background+area

выходить

I выход`ить

несов. - выходи́ть, сов. - вы́йти

1) (из; оставлять пределы чего-л) go out (of); leave (d); (из вагона и т.п.) alight (from), get out (of)

вы́йдите (отсю́да)! — leave this place!

выходить и́з дому — go out (of the house), leave the house

выходить с боя́ми из окруже́ния — fight one's way out of encirclement

2) (из; прекращать участие) leave (d)

выходить из соста́ва (рд.) — leave (d), withdraw (from); drop out (of)

выходить из федера́ции — secede from the federation

выходить из игры́ — drop out of the game

выходить из па́ртии — stop / discontinue one's membership of a party

выходить из бо́я — break off the fight, disengage, come out of action

выходить из войны́ — drop out of the war

выходить из сети́ информ. — log out / off (from the network)

3) (приходить куда-л, появляться) go; come; appear

выходить на у́лицу — go into the street; ( погулять) go out of doors

выходить на рабо́ту — come to work; turn up for work

выходить на вы́зовы театр — take one's curtain call

4) ( отправляться) leave; depart

выходить в путь — set out

выходить в похо́д — set out on a walking trip

выходить в мо́ре — put to sea, put out

5) (куда́-л; достигать) reach (d); attain (d); come (to)

выходить на грани́цу [к рубежу́, в райо́н] воен. — reach the frontier [line, area]

выходить на но́вые рубежи́ — reach new frontiers

6) (на вн.; приближаться к чему-л) come close [-s] (to); approach (d)

выходить на цель — approach the target

они вы́шли на реше́ние зада́чи — they have come close to a solution

7) (на вн.; переходить к чему-л, начинать что-л) start (d), initiate (d); switch over (to)

вы́йти на но́вую схе́му произво́дственного проце́сса — adopt [switch over to] a new process layout

8) (на вн.; получать доступ) access (d), come into contact (with)

он вы́шел на мини́стра — he gained access to the minister

9) ( издаваться) appear, be / come out, be published; (о приказе и т.п.) be issued

выходить в свет — appear, be out, be published

кни́га вы́йдет на бу́дущей неде́ле — the book will be out next week

10) (расходоваться; кончаться) run out; (тк. о сроке) be up

у него́ вы́шли все де́ньги — (all) his money has run out, he has run out of (all his) money, he has spent all his money

у него́ вы́шла вся бума́га — his paper has run out, he has run out of paper

срок выхо́дит — time is running out

срок уже́ вы́шел — time is up

11) (из чего́-л; получаться в результате) come (to), come out (of)

из э́того ничего́ не вы́йдет — nothing will come out of it, it will come to nothing

вы́шло совсе́м не так — it turned out quite different

отсю́да и вы́шли все неприя́тности — this was the origin / cause of all our problems

его́ докла́д вы́шел о́чень интере́сным — his lecture proved very interesting

всё вы́шло хорошо́ — everything has turned out well [all right]

из э́той мате́рии вы́шло о́чень краси́вое пла́тье — that material made a very pretty dress

12) (из кого́-л; формироваться, приобретать какие-л качества) make, be, become

из него́ вы́йдет хоро́ший инжене́р — he will make / be a good engineer

13) (быть родом, происходить) come (from)

он вы́шел из крестья́н — he has a rural background, he comes from a peasant family

он вы́шел из наро́да — he comes from a family of common people; he comes from the thick of the people

14) тк. несов. (куда́-л; быть обращённым в какую-л сторону) look (on, towards), face (d), front (d); (тк. об окнах) open (on), give (on)

ко́мната выхо́дит о́кнами на у́лицу — the room overlooks the street

ко́мната выхо́дит о́кнами на юг — the room looks south

окно́ выхо́дит в сад — the window opens [looks out] on the garden

••

вы́йти в лю́ди — make one's way (in life); get on in the world

выходить в отста́вку — retire

выходить в тира́ж — 1) (об облигации и т.п.) be drawn 2) тк. сов. разг. ( отойти от дел) have served one's time, retire from the scene; take a back number разг. 3) ( устаревать) become obsolete / out-of-date

выходить за́муж (за вн.) — marry (d)

выходить за преде́лы (рд.) — overstep the limits (of), exceed the bounds (of)

выходить из берего́в — overflow the banks

выходить из во́зраста (для) — be too old (for), be past the age (when), exceed the age limit (for); (для военной службы и т.п.) be over age

э́то не выходило у него́ из головы́ — he could not get it out of his head

выходить из мо́ды — go out of fashion

выходить из употребле́ния [обихо́да] — be no longer in use [-s], fall into disuse [-s], go out of use; become obsolete

выходить из стро́я — fail, break down

выходить из положе́ния — find a way out

выходить из себя́ — lose one's temper, fly into a rage; be beside oneself

выходить из терпе́ния — lose patience

выходить нару́жу — be revealed, come to light; come out into the open

выходить на связь — establish contact; ( по радио) go on the air ( for a radio contact)

само́ собо́й вы́шло — it came about quite naturally

он ро́стом не вы́шел разг. — he is anything but tall, he is short

был, да весь вы́шел погов. — ≈ there's none left of what there used to be

как бы чего́ не вы́шло! — you never know what might happen!

он бои́тся, как бы чего́ не вы́шло — he is afraid it might lead to trouble

II в`ыходить

сов. от выхаживать I, II

проверка анкетных данных

проверка анкетных данных

Проверка личности и послужного списка лица, включая, когда это допускается законодательством, любые случаи привлечения к уголовной ответственности, в рамках оценки возможности осуществления данным лицом контроля в целях безопасности и/или предоставления ему права допуска без сопровождения в охраняемую зону ограниченного доступа.

background check

A check of a person’s identity and previous experience, including where legally permissible, any criminal history as part of the assessment of an individual’s suitability to implement a security control and/or for unescorted access to a security restricted area.

(AN 17)

Official definition added to AN 17 by Amdt 10 (1/07/2002) and modified by Amdt 11 (2005).

