followed by the design for Z2, which used electromechanical relays.

Called to military service in 1939, he was soon sent to the Henschel aircraft factory, where he completed Z2. Between 1939 and 1941 the German Aeronautical Research Institute supported his development of Z3, which used 2,600 relays and a keyboard input. Taken into immediate use by the aircraft industry, both it and its predecessors were destroyed in air raids. Z4, completed towards the end of the war and using mechanical memory, survived, and with improvements was used in Switzerland until 1960. Other achievements by Zuse included a machine to perform logical calculations (LI) and his Plankalkul, one of the first computer languages. In 1950, with two friends, he formed the Zuse KG company near Bad Hersfeld, Essen, and his first Z5 relay computer was sold to Leitz in 1952. A series of machines followed, a milestone in 1958 being the first transistorized machine, Z22, of which over 200 were made. Finally, in 1969, the company was absorbed by Siemens AG and Zuse returned to scientific research.

[br]

Principal Honours and Distinctions

Honorary Doctorate Berlin Technical University 1960. Honorary Professor Göttingen University 1960.

Bibliography

11 April 1936, German patent no. Z23 1391X/42M. 16 June 1941, German patent no. Z391.

1 August 1949, German patent no. 50,746.

1993, The Computer: My Life, Berlin: SpringerVerlag (autobiography).

Further Reading

P.E.Ceruzzi, 1981, "The early computers of Konrad Zuse 1935–45", Annals of the History of Computing 3:241.

M.R.Williams, 1985, A History of Computing Technology, London: Prentice-Hall.

See also: Stibitz, George R.

KF

память программы

program memory

управляемая программа кредитования — directed credit program

управление выполнением программы — program execution control

тест; тестовая программа; программа испытаний — test program

телевизионная программа об образе жизни — life-style program

программа ядерных исследований — nuclear development program

δόξα

δόξα, ης, ἡ (s. δοξάζω; in var. mngs. Hom.+; in Ath. ‘meaning’). In many of the passages in our lit. the OT and Gr-Rom. perceptions of dependence of fame and honor on extraordinary performance deserve further exploration. SIG 456, 15 is typical: concern for others leads to enhancement of one’s δόξα or reputation. The Common Gk. usage of δ. in sense of ‘notion, opinion’ is not found in the NT.

① the condition of being bright or shining, brightness, splendor, radiance (a distinctive aspect of Hb. כָּבוֹד).

ⓐ of physical phenomena (PGM 13, 189 τὴν δόξαν τοῦ φωτός, cp. 298ff. On this Rtzst., Mysterienrel.³ 357ff, also 314 δόξα ἐκ τ. πυρός [cp. Just., D. 128]; 315 φῶς κ. δόξαν θεῖαν [=Cleopatra 150]; LXX; TestJob 43:6 τῆ λαμπάδα αὐτοῦ) οὐκ ἐνέβλεπον ἀπὸ τῆς δ. τοῦ φωτός I could not see because of the brightness of the light Ac 22:11; ὁρᾶν τὴν δ. see the radiance Lk 9:32; cp. vs. 31. Everything in heaven has this radiance: the radiant bodies in the sky 1 Cor 15:40f (cp. PGM 13, 64 σὺ ἔδωκας ἡλίῳ τὴν δόξαν κ. δύναμιν; 448; Sir 43:9, 12; 50:7).

