second+component

единственный в своём роде

•

Chemical pumping is unique in that the first component of a laser intrinsically supplies the second.

при повышении

. по мере того как

•

The sweep component beats with the second, third and fourth harmonics of the crystal oscillator as the sweep frequency increases.

с увеличением

. по мере того как; с повышением

•

The potential energy outside the metal decreases with distance from the surface.

•

Drill speeds decrease as drill diameters increase.

•

The sweep component beats with the second, third, and fourth harmonic as the sweep frequency increases.

•

As the length of the chain between... increases, so does the tendency of...

•

The amount of carbon formed tended to increase with increase in reaction temperature.

•

Corrosion rate increases with increasing (or increased) temperature.

•

The live load decreases with an increase in the floor area.

система двойная

• система f двойная

english: binary [two-component] system

deutsch: binäres System n, Zweikomponentensystem n

français: système m binaire [du second ordre]

вторая антистоксова компонента

Makarov: second anti-Stokes component

вторая гармоника

1) Engineering: quadratic component

2) Electronics: second harmonic

вторая стоксова компонента

Makarov: second Stokes component

момент

1) General subject: element, factor, inst, instant, juncture, minute, mo (half a mo - подождите минутку! одну минутку!), momentum, point (времени), sec, second, space, moment, milestone, stage, aspect (один из моментов выступления оратора касался...), period of time

2) Military: event (распорядка дня)

3) Engineering: instance

4) Mathematics: epoch, feature, heading, item, locality, moment coefficient, post, section, spot, subsection

5) Railway term: impetus

6) Australian slang: crack, tick

7) Automobile industry: disturbing moment

8) Electronics: derived average

9) Jargon: shake

10) Oil: time

11) Astronautics: couple

12) Mechanics: torque

13) Seismology: earthquake moment

14) Quality control: epoch (времени), moment (времени)

15) Robots: couple (сил), instant (времени), moment (силы), time (времени), torque (крутящий)

16) General subject: timing (впрыска, зажигания)

17) Makarov: breathing, inst (instant), instance (времени), instant of time, moment (напр. силы, инерции), moment (e. g., of a line or surface with respect to an axis) (напр. линии или поверхности относительно оси), momentum component, momentum conservation, snatch

18) Archaic: article

19) Bicycle: (tightening torque - момент затяжки torque (болта, гайки и т. д.)

20) SAP.tech. event

21) SAP.fin. callup point

22) General subject: n-th moment n-й

вторая гармоника

quadratic component

* * *

second harmonic

единственный в своём роде

•

Chemical pumping is unique in that the first component of a laser intrinsically supplies the second.

* * *

Единственный в своём роде-- It remained uncertain whether its unique geometry contributes to the ease or difficulty of actually constructing such shells.

объединять в один узел

Объединять в один узел-- The second bearing design combines the supporting rings and springs in a single component.

dio

fraction, feature

* * *

• element

• extent

• component

• second

• section

• deal

• whack

• slice

• share

• segment

• snack

• space

• portion

• proportion

• leg

• fragment

• fraction

• allotment

• arm

• article

• area

• piece

• picce

• partial detail

• particle

• part

• meed

• rate

• quota

• moiety

аортальный компонент второго тона

aortic component of the second heart sound

лёгочный компонент второго тона

pulmonic component of the second heart sound

Bailey, Sir Donald Coleman

SUBJECT AREA: Civil engineering

[br]

b. 15 September 1901 Rotherham, Yorkshire, England

d. 5 May 1985 Bournemouth, Dorset, England

[br]

English engineer, designer of the Bailey bridge.

[br]

Bailey was educated at the Leys School, Cambridge, before going to Sheffield University where he studied for a degree in engineering. He joined the Civil Service in 1928 and was posted to the staff of the Experimental Bridging Establishment of the Ministry of Supply at Christchurch, Hampshire. There he continued his boyhood hobby of making model bridges of wood and string. He evolved a design for a prefabricated metal bridge assembled from welded panels linked by pinned joints; this became known as the Bailey bridge. Its design was accepted by the War Office in 1941 and from then on it was used throughout the subsequent conflict of the Second World War. It was a great improvement on its predecessor, the Inglis bridge, designed by a Cambridge University professor of engineering, Charles Inglis, with tubular members that were 10 or 12 ft (3.66 m) long; this bridge was notoriously difficult to construct, particularly in adverse weather conditions, whereas the Bailey bridge's panels and joints were far more manageable and easy to assemble. The simple and standardized component parts of the Bailey bridge made it highly adaptable: it could be strengthened by increasing the number of truss girders, and wide rivers could be crossed by a series of Bailey bridges connected by pontoons. Field Marshal Montgomery is recorded as saying that without the Bailey bridge we should not have won the war'.

