year+of+construction

plan

1. n план, программа действий

counter plan — встречный план

short-term plan — краткосрочный план

five-year plan — пятилетний план, пятилетка

economic plan — программа экономического развития

piece rate wage plan — сдельная система оплаты труда

to adopt a plan — принять план

to carry out a plan — осуществить план

to put forward a plan — выдвинуть план

craft-loading plan — план погрузки судна

decontamination plan — план дезактивации

equalization plan — компенсационный план

logistics plan — логистическая программа

mobilization plan — мобилизационный план

2. n проект

a building erected after the plans of an eminent architect — здание, воздвигнутое по проекту известного архитектора

transportation plan — проект дорожно-транспортной планировки

landscape plan — проект создания антропогенного ландшафта

contract plan — чертеж технического проекта

land use plan — проект землепользования

project plan — план реализации проекта

3. n чертёж; схема; диаграмма

working plan — рабочий чертёж

general plan — общий план

master plan — генеральный план

ground plan — план по нулевой отметке

canard plan — аэродинамическая схема утка

fertilizer plan — схема внесения удобрений

block plan — эскизный чертёж привязки здания

bulkhead plan — схема расположения переборок

electric wiring plan — схема электропроводки

4. n горизонтальная проекция

body plan — корпус

plan drawing — чертеж в горизонтальной проекции

datum plan — базовая горизонтальная проекция

plan area — площадь горизонтального сечения

5. n крупномасштабная карта, план

hold plan — план трюмов

plan view — вид в плане

town plan — план города

view plan — вид в плане

Dodge's plan — план Доджа

6. n замысел, план, намерение

to form a new plan — составить новый план

to have no fixed plans — не иметь определённых планов

what are your plans? — каковы ваши планы ?

the plan was perfected in April — план был закончен в апреле

road construction and maintenance plan — план дорожных работ

his plan back-fired — его план обернулся против него самого

contingency plan — план на случай чрезвычайных обстоятельств

single-sample plan — план однократного выборочного контроля

7. n способ действий

the best plan would be … — самое лучшее будет …

robot plan — план действия робота

to urge a plan of action — выдвинуть план действий

game plan — запланированный ряд действий; стратегия

8. n цель, задача

his plan was to get a degree in medicine — его целью было получить диплом врача

9. n церк. расписание служб на квартал

on the American plan — с полным пансионом

frequency plan — расписание частоты

call plan — расписание телефонных звонков

numbering plan area — телефонная номерная зона

uni-service plan — план, составленный одной службой

our plan was achieved — наш план был успешно выполнен

10. v составлять план, планировать

the school was planned for 500 pupils — школа была запроектирована на пятьсот учащихся

force development plan — план строительства вооруженных сил

attributes plan — план контроля по качественным признакам

variables plan — план контроля по качественным признакам

the plan was fated to failure — план был обречён на провал

the plan died on the vine — из этого плана ничего не вышло

11. v строить планы; намереваться, затевать

to plan everything ahead — планировать заранее

to plan for the future — строить планы на будущее; думать о будущем

to plan a visit — собираться нанести визит

Keynes Plan — План Кейнса

basic plan — опорный план

plot plan — план участка

show plan — план выставки

Morris plan — план Морриса

12. v распланировать; запланировать

he had planned it all out — он всё уже распланировал

plan a meeting — запланировать совещание

plan on — планировать; план

Синонимический ряд:

1. course (noun) approach; attack; course; line; procedure; tack; technique

2. drawing (noun) chart; diagram; draft; drawing; map; outline; representation; sketch

3. end (noun) aim; ambition; animus; end; goal; intendment; intent; intention; meaning; objective; point; purpose; target; view

4. order (noun) method; order; orderliness; pattern; system

5. scheme (noun) blueprint; conception; contrivance; design; formula; game plan; idea; layout; premeditation; project; schema; scheme; strategy

6. chart (verb) chart; organize; outline; prepare

7. design (verb) arrange; blueprint; cast; concoct; contrive; delineate; design; devise; draw up; frame; illustrate; lay out; map; map out; plot; project; set out

8. mean (verb) aim; contemplate; intend; mean; project; propose; purpose

school

1. n школа, учебное заведение

day school — дневная школа

elementary school — начальная школа

junior school — младшие классы, начальная школа

senior school — старшие классы, средняя школа

higher school — высшая школа

secondary school — средняя школа

public school

technical school — техническое училище, техникум

riding school — школа верховой езды, манеж

school building — школьное здание

school grounds — школьный участок

what school were you at? — где вы учились?; какую школу вы окончили?

at school — в школе

in school — в школе

school year — учебный год

day school — дневная школа

art school — школа искусств

2. n курсы

driving school — водительские курсы; школа подготовки водителей

summer school — летние курсы для студентов и всех желающих

home study school — заочная школа; курсы заочного обучения

3. n учение, обучение, образование

free school — бесплатная школа; бесплатное школьное обучение

mixed school — школа совместного обучения, смешанная школа

professional school — школа профессионального обучения

state school — средняя школа с бесплатным обучением

correspondence school — школа заочного обучения

school pence — еженедельный взнос за учение

4. n выучка, опыт

the hard school of daily life — тяжёлый жизненный опыт

5. n занятия, уроки

to be in school — быть на уроке

to miss school — пропускать занятия

to cut school — прогуливать занятия, «сачковать»

school begins at 8 — занятия начинаются в восемь утра

to arrive ten minutes before school — приходить за десять минут до начала занятий

to be absent from school — пропустить занятия

the school lets out at 3 — занятия кончаются в 3

detention after school hours — оставление после уроков

6. n собир. учащиеся школы, школьники

school meets on the first of April — занятия в школе возобновляются 1 апреля

school will have a holiday tomorrow — завтра у школьников праздник

grammar school — средняя школа; старшие классы средней школы

to take a child away from school — забрать ребёнка из школы

to get the children off to school — отправить детей в школу

consolidated school — объединённая школа; межрайонная школа

trade school — производственная школа; ремесленное училище

7. n класс, классная комната, школьная аудитория

big school — школьный зал; актовый зал

lower school — младшие классы

school age — школьный возраст

school board — школьный отдел

school bus — школьный автобус

school tie — школьный галстук

8. n направление, школа

Lake school — «Озёрная школа», поэты «Озёрной школы»

a school of thought — философское направление, философская школа

there are two schools of thought about that — мнения по этому поводу разделились

Netherlands school — нидерландская школа

admission to the school — запись в школу

all-service school — общевойсковая школа

branch service school — школа рода войск

charity school — благотворительная школа

9. n институт, колледж

the London School of Economics — Лондонская школа экономики

prestige school — престижный колледж

10. n академия

11. n факультет университета, отделение

law school — юридический факультет

medical school faculty — медицинский факультет

12. n здание Оксфордского университета

school edition — школьное издание

to extend a school building — расширить школьное здание

13. n средневековые университеты; преподавание или образование в таком университете