ⓑ of humans involved in transcendent circumstances, and also transcendent beings: cherubim (Sir 49:8; Ezk 10:4) Hb 9:5; angels Lk 2:9; Rv 18:1. Esp. of God’s self (Ex 24:17; 40:34; Num 14:10; Bar 5:9 τὸ φῶς τῆς δόξης αὐτου; Tob 12:15; 13:16 BA; 2 Macc 2:8; SibOr 5, 427) ὁ θεὸς τῆς δ. (En 25:7) Ac 7:2 (Ps 28:3); cp. J 12:41 (Is 6:1); Ac 7:55; 2 Th 1:9; 2 Pt 1:17b; Rv 15:8; 19:1; 21:11, 23. ὁ πατὴρ τῆς δ. Eph 1:17; βασιλεὺς τῆς δ. AcPl BMM verso 24 and 26. But also of those who appear before God: Moses 2 Cor 3:7–11, 18 (Just., D. 127, 3; cp. Ἀδὰμ τῆς δ. θεοῦ ἐγυμνώθη GrBar 4:16); Christians in the next life 1 Cor 15:43; Col 3:4. The δόξα τοῦ θεοῦ as it relates to the final judgment Ro 3:23; 5:2 (but s. 3); Jesus himself has a σῶμα τῆς δ. radiant, glorious body Phil 3:21; cp. 2 Cl 17:5. Christ is the κύριος τ. δόξης 1 Cor 2:8 (cp. En 22:14; 27:3, 5; 36:4; 40:3 of God; PGM 7, 713 κύριοι δόξης of deities).—The concept has been widened to denote the glory, majesty, sublimity of God in general (PGM 4, 1202 ἐφώνησά σου τ. ἀνυπέρβλητον δόξαν; Orig., C. Cels. 4, 1, 24 οἰκοδομεῖν … ναὸν δόξης θεοῦ) ἀλλάσσειν τὴν δ. τοῦ θεοῦ exchange the majesty of God Ro 1:23; κατενώπιον τῆς δόξης αὐτοῦ Jd 24 (cp. En 104:1)=before himself. Christ was raised fr. the dead διὰ τῆς δ. τοῦ πατρός by the majesty (here, as in J 2:11, the thought of power, might is also present; cp. Rtzst., Mysterienrel.³ 344, 359 and PGM 4, 1650 δὸς δόξαν καὶ χάριν τῷ φυλακτηρίῳ τούτῳ; Wsd 9:11 φυλάξει με ἐν τ. δόξῃ; Philo, Spec. Leg. 1, 45.—JVogel, Het sanscrit woord tejas [=gloedvuur] in de beteekenis van magische Kracht 1930) of the Father Ro 6:4; cp. Mt 16:27; Mk 8:38; AcPl Ha 10, 9; ὄψῃ τὴν δ. τοῦ θεοῦ J 11:40; κράτος τῆς δ. majestic power Col 1:11; πλοῦτος τῆς δ. the wealth of his glory Ro 9:23; Eph 1:18; cp. Eph 3:16; Phil 4:19; Col 1:27; δ. τῆς χάριτος (PGM 4, 1650, s. above) Eph 1:6; w. ἀρετή 2 Pt 1:3 (τῆς ἐπʼ ἀρετῇ καὶ δόξῃ διαλήψεως, ins at Aphrodisias II, 14: ZPE 8, ’71, 186); ἀπαύγασμα τῆς δ. Hb 1:3; τὴν ἐπιφάνειαν τῆς δ. τοῦ μεγάλου θεοῦ Tit 2:13. Some would classify Ro 2:7, 10 here, but these and related pass. w. the formulation δόξα καὶ τιμή prob. are better placed in 3 below because of their focus on honor and prestige. Doxol. σοῦ ἐστιν ἡ δ. εἰς τ. αἰῶνας, ἀμήν (Odes 12:15 [Prayer of Manasseh]) Mt 6:13 v.l.; AcPl Ha 2, 33; εἰς ἔπαινον τῆς δ. αὐτοῦ Eph 1:12, 14; cp. 1:6.—1 Th 2:12; 1 Pt 5:10. Pl. Hv 1, 3, 3. κατὰ τὸ εὐαγγέλιον τῆς δ. τοῦ μακαρίου θεοῦ 1 Ti 1:11. Transferred to Christ: Mt 19:28; 24:30; 25:31; Mk 10:37; 13:26; Lk 9:26; 21:27; J 1:14; 2:11; Js 2:1 (AMeyer, D. Rätsel d. Js 1930, 118ff); B 12:7; AcPl Ha 7:7. τὸν φωτισμὸν τοῦ εὐαγγελίου τῆς δ. τοῦ χριστοῦ the news that shines with the greatness of Christ 2 Cor 4:4; cp. 4:6 (cp. Just., A I, 51, 8 παραγίνεσθαι μετὰ δόξης μέλλει). Of Christ’s prestige promoted by Paul’s associates 2 Cor 8:23 (but s. d and 3 below).

ⓒ The state of being in the next life is thus described as participation in the radiance or glory

α. w. ref. to Christ: εἰσελθεῖν εἰς τὴν δ. αὐτοῦ enter into his glory Lk 24:26 (βασιλείαν P⁷⁵ first hand); ἀνελήμφθη ἐν δ. 1 Ti 3:16; cp. τὰς μετὰ ταῦτα δ.1 Pt 1:11 (but s. β below; pl. because of the παθήματα; cp. also Wsd 18:24; Isocr. 4, 51; POslo 85, 13 [III A.D.]), 21. ἐν τῇ ἀποκαλύψει τῆς δ. αὐτοῦ 4:13. Also of Christ’s preëxistence: J 17:5, 22, 24.

β. w. ref. to his followers (cp. Da 12:13; Herm. Wr. 10, 7): Ro 8:18, 21; 1 Cor 2:7; 2 Cor 4:17; 1 Th 2:12; 2 Th 2:14; 2 Ti 2:10; Hb 2:10; 1 Pt 5:1, 4 (στέφανος τ. δόξης; on this expr. cp. Jer 13:18; TestBenj 4:1); εἰς … δ. καὶ τιμὴν ἐν ἀποκαλύψει Ἰησοῦ Χριστοῦ 1 Pt 1:7 (perh. 1:11 belongs here, in ref. to sufferings that are endured in behalf of Christ). πνεῦμα τῆς δ. w. πν. τοῦ θεοῦ 4:14. ἵνα πνευματικὴν καὶ ἄφθαρτον τῆς δικαιοσύνης δόξαν κληρονομήσωσιν ending of Mk 16:14 v.l. (Freer ms. ln. 11f) (Cleopatra 146f ἐνέδυσεν αὐτοὺς θείαν δόξαν πνευματικήν); ἥτις ἐστὶν δ. ὑμῶν (my troubles) promote your glory Eph 3:13 (s. MDibelius, comm. on Col 1:24ff) τόπος τῆς δ.=the hereafter 1 Cl 5:4.