[br]

Principal Honours and Distinctions

Knighted 1946.

Further Reading

Obituary, 1985, The Guardian 6 May.

IMcN

Lanston, Tolbert

SUBJECT AREA: Paper and printing

[br]

b. 3 February 1844 Troy, Ohio, USA

d. 18 February 1913 Washington, DC, USA

[br]

American inventor of the Monotype typesetting machine.

[br]

Although reared in a farming community, Lanston was able to develop his mechanical talent. After serving in the American Civil War he secured a clerkship in the Pensions Office in Washington, where he remained for twenty-two years. He studied law in his spare time and was called to the Bar. At the same time, he invented a whole variety of mechanical devices, many of which he patented. Around 1883 Lanston began taking an interest in machines for composing printers' type, probably stimulated by Ottmar Mergenthaler, who was then in Washington and working in this field. Four years' work were rewarded on 7 June 1887 by the grant of a patent, followed by three more, for a machine "to produce justified lines of type". The machine, the Monotype, consisted of two components: first a keyboard unit produced a strip of paper tape with holes punched in patterns corresponding to the characters required; this tape controlled the matrices in the caster, the second and "hot metal" component, from which types were ejected singly and fed to an assembly point until a complete line of type had been formed. Lanston resigned his post and set up the Lanston Type Machine Company in Washington. He laboured for ten years to convert the device defined in his patents into a machine that could be made and used commercially. In 1897 the perfected Monotype appeared. The company was reorganized as the Lanston Monotype Manufacturing Company of Philadelphia, and Lanston devoted himself to promoting and improving the machine. Monotype, with Mergenthaler's Linotype, steadily supplanted hand-setting and the various inadequate mechanical methods that were then in use, and by the 1920s they reigned supreme, until the 1960s, when they themselves began to be superseded by computer-controlled photosetting methods.

[br]

Principal Honours and Distinctions

Franklin Institute Cresson Gold Medal 1896.

Further Reading

Obituary, 1913, American Printer (March).

L.A.Legros and J.C.Grant, 1916, Typographical Printing Surfaces, London.

J.Moran, 1964, The Composition of Reading Matter, London.

LRD

Symington, William

SUBJECT AREA: Ports and shipping

[br]

b. 1764 Leadhills, Lanarkshire, Scotland

d. 22 March 1831 Wapping, London, England

[br]

Scottish pioneer of steam navigation.

[br]

Symington was the son of the Superintendent of the Mines Company in Lanarkshire, and attended the local school. When he was 22 years old he was sent by Gilbert Meason, Manager of the Wanlockhead mines, to Edinburgh University. In 1779 he was working on the assembly of a Watt engine as an apprentice to his brother, George, and in 1786 he started experiments to modify a Watt engine in order to avoid infringing the separate condenser patent. He sought a patent for his alternative, which was paid for by Meason. He constructed a model steam road carriage which was completed in 1786; it was shown in Edinburgh by Meason, attracting interest but inadequate financial support. It had a horizontal cylinder and was non-condensing. No full-sized engine was ever built but the model secured the interest of Patrick Miller, an Edinburgh banker, who ordered an engine from Symington to drive an experimental boat, 25 ft (7.6 m) long with a dual hull, which performed satisfactorily on Dalswinton Loch in 1788. In the following year Miller ordered a larger engine for a bigger boat which was tried on the Forth \& Clyde Canal in December 1789, the component parts having been made by the Carron Company. The engine worked perfectly but had the effect of breaking the paddle wheels. These were repaired and further trials were successful but Miller lost interest and his experiments lapsed. Symington devoted himself thereafter to building stationary engines. He built other engines for mine pumping at Sanquhar and Leadhills before going further afield. In all, he built over thirty engines, about half of them being rotary. In 1800–1 he designed the engine for a boat for Lord Dundas, the Charlotte Dundas; this was apparently the first boat of that name and sailed on both the Forth and Clyde rivers. A second Charlotte Dundas with a horizontal cylinder was to follow and first sailed in January 1803 for the Forth \& Clyde Canal Company. The speed of the boat was only 2 mph (3 km/h) and much was made by its detractors of the damage said to be caused to the canal banks by its wash. Lord Dundas declined to authorize payment of outstanding accounts; Symington received little reward for his efforts. He died in the house of his son-in-law, Dr Robert Bowie, in Wapping, amidst heated controversy about the true inventor of steam navigation.