he is happy at school — у него всё хорошо в школе

air Command and Staff School — командно-штабная школа ВВС

nationally known school — школа, которую знает вся страна

14. n средневековая схоластическая философия

15. n экзамены

the Schools — второй публичный экзамен

writing school — аудитория для письменных экзаменов

16. n ист. когорта или рота императорской гвардии

school crossing — пешеходный переход через дорогу или улицу вблизи школы

17. v обуздывать, дисциплинировать, сдерживать

18. v приучать; тренировать; воспитывать

to school oneself to patience — воспитывать в себе терпение

19. v дрессировать

to school a horse — выезжать лошадь

20. v уст. посылать в школу; давать образование

high school — средняя школа

flight school — летная школа

flying school — летная школа

arm school — школа рода войск

go to school — ходить в школу

21. v уст. учиться в школе; получать образование

school leaver — ученик, бросивший школу

school construction — строительство школ

area school — объединённая районная школа

nursing school — школа медицинских сестер

reformatory school — исправительная школа

22. n косяк, стая

a school of herring — косяк сельди

23. n уст. толпа, сборище

24. n уст. большое количество, масса

the school has a total enrolment of 300 — общее количество учеников в школе составляет 300 человек

25. v собираться косяком, плыть, идти косяком

to school up — собираться на поверхности воды

we were going to build a new school but it got the axe from the government — мы собирались построить новую школу, но правительство не дало на неё денег

Синонимический ряд:

1. academy (noun) academy; college; institute; lyceum; university

2. denomination (noun) denomination; faction; order; party; persuasion

3. educational institution (noun) boarding school; educational institution; elementary school; high school; junior high school; middle school; primary school; seminary

4. style (noun) adherents; character; fashion; manner; method; style; system; tendency

5. coach (verb) coach; discipline; educate; inform; instruct; teach; train

Ethnic minorities

   Traditionally and for a half millennium, Portugal has been a country of emigration, but in recent decades it has become a country of net immigration. During Portugal's long period of overseas empire, beginning in the 15th century, there was always more emigration overseas than immigration to Portugal. There were, nevertheless, populations of natives of Africa, Asia, and the Americas who came to Portugal during the 1450-1975 era. Historians continue to debate the actual numbers of migrants of African descent to Portugal during this period, but records suggest that the resident African population in Portugal during the 16th, 17th, and 18th centuries was a minority of some consequence but not as large as previously imagined.

   After the wars of independence in Africa began in 1961, and after India conquered and annexed former Portuguese Goa, Damão, and Diu in December of that year, Portugal began to receive more migrants from Asia and Africa than before. First came political refugees carrying Portuguese passports from former Portuguese India; these left India for Portugal in the early 1960s. But the larger numbers came from Portugal's former colonial territories in Africa, especially from Angola, Mozambique, and Guinea-Bissau; these sought refuge from civil wars and conflicts following the end of the colonial wars and independence from Portugal. While a considerable number of the refugee wave of 1975-76 from these territories were of African as well as Afro-European descent, larger numbers of African migrants began to arrive in the 1980s. A major impetus for their migration to Portugal was to escape civil wars in Angola and Mozambique.

   Another wave of migrants of European descent came beginning in the 1990s, primarily from Ukraine, Russia, Rumania, and Moldova. Following the fall of the Berlin Wall in November 1989, and the implosion of the Soviet Union, migrants from these countries arrived in Portugal in some number. At about the same time, there arrived migrants from Brazil and another former colony of Portugal, the isolated, poverty-stricken Cape Verde Islands. The largest number of foreign immigrants in Portugal continue to be the Brazilians and the Cape Verdeans, whose principal language is also Portuguese.

   Different ethnic migrant groups tended to work in certain occupations; for example, Brazilians were largely professional people, including dentists and technicians. Cape Verdeans, by and large, as well as numbers of other African migrants from former Portuguese African territories, worked in the construction industry or in restaurants and hotels. As of 2004, the non- European Union (EU) migrant population was over 374,000, while the EU migrant numbers were about 74,000.

   Of the foreign migrants from EU countries, the largest community was the British, with as many as 20,000 residents, with smaller numbers from France, Germany, Italy, and Spain. About 9,000 Americans reside in Portugal. Unlike many migrants from the non-EU countries noted above, who sought safety and a way to make a decent living, migrants from Europe and the United States include many who seek a comfortable retirement in Portugal, with its warm, sunny climate, fine cuisine, and security.

    Legal Foreign Residents from non- European Union Countries ( 1999- 2004)

    1999 2004

   Brazil 20,851 Brazil 66,907

   Cape Verde Isl. Cape Verde Isl. 64,164

   Angola 17,721 Angola 35,264

   Guinea Bissau 25,148

   São Tomé 10,483

   Mozambique 5,472

   Ukraine 66,227

   Romania 12,155

   Moldova 13,689

End

subs.

Conclusion: P. and V. τέλος, τό, τελευτή, ἡ, πέρας, τό, καταστροφή, ἡ (Thuc.), V. τέρμα, τό, τέρμων, ὁ.

met., death: P. and V. θάνατος, ὁ, τελεστή, ἡ.

About the end of the year: P. περὶ λήγοντα τὸν ἐνιαυτόν (Dem. 731).

End of anything that has been cut: P. and V. τομή, ἡ.

Extreme point: P. and V. τὸ ἔσχατος or use adj., ἔσχατος, agreeing with substantive; e. g., the end of the line: P. and V. τάξις ἐσχάτη.

Point: Ar. and V. ἀκμή, ἡ; see Point.

Their line had now all but passed the end of the Athenian wall: P. ἤδη ὅσον οὐ παρεληλύθει τὴν τῶν Ἀθηναίων τοῦ τείχους τελευτὴν ἡ ἐκείνων τείχεσις (Thuc. 7, 6).

They at once closed the great harbour with triremes set end to end: P. ἔκλῃον τὸν λιμένα εὐθὺς τὸν μέγαν... τριήρεσι πλαγίαις (Thuc. 7, 59).

Aim, object: P. προαίρεσις, ἡ.

Purpose: P. and V. γνώμη, ἡ, βούλευμα, τό.

For personal ends: P. διʼ ἴδια κέρδη.

Come to an end: P. and V. τέλος ἔχειν, τέλος λαμβάνειν; see end, v.

Where the construction of both walls came to an end: P. ᾗπερ τῶν τειχῶν ἀμφοτέρων αἱ ἐργασίαι ἔληγον (Thuc. 7, 6).

Come to an end at a place: P. τελευτᾶν ἐπί (acc.) (Thuc. 8, 90).

This is the action of an unscrupulous trickster who will come to a bad end: P. πονηροῦ ταῦτʼ ἐστι σοφιστοῦ καὶ οἰμωξομένου (Dem. 937).

In the end, at last: P. and V. τέλος; see at last, under Last.

Put an end to: P. τέλος ἐπιτιθέναι (dat.); see end, v.

Stand on end: P. ὀρθὸς ἵστασθαι (Plat.), V. ὄρθιος ἑστηκέναι.