ⓓ of reflected radiance reflection ἀνὴρ … εἰκὼν καὶ δόξα θεοῦ man (as distinguished from woman) is the image and reflection of God 1 Cor 11:7 (perh. this thought finds expression Ro 3:23; 5:2, but s. 3, below); also γυνὴ δόξα ἀνδρός ibid. (cp. the formal similarity but difft. mng. in the Jewish ins in Lietzmann comm. ad loc.: ἡ δόξα Σωφρονίου Λούκιλλα εὐλογημένη; s. also AFeuillet, RB 81, ’74, 161–82). Some interpret δ. Χριστοῦ 2 Cor 8:23 in ref. to Paul’s associates (but s. 1b).

② a state of being magnificent, greatness, splendor, anything that catches the eye (1 Esdr 6:9; 1 Macc 10:60, 86; 2 Macc 5:20): fine clothing (Sir 6:31; 27:8; 45:7; 50:11) of a king Mt 6:29; Lk 12:27; of royal splendor gener. (Bar 5:6; 1 Macc 10:58; Jos., Ant. 8, 166) Mt 4:8; Lk 4:6; Rv 21:24, 26. Gener. of human splendor of any sort 1 Pt 1:24 (Is 40:6).

③ honor as enhancement or recognition of status or performance, fame, recognition, renown, honor, prestige (s. s.v. ἀγαθός and δικαιο-entries; Diod S 15, 61, 5 abs. δόξα= good reputation; Appian, Bell. Civ. 2, 89 §376 δ. ἀγαθή good reputation, esteem; Polyaenus 8 Prooem. δόξα ἀθάνατος=eternal renown; Herm. Wr. 14, 7; PsSol 1:4; 17:6; Jos., Ant. 4, 14, Vi. 274; Just., A II, 10, 8 δόξης … καταφρονήσαντος) of public approbation (cp. Orig., C. Cels. 7, 24, 1; Did., Gen. 238, 25) ἐνώπιον πάντων τῶν συνανακειμένων σοι Lk 14:10; δ. λαμβάνειν (En 99:1; Diog. L. 9, 37 of Democr. οὐκ ἐκ τόπου δόξαν λαβεῖν βουλόμενος) J 5:41, 44a al.; sim. of God Rv 4:11 and the Lamb 5:12 receiving honor. J 8:54 (=make high claims for myself); 12:43a (cp. 8:50); Ro 9:4; 2 Cor 6:8 (opp. ἀτιμία); 1 Th 2:6; 1 Cl 3:1; B 19:3; Hv 1, 1, 8. Gener. γυνὴ … ἐὰν κομᾷ, δόξα αὐτῇ ἐστιν, i.e. she enjoys a favorable reputation 1 Cor 11:15 (opp. ἀτιμία). Oxymoron ὧν … ἡ δόξα ἐν τῇ αἰσχύνῃ αὐτῶν whose prestige is in their disgrace Phil 3:19. Of enhancement of divine prestige as an objective J 7:18; Lazarus’ illness redounds to God’s honor 11:4; Ro 15:7. Of divine approbation of pers. δ. τοῦ θεοῦ J 5:44b; 12:43b (cp. 1QH 17:15; 1QS 4:23); Ro 3:23; 5:2. Here also belong pass. w. the form δὸξα καὶ τιμή / τιμὴ καὶ δόξα (LXX; ins, e.g. OGI 223, 12; 244, 19f; 763, 37; Welles 42, 6; also PGM 4, 1616f δὸς δ. καὶ τιμὴν κ. χάριν; Just., D. 42, 1) Ro 2:7, 10; 1 Ti 1:17; Hb 2:7, 9 (Ps 8:6); cp. 3:3; 1 Pt 1:7; 2 Pt 1:17; Rv 4:9, 11; 5:12, 13; 21:26. Of pers. who bestow renown through their excellence: of Jesus Lk 2:32 (cp. Ro 9:4); of Paul’s epistolary recipients ὑμεῖς ἡ δ. ἡμῶν you bring us renown 1 Th 2:20 (cp. the Jewish ins in Lietzmann, 1d above: Loucilla brings renown to Sophronius).—Israel’s liturgy furnishes the pattern for the liturg. formula δ. θεῷ praise is (BWeiss; HHoltzmann; Harnack; Zahn; EKlostermann; ASchlatter; Rengstorf) or be (Weizsäcker; JWeiss; OHoltzmann) to God Lk 2:14. Cp. 19:38; Ro 11:36; 16:27; Gal 1:5; Eph 3:21; Phil 4:20; 2 Ti 4:18 (perh. Christ as referent); Hb 13:21; 1 Pt 4:11; 1 Cl 20:12; 50:7 al.; τιμὴ καὶ δ. 1 Ti 1:17 (s. also above as extra-biblical formulation, esp. OGI 223, 12; 244, 19f; 763, 37); cp. Jd 25 v.l.; Rv 5:13; 7:12. Doxologies to Christ 2 Pt 3:18; Rv 1:6; εἰς (τὴν) δ. (τοῦ) θεοῦ to the praise of God Ro 15:7; 1 Cor 10:31; 2 Cor 4:15; Phil 1:11; 2:11; cp. Ro 3:7. Also πρὸ δ. 2 Cor 1:20; πρὸ τὴν αὐτοῦ τοῦ κυρίου (Christ) δ. 8:19. Hence the expr. δ. διδόναι τῷ θεῷ praise God (Bar 2:17f; 1 Esdr 9:8; 4 Macc 1:12): in thanksgiving Lk 17:18; Rv 19:7; as a form of relig. devotion: Ac 12:23; Ro 4:20; Rv 4:9; 11:13; 14:7; 16:9; as an adjuration δὸς δ. τῷ θεῷ give God the praise by telling the truth J 9:24.—GBoobyer, ‘Thanksgiving’ and the ‘Glory of God’ in Paul, diss. Leipzig 1929; LChampion, Benedictions and Doxologies in the Epistles of Paul ’35; MPamment, The Meaning of δόξα in the Fourth Gospel: ZNW 74, ’83, 12–16, God’s glory is manifested through the gift of Jesus’ voluntary self-surrender on the cross.