[br]

Further Reading

W.S.Harvey and G.Downs-Rose, 1980, William Symington, Inventor and Engine- Builder, London: Mechanical Engineering Publications.

IMcN

Williams, Sir Frederic Calland

SUBJECT AREA: Electronics and information technology

[br]

b. 26 June 1911 Stockport, Cheshire, England

d. 11 August 1977 Prestbury, Cheshire, England

[br]

English electrical engineer who invented the Williams storage cathode ray tube, which was extensively used worldwide as a data memory in the first digital computers.

[br]

Following education at Stockport Grammar School, Williams entered Manchester University in 1929, gaining his BSc in 1932 and MSc in 1933. After a short time as a college apprentice with Metropolitan Vickers, he went to Magdalen College, Oxford, to study for a DPhil, which he was awarded in 1936. He returned to Manchester University that year as an assistant lecturer, gaining his DSc in 1939. Following the outbreak of the Second World War he worked for the Scientific Civil Service, initially at the Bawdsey Research Station and then at the Telecommunications Research Establishment at Malvern, Worcestershire. There he was involved in research on non-incandescent amplifiers and diode rectifiers and the development of the first practical radar system capable of identifying friendly aircraft. Later in the war, he devised an automatic radar system suitable for use by fighter aircraft.

After the war he resumed his academic career at Manchester, becoming Professor of Electrical Engineering and Director of the University Electrotechnical Laboratory in 1946. In the same year he succeeded in developing a data-memory device based on the cathode ray tube, in which the information was stored and read by electron-beam scanning of a charge-retaining target. The Williams storage tube, as it became known, not only found obvious later use as a means of storing single-frame, still television images but proved to be a vital component of the pioneering Manchester University MkI digital computer. Because it enabled both data and program instructions to be stored in the computer, it was soon used worldwide in the development of the early stored-program computers.

[br]

Principal Honours and Distinctions

Knighted 1976. OBE 1945. CBE 1961. FRS 1950. Hon. DSc Durham 1964, Sussex 1971, Wales 1971. First Royal Society of Arts Benjamin Franklin Medal 1957. City of Philadelphia John Scott Award 1960. Royal Society Hughes Medal 1963. Institution of Electrical Engineers Faraday Medal 1972. Institute of Electrical and Electronics Engineers Pioneer Award 1973.

Bibliography

Williams contributed papers to many scientific journals, including Proceedings of the Royal Society, Proceedings of the Cambridge Philosophical Society, Journal of the Institution of Electrical Engineers, Proceedings of the Institution of Mechanical Engineers, Wireless Engineer, Post Office Electrical Engineers' Journal. Note especially: 1948, with J.Kilburn, "Electronic digital computers", Nature 162:487; 1949, with J.Kilburn, "A storage system for use with binary digital computing machines", Proceedings of the Institution of Electrical Engineers 96:81; 1975, "Early computers at Manchester University", Radio \& Electronic Engineer 45:327. Williams also collaborated in the writing of vols 19 and 20 of the MIT Radiation

Laboratory Series.

Further Reading

B.Randell, 1973, The Origins of Digital Computers, Berlin: Springer-Verlag. M.R.Williams, 1985, A History of Computing Technology, London: Prentice-Hall. See also: Stibitz, George R.; Strachey, Christopher.