педагогическая психология

educational psychology

Анализ процессов развития вместе с общей психологией обучения/учения дает исходный материал для педагогической психологии. Специалисты в этой области занимаются составлением рекомендаций по нормальным методам обучения, диагностированием источников отсталости или иных индивидуальных трудностей, а также обеспечением специальных средств корректировки. — The study of the developmental processes together with the general psychology of teaching and learning provide the background material for educational psychology. The specialists in this area are concerned to make recommendations concerning normal teaching techniques, to diagnose the sources of backwardness or other individual difficulty, and to provide special remedial facilities.

план

м. plan

составлять план — draw up a plan

уточнить план — refine the plan

генеральный план — master plot plan

грузовой план — cargo plan

задний план — background

маркшейдерский план — surveying plan

общий план — long shot

ориентационный план — key plan

передний план — foreground

перспективный план — long-term plan

план полёта — flight plan

аннулировать план полёта — cancel a flight plan

производственный план — production plan

план работ — work schedule

рабочий план — working plan

план расположения оборудования — equipment layout

план распределения частот — frequency plan

план расстановки вагонного парка — rolling stock plan

план скоростей — velocity diagram

план скоростей на входе — inlet velocity diagram

план скоростей на выходе — outlet-velocity diagram

средний план — medium shot

схематический план — diagrammatic plan

план телефонной сети — exchange area layout

укрупнённый план — ontime plan

уточнённый план — detail plan

план эксперимента — design of an experiment

план города — town plan

план трюмов — hold plan

план сцены — ground plan

план участка — plot plan

широкий план — big plans

scene

[siːn] noun

1) the place where something real or imaginary happens:

A murderer sometimes revisits the scene of his crime

The scene of this opera is laid/set in Switzerland.

مَشْهَد، مَنْظَر

2) an incident etc which is seen or remembered:

He recalled scenes from his childhood.

حادِث

3) a show of anger:

I was very angry but I didn't want to make a scene.

مَظْهَر غاضِب

4) a view of a landscape etc:

The sheep grazing on the hillside made a peaceful scene.

مَنْظَر، مَشْهَد

5) one part or division of a play etc:

The hero died in the first scene of the third act of the play.

مَشْهَد من المَسْرَحِيَّه

6) the setting or background for a play etc:

Scene-changing must be done quickly.

مَكان أو خَلْفِيَّة المَسْرَحِيَّه

7) a particular area of activity:

the academic/business scene.

مَجال، نِطاق، مَشْهَد

spot

[spɔt]

1. noun

1) a small mark or stain (made by mud, paint etc):

She was trying to remove a spot of grease from her skirt.

لَطْخَه

2) a small, round mark of a different colour from its background:

His tie was blue with white spots.

بُقْعَه

3) a pimple or red mark on the skin caused by an illness etc:

She had measles and was covered in spots.

بَثْرَه على الجِلْد

4) a place or small area, especially the exact place (where something happened etc):

There was a large number of detectives gathered at the spot where the body had been found.

مكان الحَدَث

5) a small amount:

Can I borrow a spot of sugar?

كَميَّه صَغيرَه

2. verb

– past tense, past participle ˈspotted

1) to catch sight of:

She spotted him eventually at the very back of the crowd.

يَرى

2) to recognize or pick out:

No-one watching the play was able to spot the murderer.

يَتَعَرَّف على

Economy

   Portugal's economy, under the influence of the European Economic Community (EEC), and later with the assistance of the European Union (EU), grew rapidly in 1985-86; through 1992, the average annual growth was 4-5 percent. While such growth rates did not last into the late 1990s, portions of Portugal's society achieved unprecedented prosperity, although poverty remained entrenched. It is important, however, to place this current growth, which includes some not altogether desirable developments, in historical perspective. On at least three occasions in this century, Portugal's economy has experienced severe dislocation and instability: during the turbulent First Republic (1911-25); during the Estado Novo, when the world Depression came into play (1930-39); and during the aftermath of the Revolution of 25 April, 1974. At other periods, and even during the Estado Novo, there were eras of relatively steady growth and development, despite the fact that Portugal's weak economy lagged behind industrialized Western Europe's economies, perhaps more than Prime Minister Antônio de Oliveira Salazar wished to admit to the public or to foreigners.

   For a number of reasons, Portugal's backward economy underwent considerable growth and development following the beginning of the colonial wars in Africa in early 1961. Recent research findings suggest that, contrary to the "stagnation thesis" that states that the Estado Novo economy during the last 14 years of its existence experienced little or no growth, there were important changes, policy shifts, structural evolution, and impressive growth rates. In fact, the average annual gross domestic product (GDP) growth rate (1961-74) was about 7 percent. The war in Africa was one significant factor in the post-1961 economic changes. The new costs of finance and spending on the military and police actions in the African and Asian empires in 1961 and thereafter forced changes in economic policy.

   Starting in 1963-64, the relatively closed economy was opened up to foreign investment, and Lisbon began to use deficit financing and more borrowing at home and abroad. Increased foreign investment, residence, and technical and military assistance also had effects on economic growth and development. Salazar's government moved toward greater trade and integration with various international bodies by signing agreements with the European Free Trade Association and several international finance groups. New multinational corporations began to operate in the country, along with foreign-based banks. Meanwhile, foreign tourism increased massively from the early 1960s on, and the tourism industry experienced unprecedented expansion. By 1973-74, Portugal received more than 8 million tourists annually for the first time.

   Under Prime Minister Marcello Caetano, other important economic changes occurred. High annual economic growth rates continued until the world energy crisis inflation and a recession hit Portugal in 1973. Caetano's system, through new development plans, modernized aspects of the agricultural, industrial, and service sectors and linked reform in education with plans for social change. It also introduced cadres of forward-looking technocrats at various levels. The general motto of Caetano's version of the Estado Novo was "Evolution with Continuity," but he was unable to solve the key problems, which were more political and social than economic. As the boom period went "bust" in 1973-74, and growth slowed greatly, it became clear that Caetano and his governing circle had no way out of the African wars and could find no easy compromise solution to the need to democratize Portugal's restive society. The economic background of the Revolution of 25 April 1974 was a severe energy shortage caused by the world energy crisis and Arab oil boycott, as well as high general inflation, increasing debts from the African wars, and a weakening currency. While the regime prescribed greater Portuguese investment in Africa, in fact Portuguese businesses were increasingly investing outside of the escudo area in Western Europe and the United States.