④ a transcendent being deserving of honor, majestic being, by metonymy (cp. Diod S 15, 58, 1 of citizens who stood out from among all others in ἐξουσίαι καὶ δόξαι=offices and honors) of angelic beings (s. Philo, Spec. Leg. 1, 45; PGM 1, 199) δόξαι majestic (heavenly) beings Jd 8; 2 Pt 2:10 (s. also Ex 15:11 LXX; TestJud 25:2 αἱ δυνάμεις τ. δόξης. Also the magical text in Rtzst., Poim. p. 28 [VI 17] χαιρέτωσάν σου αἱ δόξαι (practically = δυνάμει) εἰς αἰῶνα, κύριε). Cp. JSickenberger, Engelsoder Teufelslästerer? Festschrift zur Jahrhundertfeier d. Univers. Breslau 1911, 621ff. The mng. majesties and by metonymy illustrious persons is also prob.—On the whole word Rtzst., Mysterienrel.³ 289; 314f; 344; 355ff; AvGall, D. Herrlichkeit Gottes 1900; IAbrahams, The Glory of God 1925.—AForster, The Mng. of Δόξα in the Greek Bible: ATR 12, 1929/1930, 311ff; EOwen, Δόξα and Cognate Words: JTS 33, ’32, 139–50; 265–79; CMohrmann, Note sur doxa: ADebrunner Festschr. ’54, 321–28; LBrockington, LXX Background to the NT Use of δ., Studies in the Gospels in memory of RLightfoot ’55, 1–8.—HBöhlig, D. Geisteskultur v. Tarsos 1913, 97ff; GWetter, D. Verherrlichung im Joh.-ev.: Beitr. z. Rel.-wiss. II 1915, 32–113, Phos 1915; RLloyd, The Word ‘Glory’ in the Fourth Gospel: ET 43, ’32, 546–48; BBotte, La gloire du Christ dans l’Evangile de S. Jean: Quest. liturgiques 12, 1927, 65ff; HPass, The Glory of the Father; a Study in St John 13–17, ’35; WThüsing, Die Erhöhung u. Verherrlichung Jesu im J, ’60.—GKittel, D. Rel. gesch. u. d. Urchristentum ’32, 82ff; JSchneider, Doxa ’32; HKittel, D. Herrlichkeit Gottes ’34; MGreindl, Κλεος, Κυδος, Ευχος, Τιμη, Φατις, Δοξα, diss. Munich ’38; AVermeulen, Semantic Development of Gloria in Early-Christian Latin ’56.—RAC IV 210–16; XI 196–225.—B. 1144f. DELG s.v. δοκάω etc. II p. 291. Schmidt, Syn. I 321–28, s. δοκέω. M-M. EDNT. TW. Spicq. Sv.