——————

v. trans.

P. and V. παύειν, περαίνειν, λύειν, Ar. and P. διαλύειν, καταλύειν, καταπαύειν.

Conclude: P. τελεοῦν, V. τελειοῦν, τελεῖν (rare P.), τελευτᾶν, ἐκτελευτᾶν; see Conclude.

End one's life: P. and V. τελευτᾶν ( with βίον or absol.).

End ( a speech): P. and V. τελευτᾶν (acc. or gen.).

Night ended the action: P. νύξ ἐπεγένετο τῷ ἔργῳ (Thuc. 4, 25).

Night having ended the action: P. ἀφελομένης νυκτὸς τὸ ἔργον (Thuc. 4, 134).

V. intrans. P. and V. τέλος ἔχειν, τέλος λαμβάνειν, τελευτᾶν, V. ἐκτελευτᾶν.

Lapse, expire: P. and V. ἐξέρχεσθαι, ἐξήκειν.

Cease: P. and V. παύεσθαι, λήγειν (Plat.); see Cease.

End in: P. and V. τελευτᾶν εἰς (acc.).

End off in: P. ἀποτελευτᾶν εἰς (acc.).

Aspdin, Joseph

SUBJECT AREA: Architecture and building

[br]

b. 1778 Leeds, England

d. 20 March 1855 Wakefield (?), England

[br]

English pioneer in the development of the cement industry.

[br]

Joseph Aspdin was the eldest of the six children of Thomas Aspdin, a bricklayer. He became interested in making advanced cements for rendering brickwork and, on 21 October 1824, patented a calcined mixture of limestone, clay and water that he called Portland Cement because he thought it resembled Portland Stone in colour.

Aspdin established his first cement works at Kirkgate in Wakefield in 1825: this was demolished in 1838 due to railway development, and a new works was established in the town in 1843. A year later Joseph Aspdin retired and handed the business over to his elder son James. Meanwhile, William, a younger son of Joseph, had also entered the business of manufacturing cement. Born in Leeds on 23 September 1815, he joined his father's firm at the age of 14, but left in 1841 to set up his own firm at Rotherhithe, London. There he manufactured an improved cement that was better and stronger than Parker's Roman Cement, probably because it contained a higher proportion of clinkered material. Further improvements were made during the following years and new factories were established, first at Northfleet in Kent and later at Gateshead on the south bank of the River Tyne (1853). It is interesting that Sir Marc Brunel later preferred to use William Aspdin's cement in the Thames railway tunnel construction because of its greater strength (see Frost). William Aspdin died at Itzehoe in Germany in 1864.

[br]

Further Reading

A.J.Francis, 1977, The Cement Industry 1796–1914: A History, David \& Charles.

DY

Breguet, Louis

SUBJECT AREA: Aerospace

[br]

b. 2 January 1880 Paris, France

d. 4 May 1955 Paris, France

[br]

French aviation pioneer who built a helicopter in 1907 and designed many successful aircraft.

[br]

The Breguet family had been manufacturing fine clocks since before the French Revolution, but Louis Breguet and his brother Jacques used their mechanical skills to produce a helicopter, or "gyroplane" as they named it. It was a complex machine with four biplane rotors (i.e. thirty-two lifting surfaces). Louis Breguet had carried out many tests to determine the most suitable rotor design. The Breguet brothers were assisted by Professor Charles Richet and the Breguet-Richet No. 1 was tested in September 1907 when it succeeded in lifting itself, and its pilot, to a height of 1.5 metres. Unfortunately, the gyroplane was rather unstable and four helpers had to steady it; consequently, the flight did not qualify as a "free" flight. This was achieved two months later, also in France, by Paul Cornu who made a 20-second free flight.

Louis Breguet turned his attention to aeroplane design and produced a tractor biplane when most other biplanes followed the Wright brothers' layout with a forward elevator and pusher propeller. The Breguet I made quite an impression at the 1909 Reims meeting, but the Breguet IV created a world record the following year by carrying six people. During the First World War the Breguet Type 14 bomber was widely used by French and American squadrons. Between the First and Second World Wars a wide variety of designs were produced, including flying boats and another helicopter, the Breguet- Dorand Gyroplane which flew for over one hour in 1936. The Breguet company survived World War II and in the late 1940s developed a successful four-engined airliner/transport, the Deux-Ponts, which had a bulbous double-deck fuselage.

Breguet was an innovative designer, although his designs were functional rather than elegant. He was an early advocate of metal construction and developed an oleo- (oil-spring) undercarriage leg.

[br]

Bibliography

1925, Le Vol à voile dynamique des oiseaux. Analyse des effets des pulsations du vent sur la résultante aérodynamique moyenne d'un planeur, Paris.

Further Reading

P.Faure, 1938, Louis Breguet, Paris (biography).

C.H.Gibbs-Smith, 1965, The Invention of the Aeroplane 1799–1909, London (provides a careful analysis of Breguet's early aircraft).

JDS

Burrell, William

SUBJECT AREA: Ports and shipping

[br]

b. c.1570 England

d. 1630 near Huntingdon, England

[br]

English shipbuilder and Chief Shipwright to the East India Company.

[br]

Born into comfortable circumstances, Burrell chose ship construction as his career. Ability aided by financial influence helped professional advancement, and by his early thirties he possessed a shipyard at Ratcliffe on the River Thames. Ship design was then unscientific, shrouded in mystique, and it required patience and perseverance to penetrate the conventions of the craft.

From the 1600s Burrell had been investing in the East India Company. In 1607 the Company decided to build ships in their own right, and Burrell was appointed as the first Master Shipwright, a post he held for nearly twenty years. The first ship, Trade's Increase, of 1,000-tons burthen, was the largest ship built in England until the eighteenth century, but following a mishap at launch and the ship's subsequent loss on its maiden voyage, the Company reassessed its policy and built smaller ships. Burrell's foresight can be gauged by his involvement in two private commercial undertakings in Ireland; one to create oak forests for shipbuilding, and the other to set up a small ironworks. In 1618 a Royal Commission was appointed to enquire into the poor condition of the Navy, and with the help of Burrell it was ruled that the main problems were neglect and corruption. With his name being known and his good record of production, the Royal Navy ordered no fewer than ten warships from Burrell in the four-year period from 1619 to 1623. With experience in the military and commercial sectors, Burrell can be regarded as an all-round and expert shipbuilder of the Stuart period. He used intuition at a time when there were no scientific rules and little reliable empiric guidance on ship design.

[br]

Principal Honours and Distinctions

First Warden of the Shipwrights' Company after its new Charter of 1612.

Further Reading

A.P.McGowan, 1978, "William Burrell (c. 1570–1630). A forgotten Stuart shipwright", Ingrid and other Studies (National Maritime Museum Monograph No. 36). W.Abell, 1948, The Shipwright's Trade, Cambridge.

FMW

Clement (Clemmet), Joseph

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

bapt. 13 June 1779 Great Asby, Westmoreland, England

d. 28 February 1844 London, England

[br]

English machine tool builder and inventor.