KF

κανών

κανών, όνος, ὁ (Hom. et al.; ins, pap, LXX; TestNapht 2:3. For the mngs. of the word [primarily ‘straight rod’] s. TZahn, Grundriss d. Gesch. d. ntl. Kanons² 1904, 1ff; HOppel, ΚΑΝΩΝ: Philol. Suppl. 30, 4, ’37; LWenger, Canon: SBWienAk 220, 2, ’42) the mngs. found in our lit. are

① a means to determine the quality of someth., rule, standard (Eur., Hec. 602; Demosth. 18, 296; Aeschin., In Ctesiph. 66; Sext. Emp., Log. 2, 3; Ps.-Plut., Consol. ad Ap. 103a; Epict., index Sch.; Lucian, Pisc. 30; UPZ 110, 58 [164 B.C.]; PLond I, 130, 12 p. 133 [I/II A.D.]; 4 Macc 7:21; EpArist 2; Philo; Jos., Ant. 10, 49, C. Ap. 2, 174; TestNapht 2:3) τῷ κανόνι τούτῳ στοιχεῖν Gal 6:16; Phil 3:16 v.l.; ἔλθωμεν ἐπὶ τὸν τῆς παραδόσεως ἡμῶν κανόνα 1 Cl 7:2 (cp. Epict. 1, 28, 28 ἔλθωμεν ἐπὶ τοὺς κανόνας; τὸν κ. ἀληθείας …, ὸ̔ν διὰ τοῦ βαπτίσματος εἴληφεν Iren. 1, 9, 4 [Harv. I 88, 1]).

② set of directions or formulation for an activity, assignment, formulation for public service (s. λειτουργία 1; ins New Docs 1, p. 37, ln. 29 κατὰ πόλιν καὶ κώμην ἔταξα κανόνα τῶν ὑπηρεσιῶν ‘I have promulgated in the individual cities and villages a schedule of what I judge desirable to be supplied’ [tr. Horsley]) ἐν τῷ κανόνι τῆς ὑποταγῆς ὐπάρχειν 1 Cl 1:3. παρεκβαίνειν τὸν ὡρισμένον τῆς λειτουργίας κανόνα 41:1. Sim. of the mission assignment given to Paul, which included directions about geographical area 2 Cor 10:13, 15f (s. FStrange, BA 46, ’83, 167f; AdeOliveira, Die Diakonie der Gerechtigkeit und der Versöhnung in der Apologie des 2. Korintherbriefes ’90, 141–42, n. 306: κ. signifies the apostle’s mission assignment). Others (incl. NRSV, REB) emphasize the geographical component and render sphere (of action), province, limit.

③ In the second century in the Christian church κ. came to stand for revealed truth, rule of faith (Zahn, RE VI 683ff.—Cp. Philo, Leg. All. 3, 233 ὁ διαφθείρων τὸν ὑγιῆ κανόνα τῆς ἀληθείας; Synes., Ad. Paeon. 4 p. 310d τῆς ἀληθείας κανών of mathematics; Hippol., Ref. 10, 5, 2). ἐκκλησιαστικὸς καὶ καθολικὸς κ. EpilMosq 2. ᾧ παρέλαβε κανόνι by the rule that the person has received AcPlCor 2:36.—The use of κανών as ‘list’ in ref. to the canonical scriptures, as well as in the sense of ‘(synodical-) canon’, is late.—RGG³ III, 1116–22. TRE XVII ’88, 562–70. New Docs 2, 88f. DELG (lit.). M-M. TW. Sv.

πάλιν

πάλιν adv. (Hom.+). On the spelling s. B-D-F §20, end; Mlt-H. 113).