Computers

   1) A Comparison of the Digital Computer and the Brain

   The brain has been compared to a digital computer because the neuron, like a switch or valve, either does or does not complete a circuit. But at that point the similarity ends. The switch in the digital computer is constant in its effect, and its effect is large in proportion to the total output of the machine. The effect produced by the neuron varies with its recovery from [the] refractory phase and with its metabolic state. The number of neurons involved in any action runs into millions so that the influence of any one is negligible.... Any cell in the system can be dispensed with.... The brain is an analogical machine, not digital. Analysis of the integrative activities will probably have to be in statistical terms. (Lashley, quoted in Beach, Hebb, Morgan & Nissen, 1960, p. 539)

   2) Computers Do Not Crunch Numbers, They Manipulate Symbols

   It is essential to realize that a computer is not a mere "number cruncher," or supercalculating arithmetic machine, although this is how computers are commonly regarded by people having no familiarity with artificial intelligence. Computers do not crunch numbers; they manipulate symbols.... Digital computers originally developed with mathematical problems in mind, are in fact general purpose symbol manipulating machines....

   The terms "computer" and "computation" are themselves unfortunate, in view of their misleading arithmetical connotations. The definition of artificial intelligence previously cited-"the study of intelligence as computation"-does not imply that intelligence is really counting. Intelligence may be defined as the ability creatively to manipulate symbols, or process information, given the requirements of the task in hand. (Boden, 1981, pp. 15, 16-17)

   3) Getting Computers to Explain Things to Themselves

   The task is to get computers to explain things to themselves, to ask questions about their experiences so as to cause those explanations to be forthcoming, and to be creative in coming up with explanations that have not been previously available. (Schank, 1986, p. 19)

   4) Some Limits of Artificial Intelligence

   In What Computers Can't Do, written in 1969 (2nd edition, 1972), the main objection to AI was the impossibility of using rules to select only those facts about the real world that were relevant in a given situation. The "Introduction" to the paperback edition of the book, published by Harper & Row in 1979, pointed out further that no one had the slightest idea how to represent the common sense understanding possessed even by a four-year-old. (Dreyfus & Dreyfus, 1986, p. 102)

   5) The Computer as a Humanizing Influence

   A popular myth says that the invention of the computer diminishes our sense of ourselves, because it shows that rational thought is not special to human beings, but can be carried on by a mere machine. It is a short stop from there to the conclusion that intelligence is mechanical, which many people find to be an affront to all that is most precious and singular about their humanness.

   In fact, the computer, early in its career, was not an instrument of the philistines, but a humanizing influence. It helped to revive an idea that had fallen into disrepute: the idea that the mind is real, that it has an inner structure and a complex organization, and can be understood in scientific terms. For some three decades, until the 1940s, American psychology had lain in the grip of the ice age of behaviorism, which was antimental through and through. During these years, extreme behaviorists banished the study of thought from their agenda. Mind and consciousness, thinking, imagining, planning, solving problems, were dismissed as worthless for anything except speculation. Only the external aspects of behavior, the surface manifestations, were grist for the scientist's mill, because only they could be observed and measured....

   It is one of the surprising gifts of the computer in the history of ideas that it played a part in giving back to psychology what it had lost, which was nothing less than the mind itself. In particular, there was a revival of interest in how the mind represents the world internally to itself, by means of knowledge structures such as ideas, symbols, images, and inner narratives, all of which had been consigned to the realm of mysticism. (Campbell, 1989, p. 10)

   6) The Intentionality of Computers Is Essentially Borrowed, Hence Derivative

   [Our artifacts] only have meaning because we give it to them; their intentionality, like that of smoke signals and writing, is essentially borrowed, hence derivative. To put it bluntly: computers themselves don't mean anything by their tokens (any more than books do)-they only mean what we say they do. Genuine understanding, on the other hand, is intentional "in its own right" and not derivatively from something else. (Haugeland, 1981a, pp. 32-33)

   7) The Possibility of Computer Thought

   he debate over the possibility of computer thought will never be won or lost; it will simply cease to be of interest, like the previous debate over man as a clockwork mechanism. (Bolter, 1984, p. 190)

   8) We Are Getting Better at Building Even Better Computers, an Ever- Escalating Upward Spiral

   t takes us a long time to emotionally digest a new idea. The computer is too big a step, and too recently made, for us to quickly recover our balance and gauge its potential. It's an enormous accelerator, perhaps the greatest one since the plow, twelve thousand years ago. As an intelligence amplifier, it speeds up everything-including itself-and it continually improves because its heart is information or, more plainly, ideas. We can no more calculate its consequences than Babbage could have foreseen antibiotics, the Pill, or space stations.