   During the two years of political and social turmoil following the Revolution of 25 April 1974, the economy weakened. Production, income, reserves, and annual growth fell drastically during 1974-76. Amidst labor-management conflict, there was a burst of strikes, and income and productivity plummeted. Ironically, one factor that cushioned the economic impact of the revolution was the significant gold reserve supply that the Estado Novo had accumulated, principally during Salazar's years. Another factor was emigration from Portugal and the former colonies in Africa, which to a degree reduced pressures for employment. The sudden infusion of more than 600,000 refugees from Africa did increase the unemployment rate, which in 1975 was 10-15 percent. But, by 1990, the unemployment rate was down to about 5-6 percent.

   After 1985, Portugal's economy experienced high growth rates again, which averaged 4-5 percent through 1992. Substantial economic assistance from the EEC and individual countries such as the United States, as well as the political stability and administrative continuity that derived from majority Social Democratic Party (PSD) governments starting in mid-1987, supported new growth and development in the EEC's second poorest country. With rapid infrastruc-tural change and some unregulated development, Portugal's leaders harbored a justifiable concern that a fragile environment and ecology were under new, unacceptable pressures. Among other improvements in the standard of living since 1974 was an increase in per capita income. By 1991, the average minimum monthly wage was about 40,000 escudos, and per capita income was about $5,000 per annum. By the end of the 20th century, despite continuing poverty at several levels in Portugal, Portugal's economy had made significant progress. In the space of 15 years, Portugal had halved the large gap in living standards between itself and the remainder of the EU. For example, when Portugal joined the EU in 1986, its GDP, in terms of purchasing power-parity, was only 53 percent of the EU average. By 2000, Portugal's GDP had reached 75 percent of the EU average, a considerable achievement. Whether Portugal could narrow this gap even further in a reasonable amount of time remained a sensitive question in Lisbon. Besides structural poverty and the fact that, in 2006, the EU largesse in structural funds (loans and grants) virtually ceased, a major challenge for Portugal's economy will be to reduce the size of the public sector (about 50 percent of GDP is in the central government) to increase productivity, attract outside investment, and diversify the economy. For Portugal's economic planners, the 21st century promises to be challenging.

    See also Empire, Portuguese overseas.

Armstrong, Edwin Howard

SUBJECT AREA: Broadcasting, Electronics and information technology, Telecommunications

[br]

b. 18 December 1890 New York City, New York, USA

d. 31 January 1954 New York City, New York, USA

[br]

American engineer who invented the regenerative and superheterodyne amplifiers and frequency modulation, all major contributions to radio communication and broadcasting.

[br]

Interested from childhood in anything mechanical, as a teenager Armstrong constructed a variety of wireless equipment in the attic of his parents' home, including spark-gap transmitters and receivers with iron-filing "coherer" detectors capable of producing weak Morse-code signals. In 1912, while still a student of engineering at Columbia University, he applied positive, i.e. regenerative, feedback to a Lee De Forest triode amplifier to just below the point of oscillation and obtained a gain of some 1,000 times, giving a receiver sensitivity very much greater than hitherto possible. Furthermore, by allowing the circuit to go into full oscillation he found he could generate stable continuous-waves, making possible the first reliable CW radio transmitter. Sadly, his claim to priority with this invention, for which he filed US patents in 1913, the year he graduated from Columbia, led to many years of litigation with De Forest, to whom the US Supreme Court finally, but unjustly, awarded the patent in 1934. The engineering world clearly did not agree with this decision, for the Institution of Radio Engineers did not revoke its previous award of a gold medal and he subsequently received the highest US scientific award, the Franklin Medal, for this discovery.

During the First World War, after some time as an instructor at Columbia University, he joined the US Signal Corps laboratories in Paris, where in 1918 he invented the superheterodyne, a major contribution to radio-receiver design and for which he filed a patent in 1920. The principle of this circuit, which underlies virtually all modern radio, TV and radar reception, is that by using a local oscillator to convert, or "heterodyne", a wanted signal to a lower, fixed, "intermediate" frequency it is possible to obtain high amplification and selectivity without the need to "track" the tuning of numerous variable circuits.

Returning to Columbia after the war and eventually becoming Professor of Electrical Engineering, he made a fortune from the sale of his patent rights and used part of his wealth to fund his own research into further problems in radio communication, particularly that of receiver noise. In 1933 he filed four patents covering the use of wide-band frequency modulation (FM) to achieve low-noise, high-fidelity sound broadcasting, but unable to interest RCA he eventually built a complete broadcast transmitter at his own expense in 1939 to prove the advantages of his system. Unfortunately, there followed another long battle to protect and exploit his patents, and exhausted and virtually ruined he took his own life in 1954, just as the use of FM became an established technique.

[br]

Principal Honours and Distinctions

Institution of Radio Engineers Medal of Honour 1917. Franklin Medal 1937. IERE Edison Medal 1942. American Medal for Merit 1947.

Bibliography

1922, "Some recent developments in regenerative circuits", Proceedings of the Institute of Radio Engineers 10:244.

1924, "The superheterodyne. Its origin, developments and some recent improvements", Proceedings of the Institute of Radio Engineers 12:549.

1936, "A method of reducing disturbances in radio signalling by a system of frequency modulation", Proceedings of the Institute of Radio Engineers 24:689.

Further Reading

L.Lessing, 1956, Man of High-Fidelity: Edwin Howard Armstrong, pbk 1969 (the only definitive biography).

W.R.Maclaurin and R.J.Harman, 1949, Invention \& Innovation in the Radio Industry.

J.R.Whitehead, 1950, Super-regenerative Receivers.

A.N.Goldsmith, 1948, Frequency Modulation (for the background to the development of frequency modulation, in the form of a large collection of papers and an extensive bibliog raphy).