[br]

Although known as Clement in his professional life, his baptism at Asby and his death were registered under the name of Joseph Clemmet. He worked as a slater until the age of 23, but his interest in mechanics led him to spend much of his spare time in the local blacksmith's shop. By studying books on mechanics borrowed from his cousin, a watchmaker, he taught himself and with the aid of the village blacksmith made his own lathe. By 1805 he was able to give up the slating trade and find employment as a mechanic in a small factory at Kirkby Stephen. From there he moved to Carlisle for two years, and then to Glasgow where, while working as a turner, he took lessons in drawing; he had a natural talent and soon became an expert draughtsman. From about 1809 he was employed by Leys, Mason \& Co. of Aberdeen designing and making power looms. For this work he built a screw-cutting lathe and continued his self-education. At the end of 1813, having saved about £100, he made his way to London, where he soon found employment as a mechanic and draughtsman. Within a few months he was engaged by Joseph Bramah, and after a trial period a formal agreement dated 1 April 1814 was made by which Clement was to be Chief Draughtsman and Superintendent of Bramah's Pimlico works for five years. However, Bramah died in December 1814 and after his sons took over the business it was agreed that Clement should leave before the expiry of the five-year period. He soon found employment as Chief Draughtsman with Henry Maudslay \& Co. By 1817 Clement had saved about £500, which enabled him to establish his own business at Prospect Place, Newington Butts, as a mechanical draughtsman and manufacturer of high-class machinery. For this purpose he built lathes for his own use and invented various improvements in their detailed design. In 1827 he designed and built a facing lathe which incorporated an ingenious system of infinitely variable belt gearing. He had also built his own planing machine by 1820 and another, much larger one in 1825. In 1828 Clement began making fluted taps and dies and standardized the screw threads, thus anticipating on a small scale the national standards later established by Sir Joseph Whitworth. Because of his reputation for first-class workmanship, Clement was in the 1820s engaged by Charles Babbage to carry out the construction of his first Difference Engine.

[br]

Principal Honours and Distinctions

Society of Arts Gold Medal 1818 (for straightline mechanism), 1827 (for facing lathe); Silver Medal 1828 (for lathe-driving device).

Bibliography

Examples of Clement's draughtsmanship can be found in the Transactions of the Society of Arts 33 (1817), 36 (1818), 43 (1925), 46 (1828) and 48 (1829).

Further Reading

S.Smiles, 1863, Industrial Biography, London, reprinted 1967, Newton Abbot (virtually the only source of biographical information on Clement).

L.T.C.Rolt, 1965, Tools for the Job, London (repub. 1986); W.Steeds, 1969, A History of Machine Tools 1700–1910, Oxford (both contain descriptions of his machine tools).

RTS

Cody, Colonel Samuel Franklin

SUBJECT AREA: Aerospace

[br]

b. probably 6 March 1861 Texas, USA

d. 7 August 1913 Farnborough, England

[br]

American (naturalised British) aviation pioneer who made the first sustained aeroplane flight in Britain.

[br]

"Colonel" Cody was one of the most colourful and controversial characters in aviation history. He dressed as a cowboy, frequently rode a horse, and appeared on the music-hall stage as a sharpshooter. Cody lived in England from 1896 and became a British subject in 1909. He wrote a melodrama, The Klondyke Nugget, which was first performed in 1898, with Cody as the villain and his wife as the heroine. It was a great success and Cody made enough money to indulge in his hobby of flying large kites. Several man-lifting kites were being developed in the mid-1890s, primarily for military observation purposes. Captain B.S.F. Baden-Powell built multiple hexagonal kites in England, while Lawrence Hargrave, in Australia, developed a very successful boxkite. Cody's man-lifting kites were so good that the British Government engaged him to supply kites, and act as an instructor with the Royal Engineers at the Balloon Factory, Farnborough. Cody's kites were rather like a box-kite with wings and, indeed, some were virtually tethered gliders. In 1905 a Royal Engineer reached a record height of 2,600 ft (790 m) in one of Cody's kites. While at Farnborough, Cody assisted with the construction of the experimental airship "British Army Dirigible No. 1", later known as Nulli Secundus. Cody was on board for the first flight in 1907. In the same year, Cody fitted an engine to one of his kites and it flew with no one on board; he also built a free-flying glider version. He went on to build a powered aeroplane with an Antoinette engine and on 16 October 1908 made a flight of 1,390 ft (424 m) at Farnborough; this was the first real flight in Britain. During the following years, Cody's large "Flying Cathedral" became a popular sight at aviation meetings, and in 1911 his "Cathedral" was the only British aeroplane to complete the course in the Circuit of Britain Contest. In 1912 Cody won the first British Military Aeroplane competition (a similar aeroplane is preserved by the Science Museum, London). Unfortunately, Cody and a passenger were killed when his latest aeroplane crashed at Farnborough in 1913; because Cody was such a popular figure at Farnborough, the tree to which he sometimes tethered his aeroplane was preserved as a memorial.

Later, there was a great controversy over who the first person to make an aeroplane flight in Britain was, as A.V. Roe, Horatio Phillips and Cody had all made hops before October 1908; most historians, however, now accept that it was Cody. Cody's title of'Colonel' was unofficial, although it was used by King George V on one of several visits to see Cody's work.

[br]

Bibliography

Cody gave a lecture to the (Royal) Aeronautical Society which was published in their

Aeronautical Journal, London, January 1909.

Further Reading

P.B.Walker, 1971, Early Aviation at Farnborough, 2 vols, London (an authoritative source).

A.Gould Lee, 1965, The Flying Cathedral, London (biography). G.A.Broomfield, 1953, Pioneer of the Air, Aldershot (a less-reliable biography).

JDS

Darby, Abraham

SUBJECT AREA: Metallurgy

[br]

b. 1678 near Dudley, Worcestershire, England

d. 5 May 1717 Madely Court, Coalbrookdale, Shropshire, England

[br]

English ironmaster, inventor of the coke smelting of iron ore.

[br]

Darby's father, John, was a farmer who also worked a small forge to produce nails and other ironware needed on the farm. He was brought up in the Society of Friends, or Quakers, and this community remained important throughout his personal and working life. Darby was apprenticed to Jonathan Freeth, a malt-mill maker in Birmingham, and on completion of his apprenticeship in 1699 he took up the trade himself in Bristol. Probably in 1704, he visited Holland to study the casting of brass pots and returned to Bristol with some Dutch workers, setting up a brassworks at Baptist Mills in partnership with others. He tried substituting cast iron for brass in his castings, without success at first, but in 1707 he was granted a patent, "A new way of casting iron pots and other pot-bellied ware in sand without loam or clay". However, his business associates were unwilling to risk further funds in the experiments, so he withdrew his share of the capital and moved to Coalbrookdale in Shropshire. There, iron ore, coal, water-power and transport lay close at hand. He took a lease on an old furnace and began experimenting. The shortage and expense of charcoal, and his knowledge of the use of coke in malting, may well have led him to try using coke to smelt iron ore. The furnace was brought into blast in 1709 and records show that in the same year it was regularly producing iron, using coke instead of charcoal. The process seems to have been operating successfully by 1711 in the production of cast-iron pots and kettles, with some pig-iron destined for Bristol. Darby prospered at Coalbrookdale, employing coke smelting with consistent success, and he sought to extend his activities in the neighbourhood and in other parts of the country. However, ill health prevented him from pursuing these ventures with his previous energy. Coke smelting spread slowly in England and the continent of Europe, but without Darby's technological breakthrough the ever-increasing demand for iron for structures and machines during the Industrial Revolution simply could not have been met; it was thus an essential component of the technological progress that was to come.