   Further, the effects of those ideas are rapidly compounding, because a computer design is itself just a set of ideas. As we get better at manipulating ideas by building ever better computers, we get better at building even better computers-it's an ever-escalating upward spiral. The early nineteenth century, when the computer's story began, is already so far back that it may as well be the Stone Age. (Rawlins, 1997, p. 19)

   9) Weak Artificial Intelligence and Strong Artificial Intelligence

   According to weak AI, the principle value of the computer in the study of the mind is that it gives us a very powerful tool. For example, it enables us to formulate and test hypotheses in a more rigorous and precise fashion than before. But according to strong AI the computer is not merely a tool in the study of the mind; rather the appropriately programmed computer really is a mind in the sense that computers given the right programs can be literally said to understand and have other cognitive states. And according to strong AI, because the programmed computer has cognitive states, the programs are not mere tools that enable us to test psychological explanations; rather, the programs are themselves the explanations. (Searle, 1981b, p. 353)

    10) Why People Are Smarter Than Computers

   What makes people smarter than machines? They certainly are not quicker or more precise. Yet people are far better at perceiving objects in natural scenes and noting their relations, at understanding language and retrieving contextually appropriate information from memory, at making plans and carrying out contextually appropriate actions, and at a wide range of other natural cognitive tasks. People are also far better at learning to do these things more accurately and fluently through processing experience.

   What is the basis for these differences? One answer, perhaps the classic one we might expect from artificial intelligence, is "software." If we only had the right computer program, the argument goes, we might be able to capture the fluidity and adaptability of human information processing. Certainly this answer is partially correct. There have been great breakthroughs in our understanding of cognition as a result of the development of expressive high-level computer languages and powerful algorithms. However, we do not think that software is the whole story.

   In our view, people are smarter than today's computers because the brain employs a basic computational architecture that is more suited to deal with a central aspect of the natural information processing tasks that people are so good at.... hese tasks generally require the simultaneous consideration of many pieces of information or constraints. Each constraint may be imperfectly specified and ambiguous, yet each can play a potentially decisive role in determining the outcome of processing. (McClelland, Rumelhart & Hinton, 1986, pp. 3-4)

Grammar

   1) Grammar as Analogous to a Scientific Theory

   I think that the failure to offer a precise account of the notion "grammar" is not just a superficial defect in linguistic theory that can be remedied by adding one more definition. It seems to me that until this notion is clarified, no part of linguistic theory can achieve anything like a satisfactory development.... I have been discussing a grammar of a particular language here as analogous to a particular scientific theory, dealing with its subject matter (the set of sentences of this language) much as embryology or physics deals with its subject matter. (Chomsky, 1964, p. 213)

   2) Native Speakers and Their Grammar

   Obviously, every speaker of a language has mastered and internalized a generative grammar that expresses his knowledge of his language. This is not to say that he is aware of the rules of grammar or even that he can become aware of them, or that his statements about his intuitive knowledge of his language are necessarily accurate. (Chomsky, 1965, p. 8)

   3) The Reduction of Transformation Rules In a Science of Grammar

   Much effort has been devoted to showing that the class of possible transformations can be substantially reduced without loss of descriptive power through the discovery of quite general conditions that all such rules and the representations they operate on and form must meet.... [The] transformational rules, at least for a substantial core grammar, can be reduced to the single rule, "Move alpha" (that is, "move any category anywhere"). (Mehler, Walker & Garrett, 1982, p. 21)

   4) The Relationship of Transformational Grammar to Semantics and to Human Performance

   he implications of assuming a semantic memory for what we might call "generative psycholinguistics" are: that dichotomous judgments of semantic well-formedness versus anomaly are not essential or inherent to language performance; that the transformational component of a grammar is the part most relevant to performance models; that a generative grammar's role should be viewed as restricted to language production, whereas sentence understanding should be treated as a problem of extracting a cognitive representation of a text's message; that until some theoretical notion of cognitive representation is incorporated into linguistic conceptions, they are unlikely to provide either powerful language-processing programs or psychologically relevant theories.

   Although these implications conflict with the way others have viewed the relationship of transformational grammars to semantics and to human performance, they do not eliminate the importance of such grammars to psychologists, an importance stressed in, and indeed largely created by, the work of Chomsky. It is precisely because of a growing interdependence between such linguistic theory and psychological performance models that their relationship needs to be clarified. (Quillian, 1968, p. 260)

   5) The Terminologies of Formal Grammar

   here are some terminological distinctions that are crucial to explain, or else confusions can easily arise. In the formal study of grammar, a language is defined as a set of sentences, possibly infinite, where each sentence is a string of symbols or words. One can think of each sentence as having several representations linked together: one for its sound pattern, one for its meaning, one for the string of words constituting it, possibly others for other data structures such as the "surface structure" and "deep structure" that are held to mediate the mapping between sound and meaning. Because no finite system can store an infinite number of sentences, and because humans in particular are clearly not pullstring dolls that emit sentences from a finite stored list, one must explain human language abilities by imputing to them a grammar, which in the technical sense is a finite rule system, or programme, or circuit design, capable of generating and recognizing the sentences of a particular language. This "mental grammar" or "psychogrammar" is the neural system that allows us to speak and understand the possible word sequences of our native tongue. A grammar for a specific language is obviously acquired by a human during childhood, but there must be neural circuitry that actually carries out the acquisition process in the child, and this circuitry may be called the language faculty or language acquisition device. An important part of the language faculty is universal grammar, an implementation of a set of principles or constraints that govern the possible form of any human grammar. (Pinker, 1996, p. 263)