KF

Bell, Alexander Graham

SUBJECT AREA: Telecommunications

[br]

b. 3 March 1847 Edinburgh, Scotland

d. 3 August 1922 Beinn Bhreagh, Baddeck, Cape Breton Island, Nova Scotia, Canada

[br]

Scottish/American inventor of the telephone.

[br]

Bell's grandfather was a professor of elocution in London and his father an authority on the physiology of the voice and on elocution; Bell was to follow in their footsteps. He was educated in Edinburgh, leaving school at 13. In 1863 he went to Elgin, Morayshire, as a pupil teacher in elocution, with a year's break to study at Edinburgh University; it was in 1865, while still in Elgin, that he first conceived the idea of the electrical transmission of speech. He went as a master to Somersetshire College, Bath (now in Avon), and in 1867 he moved to London to assist his father, who had taken up the grandfather's work in elocution. In the same year, he matriculated at London University, studying anatomy and physiology, and also began teaching the deaf. He continued to pursue the studies that were to lead to the invention of the telephone. At this time he read Helmholtz's The Sensations of Tone, an important work on the theory of sound that was to exert a considerable influence on him.

In 1870 he accompanied his parents when they emigrated to Canada. His work for the deaf gained fame in both Canada and the USA, and in 1873 he was apponted professor of vocal physiology and the mechanics of speech at Boston University, Massachusetts. There, he continued to work on his theory that sound wave vibrations could be converted into a fluctuating electric current, be sent along a wire and then be converted back into sound waves by means of a receiver. He approached the problem from the background of the theory of sound and voice production rather than from that of electrical science, and by 1875 he had succeeded in constructing a rough model. On 7 March 1876 Bell spoke the famous command to his assistant, "Mr Watson, come here, I want you": this was the first time a human voice had been transmitted along a wire. Only three days earlier, Bell's first patent for the telephone had been granted. Almost simultaneously, but quite independently, Elisha Gray had achieved a similar result. After a period of litigation, the US Supreme Court awarded Bell priority, although Gray's device was technically superior.

In 1877, three years after becoming a naturalized US citizen, Bell married the deaf daughter of his first backer. In August of that year, they travelled to Europe to combine a honeymoon with promotion of the telephone. Bell's patent was possibly the most valuable ever issued, for it gave birth to what later became the world's largest private service organization, the Bell Telephone Company.

Bell had other scientific and technological interests: he made improvements in telegraphy and in Edison's gramophone, and he also developed a keen interest in aeronautics, working on Curtiss's flying machine. Bell founded the celebrated periodical Science.

[br]

Principal Honours and Distinctions

Legion of Honour; Hughes Medal, Royal Society, 1913.

Further Reading

Obituary, 7 August 1922, The Times. Dictionary of American Biography.

R.Burlingame, 1964, Out of Silence into Sound, London: Macmillan.

LRD

Bigelow, Erastus Brigham

SUBJECT AREA: Textiles

[br]

b. 2 April 1814 West Boyleston, Massachusetts, USA

d. 6 December 1879 USA

[br]

American inventor of power looms for making lace and many types of carpets.

[br]

Bigelow was born in West Boyleston, Massachusetts, where his father struggled as a farmer, wheelwright, and chairmaker. Before he was 20, Bigelow had many different jobs, among them farm labourer, clerk, violin player and cotton-mill employee. In 1830, he went to Leicester Academy, Massachusetts, but he could not afford to go on to Harvard. He sought work in Boston, New York and elsewhere, making various inventions.

The most important of his early inventions was the power loom of 1837 for making coach lace. This loom contained all the essential features of his carpet looms, which he developed and patented two years later. He formed the Clinton Company for manufacturing carpets at Leicester, Massachusetts, but the factory became so large that its name was adopted for the town. The next twenty years saw various mechanical discoveries, while his range of looms was extended to cover Brussels, Wilton, tapestry and velvet carpets. Bigelow has been justly described as the originator of every fundamental device in these machines, which were amongst the largest textile machines of their time. The automatic insertion and withdrawal of strong wires with looped ends was the means employed to raise the looped pile of the Brussels carpets, while thinner wires with a knife blade at the end raised and then severed the loops to create the rich Wilton pile. At the Great Exhibition in 1851, it was declared that his looms made better carpets than any from hand looms. He also developed other looms for special materials.

He became a noted American economist, writing two books about tariff problems, advocating that the United States should not abandon its protectionist policies. In 1860 he was narrowly defeated in a Congress election. The following year he was a member of the committee that established the Massachusetts Institute of Technology.

[br]

Further Reading

National Cyclopedia of American Biography III (the standard account of his life). F.H.Sawyer, 1927, Clinton Item (provides a broad background to his life).

C.Singer (ed.), 1958, A History of Technology, Vol. V, Oxford: Clarendon Press (describes Bigelow's inventions).

RLH

Bode, Hendrik Wade

SUBJECT AREA: Electronics and information technology, Weapons and armour

[br]

b. 24 December 1905 Madison, Wisconsin, USA

d. 21 June 1982 Cambridge, Massachusetts, USA

[br]

American engineer who developed an extensive theoretical understanding of the behaviour of electronic circuits.

[br]

Bode received his bachelor's and master's degrees from Ohio State University in 1924 and 1926, respectively, and his PhD from Columbia University, New York, in 1935. In 1926 he joined the Bell Telephone Laboratories, where he made many theoretical contributions to the understanding of the behaviour of electronic circuits and, in particular, in conjunction with Harry Nyquist, of the conditions under which amplifier circuits become unstable.

During the Second World War he worked on the design of gun control systems and afterwards was a member of a team that worked with Douglas Aircraft to develop the Nike anti-aircraft missile. A member of the Bell Laboratories Mathematical Research Group from 1929, he became its Director in 1952, and then Director of Physical Sciences. Finally he became Vice-President of the Laboratories, with responsibility for systems engineering, and a director of Bellcomm, a Bell company involved in the Moon-landing programme. When he retired from Bell in 1967, he became Professor of Systems Engineering at Harvard University.

[br]

Principal Honours and Distinctions

Presidential Certificate of Merit 1946. Institute of Electrical and Electronics Engineers Edison Medal 1969.