① pert. to return to a position or state, back

ⓐ w. verbs of going, sending, turning, calling etc. πάλιν ἄγειν go back, return J 11:7. ἀναβαίνειν Gal 2:1. ἀναχωρεῖν J 6:15. ἀποστέλλειν send back Mk 11:3. διαπερᾶν 5:21. ἔρχεσθαι (Jos., Ant. 2, 106; 11, 243) Mt 26:43; Mk 11:27; J 4:46; 2 Cor 1:16. ἀπέρχεσθαι Mk 14:39; J 4:3. εἰσέρχεσθαι Mk 2:1 (ParJer 7:22). ἐξέρχεσθαι 7:31 (ParJer 9:12). ἐπιστρέφειν turn back Gal 4:9a. παραγίνεσθαι J 8:2, etc. πάλιν λαβεῖν take back (X., An. 4, 2, 13) 10:17f. παραλαβὼν πάλιν τοὺς δώδεκα he brought the twelve back (after he had been separated fr. them for a time, and had preceded them) Mk 10:32. ἀνεσπάσθη πάλιν ἅπαντα εἰς τ. οὐρανόν everything was drawn back into heaven Ac 11:10.—ἡ ἐμὴ παρουσία πάλιν πρὸς ὑμᾶς my return to you Phil 1:26.—Also pleonastically w. verbs that express the component ‘back’ (Eur., Ep. 1, 1 ἀναπέμπω πάλιν) πάλιν ἀνακάμπτειν (Bacchylides 17, 81f πάλιν ἀνεκάμπτετʼ; Synes., Kingship p. 29b) Ac 18:21. πάλιν ὑποστρέφειν Gal 1:17 (s. B-D-F §484; cp. Rob. 1205).

ⓑ in expressions that denote a falling back into a previous state or a return to a previous activity (TestAbr A 6 p. 89, 13 [Stone p. 14] ἠγέρθη πάλιν ὁ μόσχος; ApcMos 41 πάλιν τὴν ἀνάστασιν ἐπαγγέλομαί σοι; Just., A I, 18, 6; Tat. 11, 2). In Engl. mostly again. εἰ ἃ κατέλυσα ταῦτα πάλιν οἰκοδομῶ Gal 2:18. ἵνα πάλιν ἐπὶ τὸ αὐτὸ ἦτε 1 Cor 7:5. διψήσει πάλιν J 4:13. πάλιν εἰς φόβον Ro 8:15. Cp. 11:23; Gal 5:1; Phil 2:28; Hb 5:12; 6:6; 2 Pt 2:20.

② pert. to repetition in the same (or similar) manner, again, once more, anew of someth. a pers. has already done (TestAbr A 15 p. 96, 7 [Stone p. 40, 7]; TestJob 15:9; 44:2; JosAs 10:19; ParJer 9:21; Jos., Ant. 12, 109; Just., D. 3, 5 al.), of an event, or of a state or circumstance (Dicaearch., Fgm. 34 W. Pythagoras flees first to Καυλωνία … ἐκεῖθεν δὲ πάλιν εἰς Λοκρούς; ApcEsdr 4:13 κατήγαγόν με … καὶ πάλιν κατήγαγόν με βαθμοὺς τριάκοντα). πάλιν παραλαμβάνει αὐτὸν ὁ διάβολος εἰς ὄρος Mt 4:8 (cp. vs. 5). πάλιν ἐξελθών 20:5 (cp. vs. 3). πότε πάλιν ὄψονται αὐτόν when they would see (Paul) again AcPl Ha 6, 17. ἵνα παρά σου πάλιν ἀκούσωμεν AcPlCor 1:6.—Mt 21:36 (cp. vs. 34); 26:44 (cp. vs. 42), 72; 27:50; Mk 2:13; 3:1; 4:1. πάλιν πολλοῦ ὄχλου ὄντος 8:1 (cp. 6:34).—8:25; 10:1, 24; Lk 23:20 (cp. vs. 13); J 1:35 (cp. vs. 29); 8:8; 20:26; Ac 17:32; Gal 1:9; Phil 4:4; Js 5:18; Hv 3, 1, 5 al.; GJs 17:2; 23:2; AcPl Ha 4, 1.—Somet. w. additions which, in part, define πάλιν more exactly: πάλ. δεύτερον (cp. P. Argentor. Gr. 53, 5: Kl. T. 135 p. 47 τὸ δεύτερον πάλιν) J 21:16. πάλ. ἐκ δευτέρου (Ctesias: 688 Fgm. 14, 31 Jac.; 4 [6] Esdr [POxy 1010]; PCairMasp 24, 12) Mt 26:42; Ac 10:15. Also pleonastically πάλ. ἄνωθεν Gal 4:9b (s. ἄνωθεν 4). αὖ πάλιν Papias (2:9) (cp. Just., A I, 20, 2). πάλιν ἐξ ἀρχῆς (Mnesimachus Com. [IV B.C.] 4, 24; Diod S 17, 37, 5) B 16:8.—εἰς τὸ πάλιν= πάλιν 2 Cor 13:2 (on this s. WSchmid, Der Attizismus 1887–97, I 167; II 129; III 282; IV 455; 625).