Darby's eldest son, Abraham II (1711–63), entered the Coalbrookdale Company partnership in 1734 and largely assumed control of the technical side of managing the furnaces and foundry. He made a number of improvements, notably the installation of a steam engine in 1742 to pump water to an upper level in order to achieve a steady source of water-power to operate the bellows supplying the blast furnaces. When he built the Ketley and Horsehay furnaces in 1755 and 1756, these too were provided with steam engines. Abraham II's son, Abraham III (1750–89), in turn, took over the management of the Coalbrookdale works in 1768 and devoted himself to improving and extending the business. His most notable achievement was the design and construction of the famous Iron Bridge over the river Severn, the world's first iron bridge. The bridge members were cast at Coalbrookdale and the structure was erected during 1779, with a span of 100 ft (30 m) and height above the river of 40 ft (12 m). The bridge still stands, and remains a tribute to the skill and judgement of Darby and his workers.

[br]

Further Reading

A.Raistrick, 1989, Dynasty of Iron Founders, 2nd edn, Ironbridge Gorge Museum Trust (the best source for the lives of the Darbys and the work of the company).

H.R.Schubert, 1957, History of the British Iron and Steel Industry AD 430 to AD 1775, London: Routledge \& Kegan Paul.

LRD

de Havilland, Sir Geoffrey

SUBJECT AREA: Aerospace

[br]

b. 27 July 1882 High Wycombe, Buckinghamshire, England

d. 21 May 1965 Stanmore, Middlesex, England

[br]

English designer of some eighty aircraft from 1909 onwards.

[br]

Geoffrey de Havilland started experimenting with aircraft and engines of his own design in 1908. In the following year, with the help of his friend Frank Hearle, he built and flew his first aircraft; it crashed on its first flight. The second aircraft used the same engine and made its first flight on 10 September 1910, and enabled de Havilland to teach himself to fly. From 1910 to 1914 he was employed at Farnborough, where in 1912 the Royal Aircraft Factory was established. As Chief Designer and Chief Test Pilot he was responsible for the BE 2, which was the first British military aircraft to land in France in 1914.

In May 1914 de Havilland went to work for George Holt Thomas, whose Aircraft Manufacturing Company Ltd (Airco) of Hendon was expanding to design and build aircraft of its own design. However, because de Havilland was a member of the Royal Flying Corps Reserve, he had to report for duty when war broke out in August. His value as a designer was recognized and he was transferred back to Airco, where he designed eight aircraft in four years. Of these, the DH 2, DH 4, DH 5, DH 6 and DH 9 were produced in large numbers, and a modified DH 4A operated the first British cross- Channel air service in 1919.

On 25 September 1920 de Havilland founded his own company, the De Havilland Aircraft Company Ltd, at Stag Lane near Edgware, London. During the 1920s and 1930s de Havilland concentrated on civil aircraft and produced the very successful Moth series of small biplanes and monoplanes, as well as the Dragon, Dragon Rapide, Albatross and Flamingo airliners. In 1930 a new site was acquired at Hatfield, Hertfordshire, and by 1934 a modern factory with a large airfield had been established. His Comet racer won the England-Australia air race in 1934 using de Havilland engines. By this time the company had established very successful engine and propeller divisions. The Comet used a wooden stressed-skin construction which de Havilland developed and used for one of the outstanding aircraft of the Second World War: the Mosquito. The de Havilland Engine Company started work on jet engines in 1941 and their Goblin engine powered the Vampire jet fighter first flown by Geoffrey de Havilland Jr in 1943. Unfortunately, Geoffrey Jr and his brother John were both killed in flying accidents. The Comet jet airliner first flew in 1949 and the Trident in 1962, although by 1959 the De Havilland Company had been absorbed into Hawker Siddeley Aviation.

[br]

Principal Honours and Distinctions

Knight Bachelor 1944. Order of Merit 1962. CBE 1934. Air Force Cross 1919. (A full list is contained in R.M.Clarkson's paper (see below)).

Bibliography

1961, Sky Fever, London; repub. 1979, Shrewsbury (autobiography).

Further Reading

R.M.Clarkson, 1967, "Geoffrey de Havilland 1882–1965", Journal of the Royal Aeronautical Society (February) (a concise account of de Havilland, his achievements and honours).

C.M.Sharp, 1960, D.H.—An Outline of de Havilland History, London (mostly a history of the company).

A.J.Jackson, 1962, De Havilland Aircraft since 1915, London.

JDS

Denny, William

SUBJECT AREA: Ports and shipping

[br]

b. 25 May 1847 Dumbarton, Scotland

d. 17 March 1887 Buenos Aires, Argentina

[br]

Scottish naval architect and partner in the leading British scientific shipbuilding company.

[br]

From 1844 until 1962, the Clyde shipyard of William Denny and Brothers, Dumbarton, produced over 1,500 ships, trained innumerable students of all nationalities in shipbuilding and marine engineering, and for the seventy-plus years of their existence were accepted worldwide as the leaders in the application of science to ship design and construction. Until the closure of the yard members of the Denny family were among the partners and later directors of the firm: they included men as distinguished as Dr Peter Denny (1821(?)–95), Sir Archibald Denny (1860–1936) and Sir Maurice Denny (1886– 1955), the main collaborator in the design of the Denny-Brown ship stabilizer.