Bibliography

1940, "Relation between attenuation and phase in feedback amplifier design", Bell System Technical Journal 19:421.

1945, Network Analysis and Feedback Amplifier Design, New York: Van Nostrand.

1950, with C.E.Shannon, "A simplified derivation of linear least squares smoothing and prediction theory", Proceedings of the Institute of Radio Engineers 38:417.

1961, "Feedback. The history of an idea", Proceedings of the Symposium on Active Networks and Feedback Systems, Brooklyn Polytechnic.

1971, Synergy: Technical Integration and Technical Innovation in the Bell System Bell Laboratories, Bell Telephone Laboratories (provides background on his activities at Bell).

Further Reading

P.C.Mahon, 1975, Mission Communications, Bell Telephone Laboratories. See also Black, Harold Stephen; Shannon, Claude Elwood.

KF

Boulle, André-Charles

SUBJECT AREA: Domestic appliances and interiors

[br]

b. 11 November 1642 Paris, France

d. 29 February 1732 Paris, France

[br]

French cabinet-maker noted for his elaborate designs and high-quality technique in marquetry using brass and tortoiseshell.

[br]

As with the Renaissance artists and architects of fifteenth-and sixteenth-century Italy, Boulle worked as a young man in varied media, as a painter, engraver and metalworker an in mosaic techniques. It was in the 1660s that he turned more specifically to furniture and in the following decade, under the patronage of Louis XIV, that he became a leading ébéniste or cabinet-maker, In 1672 the King's Controller-General, Jean-Baptiste Colbert, recommended Boulle as an outstanding cabinet-maker and he was appointed ébéniste du roi. From then he spent the rest of his life working in the royal palaces, notably the Louvre and Versailles, and also carried out commissions for the French aristocracy and from abroad, particularly Spain and Germany.

Before the advent of Boulle, the quality furniture made for the French court and aristocracy had come from foreign craftsmen, particularly Domenico Cucci of Italy and Pierre Colle of the Low Countries. Boulle made his name as their equal in his development of new forms of furniture such as his bureaux and commodes, the immense variety of his designs and their architectural quality, the beauty of his sculptural, gilded mounts, and the development of his elaborate marquetry. He was a leading exponent of the contemporary styles, which meant the elaborately rich baroque forms in the time of Louis XIV and the more delicate rococo elegance in that of Louis XV. The technique to which Boulle gave his name (sometimes referred to in its German spelling of Bühl) incorporated a rich variety of veneering materials into his designs: in particular, he used tortoiseshell and brass with ebony. Even greater richness was created with the introduction of an engraved design upon the brass surfaces. Further delicate elaboration derived from the use of paired panels of decoration to be used in reverse form in one piece, or two matching pieces, of furniture. In one panel, designated as première partie, the marquetry took the form of brass upon tortoiseshell, while in the other (contre-partie) the tortoiseshell was set into the brass background.

[br]

Further Reading

J.Fleming and H.Honour, 1977, The Penguin Dictionary of Decorative Arts: Allen Lane, pp. 107–9.

1982, The History of Furniture: Orbis (contains many references to Boulle).

DY

Cartwright, Revd Edmund

SUBJECT AREA: Agricultural and food technology, Textiles

[br]

b. 24 April 1743 Marnham, Nottingham, England

d. 30 October 1823 Hastings, Sussex, England

[br]

English inventor of the power loom, a combing machine and machines for making ropes, bread and bricks as well as agricultural improvements.

[br]

Edmund Cartwright, the fourth son of William Cartwright, was educated at Wakefield Grammar School, and went to University College, Oxford, at the age of 14. By special act of convocation in 1764, he was elected Fellow of Magdalen College. He married Alice Whitaker in 1772 and soon after was given the ecclesiastical living of Brampton in Derbyshire. In 1779 he was presented with the living of Goadby, Marwood, Leicestershire, where he wrote poems, reviewed new works, and began agricultural experiments. A visit to Matlock in the summer of 1784 introduced him to the inventions of Richard Arkwright and he asked why weaving could not be mechanized in a similar manner to spinning. This began a remarkable career of inventions.

Cartwright returned home and built a loom which required two strong men to operate it. This was the first attempt in England to develop a power loom. It had a vertical warp, the reed fell with the weight of at least half a hundredweight and, to quote Gartwright's own words, "the springs which threw the shuttle were strong enough to throw a Congreive [sic] rocket" (Strickland 19.71:8—for background to the "rocket" comparison, see Congreve, Sir William). Nevertheless, it had the same three basics of weaving that still remain today in modern power looms: shedding or dividing the warp; picking or projecting the shuttle with the weft; and beating that pick of weft into place with a reed. This loom he proudly patented in 1785, and then he went to look at hand looms and was surprised to see how simply they operated. Further improvements to his own loom, covered by two more patents in 1786 and 1787, produced a machine with the more conventional horizontal layout that showed promise; however, the Manchester merchants whom he visited were not interested. He patented more improvements in 1788 as a result of the experience gained in 1786 through establishing a factory at Doncaster with power looms worked by a bull that were the ancestors of modern ones. Twenty-four looms driven by steam-power were installed in Manchester in 1791, but the mill was burned down and no one repeated the experiment. The Doncaster mill was sold in 1793, Cartwright having lost £30,000, However, in 1809 Parliament voted him £10,000 because his looms were then coming into general use.

In 1789 he began working on a wool-combing machine which he patented in 1790, with further improvements in 1792. This seems to have been the earliest instance of mechanized combing. It used a circular revolving comb from which the long fibres or "top" were. carried off into a can, and a smaller cylinder-comb for teasing out short fibres or "noils", which were taken off by hand. Its output equalled that of twenty hand combers, but it was only relatively successful. It was employed in various Leicestershire and Yorkshire mills, but infringements were frequent and costly to resist. The patent was prolonged for fourteen years after 1801, but even then Cartwright did not make any profit. His 1792 patent also included a machine to make ropes with the outstanding and basic invention of the "cordelier" which he communicated to his friends, including Robert Fulton, but again it brought little financial benefit. As a result of these problems and the lack of remuneration for his inventions, Cartwright moved to London in 1796 and for a time lived in a house built with geometrical bricks of his own design.