   6) The Theory of Grammar

   A grammar of language L is essentially a theory of L. Any scientific theory is based on a finite number of observations, and it seeks to relate the observed phenomena and to predict new phenomena by constructing general laws in terms of hypothetical constructs.... Similarly a grammar of English is based on a finite corpus of utterances (observations), and it will contain certain grammatical rules (laws) stated in terms of the particular phonemes, phrases, etc., of English (hypothetical constructs). These rules express structural relations among the sentences of the corpus and the infinite number of sentences generated by the grammar beyond the corpus (predictions). (Chomsky, 1957, p. 49)

технологии для автоматизации

1. automation technologies

 

технологии для автоматизации
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[Интент]

Параллельные тексты EN-RU

Automation technologies: a strong focal point for our R&D

Технологии для автоматизации - одна из главных тем наших научно исследовательских разработок

Automation is an area of ABB’s business with an extremely high level of technological innovation.

Автоматика относится к одной из областей деятельности компании АББ, для которой характерен исключительно высокий уровень технических инноваций.

In fact, it may be seen as a showcase for exhibiting the frontiers of development in several of today’s emerging technologies, like short-range wireless communication and microelectromechanical systems (MEMS).

В определенном смысле ее можно уподобить витрине, в которой выставлены передовые разработки из области только еще зарождающихся технологий, примерами которых являются ближняя беспроводная связь и микроэлектромеханические системы (micro electromechanical systems MEMS).

Mechatronics – the synthesis of mechanics and electronics – is another very exciting and rapidly developing area, and the foundation on which ABB has built its highly successful, fast-growing robotics business.

Еще одной исключительно интересной быстро развивающейся областью и в то же время фундаментом, на котором АББ в последнее время строит свой исключительно успешный и быстро расширяющийся бизнес в области робототехники, является мехатроника - синтез механики с электроникой.

Robotic precision has now reached the levels we have come to expect of the watch-making industry, while robots’ mechanical capabilities continue to improve significantly.

Точность работы робототехнических устройств достигла сегодня уровней, которые мы привыкли ожидать только на предприятиях часовой промышленности. Большими темпами продолжают расти и механические возможности роботов.

Behind the scenes, highly sophisticated electronics and software control every move these robots make.

А за кулисами всеми перемещениями робота управляют сложные электронные устройства и компьютерные программы.

Throughout industry today we see a major shift of ‘intelligence’ to lower levels in the automation system hierarchy, leading to a demand for more communication within the system.

Во всех отраслях промышленности сегодня наблюдается интенсивный перенос "интеллекта" на нижние уровни иерархии автоматизированных систем, что требует дальнейшего развития внутрисистемных средств обмена.

‘Smart’ transmitters, with powerful microprocessors, memory chips and special software, carry out vital operations close to the processes they are monitoring.

"Интеллектуальные" датчики, снабженные высокопроизводительными микропроцессорами, мощными чипами памяти и специальным программно-математическим обеспечением, выполняют особо ответственные операции в непосредственной близости от контролируемых процессов.

And they capture and store data crucial for remote diagnostics and maintenance.

Они же обеспечивают возможность измерения и регистрации информации, крайне необходимой для дистанционной диагностики и дистанционного обслуживания техники.

The communication highway linking such systems is provided by fieldbuses.

В качестве коммуникационных магистралей, связывающих такого рода системы, служат промышленные шины fieldbus.

In an ideal world there would be no more than a few, preferably just one, fieldbus standard.

В идеале на промышленные шины должно было бы существовать небольшое количество, а лучше всего вообще только один стандарт.

However, there are still too many of them, so ABB has developed ‘fieldbus plugs’ that, with the help of translation, enable devices to communicate across different standards.

К сожалению, на деле количество их типов продолжает оставаться слишком разнообразным. Ввиду этой особенности рынка промышленных шин компанией АББ разработаны "штепсельные разъемы", которые с помощью средств преобразования обеспечивают общение различных устройств вопреки границам, возникшим из-за различий в стандартах.

This makes life easier as well as less costly for our customers. Every automation system is dependent on an electrical network for distributing – and interrupting, when necessary – the power needed to carry out its various functions.

Это, безусловно, не только облегчает, но и удешевляет жизнь нашим заказчикам. Ни одна система автоматики не может работать без сети, обеспечивающей подачу, а при необходимости и отключение напряжения, необходимого для выполнения автоматикой своих задач.

Here, too, we see a clear trend toward more intelligence and communication, for example in traditional electromechanical devices such as contactors and switches.

И здесь наблюдаются отчетливо выраженные тенденции к повышению уровня интеллектуальности и расширению возможностей связи, например, в таких традиционных электромеханических устройствах, как контакторы и выключатели.