One of the most influential of this shipbuilding family was William Denny, now referred to as William 3! His early education was at Dumbarton, then on Jersey and finally at the Royal High School, Edinburgh, before he commenced an apprenticeship at his father's shipyard. From the outset he not only showed great aptitude for learning and hard work but also displayed an ability to create good relationships with all he came into contact with. At the early age of 21 he was admitted a partner of the shipbuilding business of William Denny and Brothers, and some years later also of the associated engineering firm of Denny \& Co. His deep-felt interest in what is now known as industrial relations led him in 1871 to set up a piecework system of payment in the shipyard. In this he was helped by the Yard Manager, Richard Ramage, who later was to found the Leith shipyard, which produced the world's most elegant steam yachts. This research was published later as a pamphlet called The Worth of Wages, an unusual and forward-looking action for the 1860s, when Denny maintained that an absentee employer should earn as much contempt and disapproval as an absentee landlord! In 1880 he initiated an awards scheme for all company employees, with grants and awards for inventions and production improvements. William Denny was not slow to impose new methods and to research naval architecture, a special interest being progressive ship trials with a view to predicting effective horsepower. In time this led to his proposal to the partners to build a ship model testing tank beside the Dumbarton shipyard; this scheme was completed in 1883 and was to the third in the world (after the Admiralty tank at Torquay, managed by William Froude and the Royal Netherlands Navy facility at Amsterdam, under B.J. Tideman. In 1876 the Denny Shipyard started work with mild-quality shipbuilding steel on hulls for the Irrawaddy Flotilla Company, and in 1879 the world's first two ships of any size using this weight-saving material were produced: they were the Rotomahana for the Union Steamship Company of New Zealand and the Buenos Ayrean for the Allan Line of Glasgow. On the naval-architecture side he was involved in Denny's proposals for standard cross curves of stability for all ships, which had far-reaching effects and are now accepted worldwide. He served on the committee working on improvements to the Load Line regulations and many other similar public bodies. After a severe bout of typhoid and an almost unacceptable burden of work, he left the United Kingdom for South America in June 1886 to attend to business with La Platense Flotilla Company, an associate company of William Denny and Brothers. In March the following year, while in Buenos Aires, he died by his own hand, a death that caused great and genuine sadness in the West of Scotland and elsewhere.

[br]

Principal Honours and Distinctions

President, Institution of Engineers and Shipbuilders in Scotland 1886. FRS Edinburgh 1879.

Bibliography

William Denny presented many papers to various bodies, the most important being to the Institution of Naval Architects and to the Institution of Engineers and Shipbuilders in Scotland. The subjects include: trials results, the relation of ship speed to power, Lloyd's Numerals, tonnage measurement, layout of shipyards, steel in shipbuilding, cross curves of stability, etc.

Further Reading

A.B.Bruce, 1889, The Life of William Denny, Shipbuilder, London: Hodder \& Stoughton.

Denny Dumbarton 1844–1932 (a souvenir hard-back produced for private circulation by the shipyard).

Fred M.Walker, 1984, Song of the Clyde. A History of Clyde Shipbuilding, Cambridge: PSL.

FMW

Doane, Thomas

SUBJECT AREA: Civil engineering, Mechanical, pneumatic and hydraulic engineering, Railways and locomotives

[br]

b. 20 September 1821 Orleans, Massachusetts, USA

d. 22 October 1897 West Townsend, Massachusetts, USA

[br]

American mechanical engineer.

[br]

The son of a lawyer, he entered an academy in Cape Cod and, at the age of 19, the English Academy at Andover, Massachusetts, for five terms. He was then in the employ of Samuel L. Fenton of Charlestown, Massachusetts. He served a three-year apprenticeship, then went to the Windsor White River Division of the Vermont Central Railroad. He was Resident Engineer of the Cheshire Railroad at Walpote, New Hampshire, from 1847 to 1849, and then worked in independent practice as a civil engineer and surveyor until his death. He was involved with nearly all the railroads running out of Boston, especially the Boston \& Maine. In April 1863 he was appointed Chief Engineer of the Hoosac Tunnel, which was already being built. He introduced new engineering methods, relocated the line of the tunnel and achieved great accuracy in the meeting of the borings. He was largely responsible for the development in the USA of the advanced system of tunnelling with machinery and explosives, and pioneered the use of compressed air in the USA. In 1869 he was Chief Engineer of the Burlington \& Missouri River Railroad in Nebraska, laying down some 240 miles (386 km) of track in four years. During this period he became interested in the building of a Congregational College at Crete, Nebraska, for which he gave the land and which was named after him. In 1873 he returned to Charlestown and was again appointed Chief Engineer of the Hoosac Tunnel. At the final opening of the tunnel on 9 February 1875 he drove the first engine through. He remained in charge of construction for a further two years.

[br]

Principal Honours and Distinctions

President, School of Civil Engineers.

Further Reading

Duncan Malone (ed.), 1932–3, Dictionary of American Biography, New York: Charles Scribner.

IMcN

Dyer, Joseph Chessborough

SUBJECT AREA: Textiles

[br]

b. 15 November 1780 Stonnington Point, Connecticut, USA

d. 2 May 1871 Manchester, England

[br]

American inventor of a popular type of roving frame for cotton manufacture.

[br]

As a youth, Dyer constructed an unsinkable life-boat but did not immediately pursue his mechanical bent, for at 16 he entered the counting-house of a French refugee named Nancrède and succeeded to part of the business. He first went to England in 1801 and finally settled in 1811 when he married Ellen Jones (d. 1842) of Gower Street, London. Dyer was already linked with American inventors and brought to England Perkins's plan for steel engraving in 1809, shearing and nail-making machines in 1811, and also received plans and specifications for Fulton's steamboats. He seems to have acted as a sort of British patent agent for American inventors, and in 1811 took out a patent for carding engines and a card clothing machine. In 1813 there was a patent for spinning long-fibred substances such as hemp, flax or grasses, and in 1825 there was a further patent for card making machinery. Joshua Field, on his tour through Britain in 1821, saw a wire drawing machine and a leather splitting machine at Dyer's works as well as the card-making machines. At first Dyer lived in Camden Town, London, but he had a card clothing business in Birmingham. He moved to Manchester c.1816, where he developed an extensive engineering works under the name "Joseph C.Dyer, patent card manufacturers, 8 Stanley Street, Dale Street". In 1832 he founded another works at Gamaches, Somme, France, but this enterprise was closed in 1848 with heavy losses through the mismanagement of an agent. In 1825 Dyer improved on Danforth's roving frame and started to manufacture it. While it was still a comparatively crude machine when com-pared with later versions, it had the merit of turning out a large quantity of work and was very popular, realizing a large sum of money. He patented the machine that year and must have continued his interest in these machines as further patents followed in 1830 and 1835. In 1821 Dyer had been involved in the foundation of the Manchester Guardian (now The Guardian) and he was linked with the construction of the Liverpool \& Manchester Railway. He was not so successful with the ill-fated Bank of Manchester, of which he was a director and in which he lost £98,000. Dyer played an active role in the community and presented many papers to the Manchester Literary and Philosophical Society. He helped to establish the Royal Institution in London and the Mechanics Institution in Manchester. In 1830 he was a member of the delegation to Paris to take contributions from the town of Manchester for the relief of those wounded in the July revolution and to congratulate Louis-Philippe on his accession. He called for the reform of Parliament and helped to form the Anti-Corn Law League. He hated slavery and wrote several articles on the subject, both prior to and during the American Civil War.

[br]

Bibliography

1811, British patent no. 3,498 (carding engines and card clothing machine). 1813, British patent no. 3,743 (spinning long-fibred substances).

1825, British patent no. 5,309 (card making machinery).

1825, British patent no. 5,217 (roving frame). 1830, British patent no. 5,909 (roving frame).

1835, British patent no. 6,863 (roving frame).

Further Reading

Dictionary of National Biography.