③ marker of a discourse or narrative item added to items of a related nature, also, again, furthermore, thereupon (Ps.-Pla., Eryx. 11, 397a καὶ π. with a series of examples): very oft. in a series of quotations fr. scripture (cp. Diod S 37, 30, 2 καὶ πάλιν … καὶ … followed both times by a poetic quotation; a third one had preceded these. All three deal with riches as the highest good and probably come from a collection of quotations; Ps.-Demetr. c. 184 καὶ πάλιν … καὶ π. with one quotation each. Cp. also Diod S 1, 96, 6; Diog. L. 2, 18; 3, 16; Athen. 4, 17, 140c; 14, 634d; Plut., Mor. 361a καὶ πάλιν … καὶ … ; a quotation follows both times; Just., A I, 35, 5; 38, 2 al.; Ath. 9, 1 al.) J 12:39; 19:37; Ro 15:10–12; 1 Cor 3:20; Hb 1:5; 2:13ab; 4:5; 10:30; 1 Cl 10:4; 15:3f; 16:15; 17:6; 26:3; B 2:7; B 3:1; B 6:2, B 4, B 6, B 14, B 16 and oft. In a series of parables (Simplicius, In Epict. p. 111, 13–34 connects by means of π. two stories that are along the same lines as the Good Samaritan and the Pharisee and the publican; Kephal. I 76, 34; 77, 8 [a series of proverbs]) Lk 13:20 (cp. vs. 18). Also a favorite expr. when a speaker takes up a formula previously used and continues: πάλιν ἠκούσατε Mt 5:33 (cp. vs. 27). πάλιν ὁμοία ἐστὶν ἡ βασιλεία 13:45 (cp. vs. 44), 47.—18:19 (cp. vs. 18); 19:24 (cp. vs. 23).

④ marker of contrast or an alternative aspect, on the other hand, in turn (Pla., Gorg. 482d; Theocr. 12, 14; Polyb. 10, 9, 1; Diod S 4, 46, 3; Chariton 7, 6, 9; Wsd 13:8; 16:23; 2 Macc 15:39; TestJob 26:4; GrBar 4:15; Just., D. 41, 4 al.) πάλιν γέγραπται on the other hand, it is written Mt 4:7. πάλ. Ἀνδρέας Andrew in turn J 12:22 v.l.—1 Cor 12:21. τοῦτο λογιζέσθω πάλ. ἐφʼ ἐαυτοῦ let him remind himself, on the other hand 2 Cor 10:7; on the other hand Lk 6:43; 1J 2:8.

⑤ A special difficulty is presented by Mk 15:13, where the first outcry of the crowd is reported w. the words οἱ δὲ πάλιν ἔκραξεν. Is it simply a connective (so δὲ πάλιν Ps.-Callisth. 2, 21, 22; POxy 1676, 20 ἀλλὰ καὶ λυποῦμαι πάλιν ὅτι ἐκτός μου εἶ)? Is it because a different source is here used? Or is the meaning they shouted back? (so Goodsp.); s. 1a. Or is this really a second outcry, and is the first one hidden behind vs. 8 or 11? Acc. to the parallel Mt 27:21f, which actually mentions several outcries, one after the other, the first one may have been: τὸν Βαραββᾶν. The πάλιν of J 18:40 is also hard to explain (Bultmann 502; 509, 3). Could there be a connection here betw. Mk and J?—Another possibility would be to classify Mk 15:13 and J 18:40 under 4 above, with the meaning in turn (Aristoph., Acharn. 342 et al.; s. L-S-J-M). On a poss. Aram. background s. JHudson, ET 53, ’41/42, 267f; Mlt-H. 446; Mlt-Turner 229; MBlack, An Aramaic Approach³, ’67, 112f.—B. 989. DELG. M-M.