Other inventions followed fast, including a tread-wheel for cranes, metallic packing for pistons in steam-engines, and bread-making and brick-making machines, to mention but a few. He had already returned to agricultural improvements and he put forward suggestions in 1793 for a reaping machine. In 1801 he received a prize from the Board of Agriculture for an essay on husbandry, which was followed in 1803 by a silver medal for the invention of a three-furrow plough and in 1805 by a gold medal for his essay on manures. From 1801 to 1807 he ran an experimental farm on the Duke of Bedford's estates at Woburn.

From 1786 until his death he was a prebendary of Lincoln. In about 1810 he bought a small farm at Hollanden near Sevenoaks, Kent, where he continued his inventions, both agricultural and general. Inventing to the last, he died at Hastings and was buried in Battle church.

[br]

Principal Honours and Distinctions

Board of Agriculture Prize 1801 (for an essay on agriculture). Society of Arts, Silver Medal 1803 (for his three-furrow plough); Gold Medal 1805 (for an essay on agricultural improvements).

Bibliography

1785. British patent no. 1,270 (power loom).

1786. British patent no. 1,565 (improved power loom). 1787. British patent no. 1,616 (improved power loom).

1788. British patent no. 1,676 (improved power loom). 1790, British patent no. 1,747 (wool-combing machine).

1790, British patent no. 1,787 (wool-combing machine).

1792, British patent no. 1,876 (improved wool-combing machine and rope-making machine with cordelier).

Further Reading

M.Strickland, 1843, A Memoir of the Life, Writings and Mechanical Inventions of Edmund Cartwright, D.D., F.R.S., London (remains the fullest biography of Cartwright).

Dictionary of National Biography (a good summary of Cartwright's life). For discussions of Cartwright's weaving inventions, see: A.Barlow, 1878, The History and Principles of Weaving by Hand and by Power, London; R.L. Hills, 1970, Power in the Industrial Revolution, Manchester. F.Nasmith, 1925–6, "Fathers of machine cotton manufacture", Transactions of the

Newcomen Society 6.

H.W.Dickinson, 1942–3, "A condensed history of rope-making", Transactions of the Newcomen Society 23.

W.English, 1969, The Textile Industry, London (covers both his power loom and his wool -combing machine).

RLH

Caxton, William

SUBJECT AREA: Paper and printing

[br]

b. c.1422 Kent, England

d. 1491 Westminster, England

[br]

English printer who produced the first book to be printed in English.

[br]

According to his own account, Caxton was born in Kent and received a schooling before entering the Mercers' Company, one of the most influential of the London guilds and engaged in the wholesale export trade in woollen goods and other wares, principally with the Low Countries. Around 1445, Caxton moved to Bruges, where he engaged in trade with such success that in 1462 he was appointed Governor of the English Nation in Bruges. He was entrusted with diplomatic missions, and his dealings with the court of Burgundy brought him into contact with the Duchess, Margaret of York, sister of the English King Edward IV. Caxton embarked on the production of fine manuscripts, making his own translations from the French for the Duchess and other noble patrons with a taste for this kind of literature. This trend became more marked after 1470–1 when Caxton lost his post in Bruges, probably due to the temporary overthrow of King Edward. Perhaps to satisfy an increasing demand for his texts, Caxton travelled to Cologne in 1471 to learn the art of printing. He set up a printing business in Bruges, in partnership with the copyist and bookseller Colard Mansion. There, late in 1474 or early the following year, Caxton produced the first book to be printed in English, and the first by an English printer, The Recuyell of the Histories of Troy, which he had translated from the French.

In 1476 Caxton returned to England and set up his printing and publishing business "at the sign of the Red Pale" within the precincts of Westminster Abbey. This was more conveniently placed than the City of London for the likely customers among the court and Members of Parliament for the courtly romances and devotional works he aimed to produce. Other printers followed but survived only a few years, whereas Caxton remained successful for fifteen years and then bequeathed a flourishing concern to his assistant Wynkyn de Worde. During that time, 107 printed works, including seventy-four books, issued from Caxton's press. Of these, some twenty were his own translations. As printer and publisher, he did much to promote English literature, above all by producing the first editions of the literary masterpieces of the Middle Ages, such as the works of Chaucer, Gower and Lydgate and Malory's Morte d'Arthur. Among the various dialects of spoken English in use at the time, Caxton adopted the language of London and the court and so did much to fix a permanent standard for written English.

[br]

Further Reading

W.Blades, 1877, The Biography and Typography of William Caxton, England's First Printer, London; reprinted 1971 (the classic life of Caxton, superseded in detail by modern scholarship but still indispensable).

G.D.Painter, 1976, William Caxton: A Quincentenary Biography of England's First

Printer, London: Chatto \& Windus (the most thorough recent biography, describing every known Caxton document and edition, with corrected and new interpretations based on the latest scholarship).

N.F.Blake, 1969, Caxton and His World, London (a reliable account, set against the background of English late-medieval life).

See also: Gutenberg, Johann Gensfleisch zum

LRD

Cotton, William

SUBJECT AREA: Textiles

[br]

b. 1819 Seagrave, Leicestershire, England

d. after 1878

[br]

English inventor of a power-driven flat-bed knitting machine.