J.W.Hall, 1932–3, "Joshua Field's diary of a tour in 1821 through the Midlands", Transactions of the Newcomen Society 6.

Evan Leigh, 1875, The Science of Modern Cotton Spinning, Vol. II, Manchester (provides an account of Dyer's roving frame).

D.J.Jeremy, 1981, Transatlantic Industrial Revolution: The Diffusion of Textile

Technologies Between Britain and America, 1790–1830s, Oxford (describes Dyer's links with America).

See also: Arnold, Aza

RLH

Fermi, Enrico

SUBJECT AREA: Metallurgy, Weapons and armour

[br]

b. 29 September 1901 Rome, Italy

d. 28 November 1954 Chicago, USA

[br]

Italian nuclear physicist.

[br]

Fermi was one of the most versatile of twentieth-century physicists, one of the few to excel in both theory and experiment. His greatest theoretical achievements lay in the field of statistics and his theory of beta decay. His statistics, parallel to but independent of Dirac, were the key to the modern theory of metals and the statistical modds of the atomic nucleus. On the experimental side, his most notable discoveries were artificial radioactivity produced by neutron bombardment and the realization of a controlled nuclear chain reaction, in the world's first nuclear reactor.

Fermi received a conventional education with a chemical bias, but reached proficiency in mathematics and physics largely through his own reading. He studied at Pisa University, where he taught himself modern physics and then travelled to extend his knowledge, spending time with Max Born at Göttingen. On his return to Italy, he secured posts in Florence and, in 1927, in Rome, where he obtained the first Italian Chair in Theoretical Physics, a subject in which Italy had so far lagged behind. He helped to bring about a rebirth of physics in Italy and devoted himself to the application of statistics to his model of the atom. For this work, Fermi was awarded the Nobel Prize in Physics in 1938, but in December of that year, finding the Fascist regime uncongenial, he transferred to the USA and Columbia University. The news that nuclear fission had been achieved broke shortly before the Second World War erupted and it stimulated Fermi to consider this a way of generating secondary nuclear emission and the initiation of chain reactions. His experiments in this direction led first to the discovery of slow neutrons.

Fermi's work assumed a more practical aspect when he was invited to join the Manhattan Project for the construction of the first atomic bomb. His small-scale work at Columbia became large-scale at Chicago University. This culminated on 2 December 1942 when the first controlled nuclear reaction took place at Stagg Field, Chicago, an historic event indeed. Later, Fermi spent most of the period from September 1944 to early 1945 at Los Alamos, New Mexico, taking part in the preparations for the first test explosion of the atomic bomb on 16 July 1945. President Truman invited Fermi to serve on his Committee to advise him on the use of the bomb. Then Chicago University established an Institute for Nuclear Studies and offered Fermi a professorship, which he took up early in 1946, spending the rest of his relatively short life there.

[br]

Principal Honours and Distinctions

Nobel Prize for Physics 1938.

Bibliography

1962–5, Collected Papers, ed. E.Segrè et al., 2 vols, Chicago (includes a biographical introduction and bibliography).

Further Reading

L.Fermi, 1954, Atoms in the Family, Chicago (a personal account by his wife).

E.Segrè, 1970, Enrico Fermi, Physicist, Chicago (deals with the more scientific aspects of his life).

LRD

Ferranti, Sebastian Ziani de

SUBJECT AREA: Electricity, Public utilities

[br]

b. 9 April 1864 Liverpool, England

d. 13 January 1930 Zurich, Switzerland

[br]

English manufacturing engineer and inventor, a pioneer and early advocate of high-voltage alternating-current electric-power systems.

[br]

Ferranti, who had taken an interest in electrical and mechanical devices from an early age, was educated at St Augustine's College in Ramsgate and for a short time attended evening classes at University College, London. Rather than pursue an academic career, Ferranti, who had intense practical interests, found employment in 1881 with the Siemens Company (see Werner von Siemens) in their experimental department. There he had the opportunity to superintend the installation of electric-lighting plants in various parts of the country. Becoming acquainted with Alfred Thomson, an engineer, Ferranti entered into a short-lived partnership with him to manufacture the Ferranti alternator. This generator, with a unique zig-zag armature, had an efficiency exceeding that of all its rivals. Finding that Sir William Thomson had invented a similar machine, Ferranti formed a company with him to combine the inventions and produce the Ferranti- Thomson machine. For this the Hammond Electric Light and Power Company obtained the sole selling rights.

In 1885 the Grosvenor Gallery Electricity Supply Corporation was having serious problems with its Gaulard and Gibbs series distribution system. Ferranti, when consulted, reviewed the design and recommended transformers connected across constant-potential mains. In the following year, at the age of 22, he was appointed Engineer to the company and introduced the pattern of electricity supply that was eventually adopted universally. Ambitious plans by Ferranti for London envisaged the location of a generating station of unprecedented size at Deptford, about eight miles (13 km) from the city, a departure from the previous practice of placing stations within the area to be supplied. For this venture the London Electricity Supply Corporation was formed. Ferranti's bold decision to bring the supply from Deptford at the hitherto unheard-of pressure of 10,000 volts required him to design suitable cables, transformers and generators. Ferranti planned generators with 10,000 hp (7,460 kW)engines, but these were abandoned at an advanced stage of construction. Financial difficulties were caused in part when a Board of Trade enquiry in 1889 reduced the area that the company was able to supply. In spite of this adverse situation the enterprise continued on a reduced scale. Leaving the London Electricity Supply Corporation in 1892, Ferranti again started his own business, manufacturing electrical plant. He conceived the use of wax-impregnated paper-insulated cables for high voltages, which formed a landmark in the history of cable development. This method of flexible-cable manufacture was used almost exclusively until synthetic materials became available. In 1892 Ferranti obtained a patent which set out the advantages to be gained by adopting sector-shaped conductors in multi-core cables. This was to be fundamental to the future design and development of such cables.

A total of 176 patents were taken out by S.Z. de Ferranti. His varied and numerous inventions included a successful mercury-motor energy meter and improvements to textile-yarn produc-tion. A transmission-line phenomenon where the open-circuit voltage at the receiving end of a long line is greater than the sending voltage was named the Ferranti Effect after him.

[br]

Principal Honours and Distinctions

FRS 1927. President, Institution of Electrical Engineers 1910 and 1911. Institution of Electrical Engineers Faraday Medal 1924.

Bibliography

18 July 1882, British patent no. 3,419 (Ferranti's first alternator).

13 December 1892, British patent no. 22,923 (shaped conductors of multi-core cables). 1929, "Electricity in the service of man", Journal of the Institution of Electrical Engineers 67: 125–30.

Further Reading

G.Z.de Ferranti and R. Ince, 1934, The Life and Letters of Sebastian Ziani de Ferranti, London.

A.Ridding, 1964, S.Z.de Ferranti. Pioneer of Electric Power, London: Science Museum and HMSO (a concise biography).

R.H.Parsons, 1939, Early Days of the Power Station Industry, Cambridge, pp. 21–41.