We are pleased to see that our R&D efforts in these areas over the past few years are bearing fruit.

Мы с удовлетворением отмечаем, что научно-исследовательские разработки, выполненные нами за последние годы в названных областях, начинают приносить свои плоды.

Recently, we have seen a strong increase in the use of wireless technology in industry.

В последнее время на промышленных предприятиях наблюдается резкое расширение применения техники беспроводной связи.

This is a key R&D area at ABB, and several prototype applications have already been developed.

В компании АББ эта область также относится к числу одной из ключевых тем научно-исследовательских разработок, результатом которых стало создание ряда опытных образцов изделий практического направления.

At the international Bluetooth Conference in Amsterdam in June 2002, we presented a truly ‘wire-less’ proximity sensor – with even a wireless power supply.

На международной конференции по системам Bluetooth, состоявшейся в Амстердаме в июне 2002 г., наши специалисты выступили с докладом о поистине "беспроводном" датчике ближней локации, снабженном опять-таки "беспроводным" источником питания.

This was its second major showing after the launch at the Hanover Fair.

На столь крупном мероприятии это устройство демонстрировалось во второй раз после своего первого показа на Ганноверской торгово-промышленной ярмарке.

Advances in microelectronic device technology are also having a profound impact on the power electronics systems around which modern drive systems are built.

Достижения в области микроэлектроники оказывают также глубокое влияние на системы силовой электроники, лежащие в основе современных приводных устройств.

The ABB drive family ACS 800 is visible proof of this.

Наглядным тому доказательством может служить линейка блоков регулирования частоты вращения электродвигателей ACS-800, производство которой начато компанией АББ.

Combining advanced trench gate IGBT technology with efficient cooling and innovative design, this drive – for motors rated from 1.1 to 500 kW – has a footprint for some power ranges which is six times smaller than competing systems.

Предназначены они для двигателей мощностью от 1,1 до 500 кВт. В блоках применена новейшая разновидность приборов - биполярные транзисторы с изолированным желобковым затвором (trench gate IGBT) в сочетании с новыми конструктивными решениями, благодаря чему в отдельных диапазонах мощностей габариты блоков удалось снизить по сравнению с конкурирующими изделиями в шесть раз.

To get the maximum benefit out of this innovative drive solution we have also developed a new permanent magnet motor.

Стремясь с максимальной пользой использовать новые блоки регулирования, мы параллельно с ними разработали новый двигатель с постоянными магнитами.

It uses neodymium iron boron, a magnetic material which is more powerful at room temperature than any other known today.

В нем применен новый магнитный материал на основе неодима, железа и бора, характеристики которого при комнатной температуре на сегодняшний день не имеют себе равных.

The combination of new drive and new motor reduces losses by as much as 30%, lowering energy costs and improving sustainability – both urgently necessary – at the same time.

Совместное использование нового блока регулирования частоты вращения с новым двигателем снижает потери мощности до 30 %, что позволяет решить сразу две исключительно актуальные задачи:
сократить затраты на электроэнергию и повысить уровень безотказности.

These innovations are utilized most fully, and yield the maximum benefit, when integrated by means of our Industrial IT architecture.

Потенциал перечисленных выше новых разработок используется в наиболее полной степени, а сами они приносят максимальную выгоду, если их интеграция осуществлена на основе нашей архитектуры IndustrialIT.

Industrial IT is a unique platform for exploiting the full potential of information technology in industrial applications.

IndustrialIT представляет собой уникальную платформу, позволяющую в максимальной степени использовать возможности информационных технологий применительно к задачам промышленности.

Consequently, our new products and technologies are Industrial IT Enabled, meaning that they can be integrated in the Industrial IT architecture in a ‘plug and produce’ manner.

Именно поэтому все наши новые изделия и технологии выпускаются в варианте, совместимом с архитектурой IndustrialIT, что означает их способность к интеграции с этой архитектурой по принципу "подключи и производи".

We are excited to present in this issue of ABB Review some of our R&D work and a selection of achievements in such a vital area of our business as Automation.

Мы рады представить в настоящем номере "АББ ревю" некоторые из наших научно-исследовательских разработок и достижений в такой жизненно важной для нашего бизнеса области, как автоматика.

R&D investment in our corporate technology programs is the foundation on which our product and system innovation is built.

Вклад наших разработок в общекорпоративные технологические программы группы АББ служит основой для реализации новых технических решений в создаваемых нами устройствах и системах.

Examples abound in the areas of control engineering, MEMS, wireless communication, materials – and, last but not least, software technologies. Enjoy reading about them.
[ABB Review]

Это подтверждается многочисленными примерами из области техники управления, микроэлектромеханических систем, ближней радиосвязи, материаловедения и не в последнюю очередь программотехники. Хотелось бы пожелать читателю получить удовольствие от чтения этих материалов.
[Перевод Интент]

Тематики

• автоматизированные системы

EN

• automation technologies