[br]

Cotton was originally employed in Loughborough and became one of the first specialized hosiery-machine builders. After the introduction of the latch needle by Matthew Townsend in 1856, knitting frames developed rapidly. The circular frame was easier to work automatically, but attempts to apply power to the flat frame, which could produce fully fashioned work, culminated in 1863 with William Cotton's machine. In that year he invented a machine that could make a dozen or more stockings or hose simultaneously and knit fashioned garments of all kinds. The difficulty was to reduce automatically the number of stitches in the courses where the hose or garment narrowed to give it shape. Cotton had early opportunities to apply himself to the improvement of hosiery machines while employed in the patent shop of Cartwright \& Warner of Loughborough, where some of the first rotaries were made. He remained with the firm for twenty years, during which time sixty or seventy of these machines were turned out. Cotton then established a factory for the manufacture of warp fabrics, and it was here that he began to work on his ideas. He had no knowledge of the principles of engineering or drawing, so his method of making sketches and then getting his ideas roughed out involved much useless labour. After twelve years, in 1863, a patent was issued for the machine that became the basis of the Cotton's Patent type. This was a flat frame driven by rotary mechanism and remarkable for its adaptability. At first he built his machine upright, like a cottage piano, but after much thought and experimentation he conceived the idea of turning the upper part down flat so that the needles were in a vertical position instead of being horizontal, and the work was carried off horizontally instead of vertically. His first machine produced four identical pieces simultaneously, but this number was soon increased. Cotton was induced by the success of his invention to begin machine building as a separate business and thus established one of the first of a class of engineering firms that sprung up as an adjunct to the new hosiery manufacture. He employed only a dozen men and turned out six machines in the first year, entering into an agreement with Hine \& Mundella for their exclusive use. This was later extended to the firm of I. \& R.Morley. In 1878, Cotton began to build on his own account, and the business steadily increased until it employed some 200 workers and had an output of 100 machines a year.

[br]

Bibliography

1863, British patent no. 1,901 (flat-frame knitting machine).

Further Reading

F.A.Wells, 1935, The British Hosiery and Knitwear Industry: Its History and Organisation, London (based on an article in the Knitters' Circular (Feb. 1898).

A brief account of the background to Cotton's invention can be found in T.K.Derry and T.I. Williams, 1960, A Short History of Technology from the Earliest Times to AD 1900, Oxford; C. Singer (ed.), 1958, A History of Technology, Vol. V, Oxford: Clarendon Press.

F.Moy Thomas, 1900, I. \& R.Morley. A Record of a Hundred Years, London (mentions cotton's first machines).

RLH

Cowper-Coles, Sherard Osborn

SUBJECT AREA: Metallurgy

[br]

b. 8 October 1866 East Harting, Sussex, England

d. 9 September 1936

[br]

English inventor of the sherardizing process for metal protection.

[br]

He was the son of Captain Cowper- Coles, Royal Navy, the inventor of the swivelling turret for naval guns. He inherited his father's inventive talents and investigated a variety of inventions in his workshop at his home at Sunbury-on-Thames, assisted by a number of scientific workers. He had been educated by governesses, but he lacked a sound scientific background. His inventions, rarely systematically pursued, ranged from electrolytic processes for making copper sheets and parabolic reflectors to a process for inlaying and decorating metallic surfaces. Overall, however, he is best known for the invention of "sherardizing", the process for producing a rustproof coating of zinc on small metallic articles. The discovery came by chance, when he was annealing iron and steel packed in zinc dust to exclude air. The metal was found to be coated with a thin layer of zinc with some surface penetration. The first patent for the process was obtained in 1900, and later the American rights were sold, with a company being formed in 1908 to control them. A small plant was set up in Chelsea, London, to develop the process to the point where it could be carried out on a commercial scale in a plant in Willesden. Sherardizing has not been a general protective finish, but is restricted to articles such as nuts and bolts which are then painted or finished. The process was still in use in 1977, operated by the Zinc Alloy Company (London) Ltd.

[br]

Further Reading

C.A.Smith, 1978, "Sherard Cowper-Coles: a review of the inception of sherardizing", Transactions of the Newcomen Society 49:1–4.

LRD

Dolby, Ray M.

SUBJECT AREA: Electronics and information technology, Recording

[br]

b. 1933 Portland, Oregon, USA

[br]

American electronics engineer who developed professional systems for noise reduction.

[br]

He was employed by Ampex Corporation from 1949 to 1957 and received a BSc in electrical engineering from Stanford University in 1957. He studied in England and received a PhD in physics from Cambridge University in 1961. He was a United Nations adviser in India 1963–5 and established the Dolby Laboratories in London in 1965. The Dolby Laboratories continuously developed systems for background-noise reduction, and in 1966 introduced Dolby A for professional tape and film formats. In 1968 Dolby B was developed and quickly found its use in the Philips Compact Cassette, which had become the new consumer medium for music. In 1981 Dolby C was an improvement designed for the consumer market, but it also was used in professional video equipment. In 1986 Dolby SR was introduced for professional sound recording. It is a common feature that the equipment has to be in a good state of calibration in order to obtain the advantages of these compander systems.

[br]

Principal Honours and Distinctions

OBE 1986.

GB-N

Forrester, Jay Wright

SUBJECT AREA: Electronics and information technology

[br]

b. 14 July 1918 Anselmo, Nebraska, USA

[br]

American electrical engineer and management expert who invented the magnetic-core random access memory used in most early digital computers.

[br]

Born on a cattle ranch, Forrester obtained a BSc in electrical engineering at the University of Nebraska in 1939 and his MSc at the Massachusetts Institute of Technology (MIT) in Cambridge, Massachusetts, where he remained to teach and carry out research. Becoming interested in computing, he established the Digital Computer Laboratory at MIT in 1945 and became involved in the construction of Whirlwind I, an early general-purpose computer completed in March 1951 and used for flight-simulation by the US Army Air Force. Finding the linear memories then available for storing data a major limiting factor in the speed at which computers were able to operate, he developed a three-dimensional store based on the binary switching of the state of small magnetic cores that could be addressed and switched by a matrix of wires carrying pulses of current. The machine used parallel synchronous fixed-point computing, with fifteen binary digits and a plus sign, i.e. 16 bits in all, and contained 5,000 vacuum tubes, eleven semiconductors and a 2 MHz clock for the arithmetic logic unit. It occupied a two-storey building and consumed 150kW of electricity. From his experience with the development and use of computers, he came to realize their great potential for the simulation and modelling of real situations and hence for the solution of a variety of management problems, using data communications and the technique now known as interactive graphics. His later career was therefore in this field, first at the MIT Lincoln Laboratory in Lexington, Massachusetts (1951) and subsequently (from 1956) as Professor at the Sloan School of Management at the Massachusetts Institute of Technology.