GW

Fife, William

SUBJECT AREA: Ports and shipping

[br]

b. 15 June 1857 Fairlie, Scotland

d. 11 August 1944 Fairlie, Scotland

[br]

Scottish naval architect and designer of sailing yachts of legendary beauty and performance.

[br]

Following his education at Brisbane Academy in Largs, William Fife (the third generation of the name) became apprenticed at the age of 14 to the already famous yacht-building yard owned by his family at Fairlie in Ayrshire. On completion of his apprenticeship, he joined the Paisley shipbuilders John Fullerton \& Co. to gain experience in iron shipbuilding before going on as Manager to the Marquis of Ailsa's Culzean Steam Launch and Yacht Works. Initially the works was sited below the famous castle at Culzean, but some years later it moved a few miles along the Ayrshire Coast to Maidens. The Culzean Company was wound up in 1887 and Fife then returned to the family yard, where he remained for the rest of his working life. Many outstanding yachts were the product of his hours on the drawing board, including auxiliary sailing cruisers, motor yachts and well-known racing craft. The most outstanding designs were for two of Sir Thomas Lipton's challengers for the America's Cup: Shamrock I and Shamrock III. The latter yacht was tested at the Ship Model Experiment Tank owned by Denny of Dumbarton before being built at their Leven Shipyard in 1903. Shamrock III may have been one of the earliest America's Cup yachts to have been designed with a high level of scientific input. The hull construction was unusual for the early years of the twentieth century, being of alloy steel with decks of aluminium.

William Fife was decorated for his service to shipbuilding during the First World War. With the onset of the Great Depression the shipyard's output slowed, and in the 1930s it was sold to other interests; this was the end of the 120-year Fife dynasty.

[br]

Principal Honours and Distinctions

OBE c.1919.

FMW

Fokker, Anthony Herman Gerard

SUBJECT AREA: Aerospace

[br]

b. 6 April 1890 Kediri, Java, Dutch East Indies (now Indonesia)

d. 23 December 1939 New York, USA

[br]

Dutch designer of German fighter aircraft during the First World War and of many successful airliners during the 1920s and 1930s.

[br]

Anthony Fokker was born in Java, where his Dutch father had a coffee plantation. The family returned to the Netherlands and, after schooling, young Anthony went to Germany to study aeronautics. With the aid of a friend he built his first aeroplane, the Spin, in 1910: this was a monoplane capable of short hops. By 1911 Fokker had improved the Spin and gained a pilot's licence. In 1912 he set up a company called Fokker Aeroplanbau at Johannistal, outside Berlin, and a series of monoplanes followed.

When war broke out in 1914 Fokker offered his designs to both sides, and the Germans accepted them. His E I monoplane of 1915 caused a sensation with its manoeuvrability and forward-firing machine gun. Fokker and his collaborators improved on the French deflector system introduced by Raymond Saulnier by fitting an interrupter gear which synchronized the machine gun to fire between the blades of the rotating propeller. The Fokker Dr I triplane and D VII biplane were also outstanding German fighters of the First World War. Fokker's designs were often the work of an employee who received little credit: nevertheless, Fokker was a gifted pilot and a great organizer. After the war, Fokker moved back to the Netherlands and set up the Fokker Aircraft Works in Amsterdam. In 1922, however, he emigrated to the USA and established the Atlantic Aircraft Corporation in New Jersey. His first significant success there came the following year when one of his T-2 monoplanes became the first aircraft to fly non-stop across the USA, from New York to San Diego. He developed a series of civil aircraft using the well-proven method of construction he used for his fighters: fuselages made from steel tubes and thick, robust wooden wings. Of these, probably the most famous was the F VII/3m, a high-wing monoplane with three engines and capable of carrying about ten passengers. From 1925 the F VII/3m airliner was used worldwide and made many record-breaking flights, such as Lieutenant-Commander Richard Byrd's first flight over the North Pole in 1926 and Charles Kingsford-Smith's first transpacific flight in 1928. By this time Fokker had lost interest in military aircraft and had begun to see flight as a means of speeding up global communications and bringing people together. His last years were spent in realizing this dream, and this was reflected in his concentration on the design and production of passenger aircraft.

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Principal Honours and Distinctions

Royal Netherlands Aeronautical Society Gold Medal 1932.

Bibliography

1931, The Flying Dutchman: The Life of Anthony Fokker, London: Routledge \& Sons (an interesting, if rather biased, autobiography).

Further Reading

A.R.Weyl, 1965, Fokker: The Creative Years, London; reprinted 1988 (a very detailed account of Fokker's early work).

Thijs Postma, 1979, Fokker: Aircraft Builders to the World, Holland; 1980, English edn, London (a well-illustrated history of Fokker and the company).

Henri Hegener, 1961, Fokker: The Man and His Aircraft, Letchworth, Herts.

JDS / CM

Forrester, Jay Wright

SUBJECT AREA: Electronics and information technology

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b. 14 July 1918 Anselmo, Nebraska, USA

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

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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.

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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

Giles, Francis

SUBJECT AREA: Canals, Civil engineering, Ports and shipping

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b. 1787 England

d. 4 March 1847 England

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English civil engineer engaged in canal, harbour and railway construction.

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Trained as a surveyor in John Rennie's organization, Giles carried out surveys on behalf of Rennie before setting up in practice on his own. His earliest survey seems to have been on the line of the proposed Weald of Kent Canal in 1809. Then in 1811 he surveyed the proposed London \& Cambridge Canal linking Bishops Stortford on the Stort with Cambridge and with a branch to Shefford on the Ivel. In the same year he surveyed the line of the Wey \& Arun Junction Canal, and in 1816, in the same area, the Portsmouth \& Arundel Canal. In 1819 he carried out what is regarded as his first independent commission—the extension of the River Ivel Navigation from Biggleswade to Shefford. At this time he was helping John Rennie on the Aire \& Calder Navigation and continued there after Rennie's death in 1821. In 1825 he was engaged on plans for a London to Portsmouth Ship Canal and also on a suggested link between the Basingstoke and Kennet \& Avon Canals. Later, on behalf of Sir George Duckett, he was Engineer to the Hertford Union Canal, which was completed in 1830, and linked the Regent's Canal to the Lee Navigation. In 1833 he completed the extension of the Sankey Brook Navigation from Fiddler's Ferry to the Mersey at Widnes. One of his last canal works was a survey of the River Lee in 1844. Apart from his canal work, he was appointed Engineer to the Newcastle \& Carlisle Railway in 1829 and designed, among other works, the fine viaducts at Wetheral and Cor by. He was also, for a very short time, Engineer to the London \& Southampton Railway. Among other commissions, he was involved in harbour surveys and works at Dover, Rye, Holyhead, Dundee, Bridport and Dun Laoghaire (Kingstown). He was elected a member of the Institution of Civil Engineers in 1842 and succeeded Telford on the Exchequer Bill Loans Board.

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Further Reading

1848, Memoir 17, London: Institution of Civil Engineers, 9.

JHB