[br]

Principal Honours and Distinctions

National Academy of Engineering 1967. George Washington University Inventor of the Year 1968. Danish Academy of Science Valdemar Poulsen Gold Medal 1969. Systems, Man and Cybernetics Society Award for Outstanding Accomplishments 1972. Computer Society Pioneer Award 1972. Institution of Electrical Engineers Medal of Honour 1972. National Inventors Hall of Fame 1979. Magnetics Society Information Storage Award 1988. Honorary DEng Nebraska 1954, Newark College of Engineering 1971, Notre Dame University 1974. Honorary DSc Boston 1969, Union College 1973. Honorary DPolSci Mannheim University, Germany. Honorary DHumLett, State University of New York 1988.

Bibliography

1951, "Data storage in three dimensions using magnetic cores", Journal of Applied Physics 20: 44 (his first description of the core store).

Publications on management include: 1961, Industrial Dynamics, Cambridge, Mass.: MIT Press; 1968, Principles of Systems, 1971, Urban Dynamics, 1980, with A.A.Legasto \& J.M.Lyneis, System Dynamics, North Holland. 1975, Collected Papers, Cambridge, Mass.: MIT.

Further Reading

K.C.Redmond \& T.M.Smith, Project Whirlwind, the History of a Pioneer Computer (provides details of the Whirlwind computer).

H.H.Goldstine, 1993, The Computer from Pascal to von Neumann, Princeton University Press (for more general background to the development of computers).

Serrell et al., 1962, "Evolution of computing machines", Proceedings of the Institute of

Radio Engineers 1,047.

M.R.Williams, 1975, History of Computing Technology, London: Prentice-Hall.

See also: Burks, Arthur Walter; Goldstine, Herman H.; Wilkes, Maurice Vincent; Williams, Sir Frederic Calland

KF

Goodyear, Charles

SUBJECT AREA: Chemical technology, Land transport

[br]

b. 29 December 1800 New Haven, Connecticut, USA

d. 1 July 1860 New York, USA

[br]

American inventor of the vulcanization of rubber.

[br]

Goodyear entered his father's country hardware business before setting up his own concern in Philadelphia. While visiting New York, he noticed in the window of the Roxburgh India Rubber Company a rubber life-preserver. Goodyear offered to improve its inflating valve, but the manager, impressed with Goodyear's inventiveness, persuaded him to tackle a more urgent problem, that of seeking a means of preventing rubber from becoming tacky and from melting or decomposing when heated. Goodyear tried treatments with one substance after another, without success. In 1838 he started using Nathaniel M.Hayward's process of spreading sulphur on rubber. He accidentally dropped a mass of rubber and sulphur on to a hot stove and noted that the mixture did not melt: Goodyear had discovered the vulcanization of rubber. More experiments were needed to establish the correct proportions for a uniform mix, and eventually he was granted his celebrated patent no. 3633 of 15 June 1844. Goodyear's researches had been conducted against a background of crippling financial difficulties and he was forced to dispose of licences to vulcanize rubber at less than their real value, in order to pay off his most pressing debts.

Goodyear travelled to Europe in 1851 to extend his patents. To promote his process, he designed a spectacular exhibit for London, consisting of furniture, floor covering, jewellery and other items made of rubber. A similar exhibit in Paris in 1855 won him the Grande Médaille d'honneur and the Croix de la Légion d'honneur from Napoleon III. Patents were granted to him in all countries except England. The improved properties of vulcanized rubber and its stability over a much wider range of temperatures greatly increased its applications; output rose from a meagre 31.5 tonnes a year in 1827 to over 28,000 tonnes by 1900. Even so, Goodyear profited little from his invention, and he bequeathed to his family debts amounting to over $200,000.

[br]

Principal Honours and Distinctions

Grande Médaille d'honneur 1855. Croix de la Légion d'honneur 1855.

Bibliography

15 June 1844, US patent no. 3633 (vulcanization of rubber).

1853, Gum Elastic and Its Varieties (includes some biographical material).

Further Reading

B.K.Pierce, 1866, Trials of an Inventor: Life and Discoveries of Charles Goodyear.

H.Allen, 1989, Charles Goodyear: An Intimate Biographical Sketch, Akron, Ohio: Goodyear Tire \& Rubber Company.

LRD

Hall, Joseph

SUBJECT AREA: Metallurgy

[br]

b. 1789

d. 1862

[br]

English ironmaker who invented the wet puddling process.

[br]

Hall was a practical man with no theoretical background: his active years were spent at Bloomfield Ironworks, Tipton, Staffordshire. Around 1816 he began experimenting in the production of wrought iron. At that time, blast-furnace or cast iron was converted to wrought iron by the dry puddling process invented by Henry Cort in 1784. In this process, the iron was decarburized (i.e. had its carbon removed) by heating it in a current of air in a furnace with a sand bed. Some of the iron combined with the silica in the sand to form a slag, however, so that no less than 2 tons of cast iron were needed to produce 1 ton of wrought. Hall found that if bosh cinder was charged into the furnace, a vigorous reaction occurred in which the cast iron was converted much more quickly than before, to produce better quality wrought iron, a ton of which could be formed by no more than 21 cwt (1,067 kg) of cast iron. Because of the boiling action, the process came to be known as pig boiling. Bosh cinder, essentially iron oxide, was formed in the water troughs or boshes in which workers cooled their tools used in puddling and reacted with the carbon in the cast iron. The advantages of pig boiling over dry puddling were striking enough for the process to be widely used by the late 1820s. By mid-century it was virtually the only process used for producing wrought iron, an essential material for mechanical and civil engineering during the Industrial Revolution. Hall reckoned that if he had patented his invention he would have "made a million". As luck would have it, the process that he did patent in 1838 left his finances unchanged: this was for the roasting of cinder for use as the base of the puddling furnace, providing better protection than the bosh cinder for the iron plates that formed the base.

[br]

Bibliography

1857, The Iron Question Considered in Connection with Theory, Practice and Experience with Special Reference to the Bessemer Process, London.

Further Reading

J.Percy, 1864, Metallurgy. Iron and Steel, London, pp. 670 ff. W.K.V.Gale, Iron and Steel, London: Longmans, pp. 46–50.

LRD