the+revolution+within+the+revolution

Santos, José Manuel Cerqueira Afonso

(1929-1987)

   Balladeer, singer, poet, musician, composer, and teacher. Known to the public simply as "Zeca" or "José Afonso," he was a student poet, singer, and musician in the 1950s, and premier interpreter of Coimbra fado, creator of a new school of fado music, and leader of a reform movement in popular music. Using his distinctive musical compositions, appealing baritone singing voice, and iconoclastic lyrics of resistance to tyranny, Afonso Santos employed his poetic and musical gifts as instruments of resistance and opposition to the enduring Estado Novo. Two recorded songs became early shots in this war: Balada de Outono (Autumn's Ballad) and Menino d'Oiro (Golden Boy). With diverse, subversive meanings usually disguised in allegory, his lyrics and style eschewed the traditional Coimbra fado's fare of broad sentiment and unrequited love. Instead, Afonso presented new ballads with contemporary resonance. In the mid-1960s, when so many Portuguese youth were drafted and mobilized for Portugal's colonial wars in Africa, he lived and taught school in Mozambique, where he organized opposition to the regime. Later in that colony, he was arrested by the PIDE.

   After his return to Portugal, Afonso's reputation as a rebel ballad-eer grew; among his most celebrated recorded ballads were Cantigas de Maio (Songs of May, 1971) and Venham Mais Cinco (Five More Came, 1973). His famous revolutionary, rallying song, Grândola, Vila Morena, banned by the Estado Novo before 1974, became the single most famous piece of Portuguese revolutionary music in the second half of the 20th century. Grândola featured Afonso's voice and lyrics and expressed a clearly leftist ideology and resistance to tyranny, to the background sounds of marching feet growing louder. Selected by the coup planners of the Armed Forces Movement as a signal for action, a secret password sign to be played over Lisbon radio at about midnight on 24/25 April 1974, this remarkable song acquired new fame and a place in history as both an actual signal for rebel military operations to begin and an enduring revolutionary rallying cry. After the Revolution of 25 April 1974, Grândola became the most potent symbol of the move to topple the Estado Novo and open the way for profound change, as well as a musical icon, equaled only by the iconographic red carnation. The first stanza of Afonso's lyrics, translated from the Portuguese, is: Grândola, dark-brown town, Homeland of Brotherhood The people have more power within you, oh city....

Cobbett, William

SUBJECT AREA: Agricultural and food technology

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b. 9 March 1762 Farnham, Surrey, England

d. 17 June 1835 Guildford, Surrey, England

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English political writer and activist; writer on rural affairs, with a particular concern for the conditions of the agricultural worker; a keen experimental farmer who claimed responsibility for the import of Indian maize to Britain.

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The son of a smallholder farmer and self-taught surveyor, William Cobbett was brought up to farm work from an early age. In 1783 he took employment as an attorney's clerk in London, but not finding this to his liking he travelled to Chatham with the intention of joining the Navy. A mistake in "taking the King's shilling" found him in an infantry regiment. After a year's training he was sent out to Nova Scotia and quickly gained the rank of sergeant major. On leaving the Army he brought corruption charges against three officers in his regiment, but did not press with the prosecution. England was not to his taste, and he returned to North America with his wife.

In America Cobbett taught English to the growing French community displaced by the French Revolution. He found American criticism of Britain ill-balanced and in 1796 began to publish a daily newspaper under the title Porcupine's Gazetteer, in which he wrote editorials in defence of Britain. His writings won him little support from the Americans. However, on returning to London in 1800 he was offered, but turned down, the management of a Government newspaper. Instead he began to produce a daily paper called the Porcupine, which was superseded in 1802 by Cobbett's Political Register, this publication continued on a weekly basis until after his death. In 1803 he also began the Parliamentary Debates, which later merged into Hansard, the official report of parliamentary proceedings.

In 1805 Cobbett took a house and 300-acre (120-hectare) farm in Hampshire, from which he continued to write, but at the same time followed the pursuits he most enjoyed. In 1809 his criticism of the punishment given to mutineers in the militia at Ely resulted in his own imprisonment. On his release in 1812 he decided that the only way to remain an independent publisher was to move back to the USA. He bought a farm at Hampstead, Long Island, New York, and published A Year's Residence in America, which contains, amongst other things, an interesting account of a farmer's year.

Returning to Britain in the easier political climate of the 1820s, Cobbett bought a small seed farm in Kensington, then outside London. From there he made a number of journeys around the country, publishing accounts of them in his famous Rural Rides. His experiments and advice on the sowing and cultivation of crops, particularly turnips and swedes, and on forestry, were an important mechanism for the spread of ideas within the UK. He also claimed that he was the first to introduce the acacia and Indian maize to Britain. Much of his writing expresses a concern for the rural poor and he was firmly convinced that only parliamentary reform would achieve the changes needed. His political work and writing led to his election as Member of Parlaiment for Oldham in the 1835 election, which followed the Reform Act of 1832. However, by this time his energy was failing rapidly and he died peacefully at Normandy Farm, near Guildford, at the age of 73.

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Bibliography

Cobbett's Observations on Priestley's Emigration, published in 1794, was the first of his pro-British tracts written in America. On the basis of his stay in that country he wrote A Year's Residence in America. His books on agricultural practice included Woodlands (1825) and Treatise on Cobbett's Corn (1828). Dealing with more social problems he wrote an English Grammar for the use of Apprentices, Plough Boys, Soldiers and Sailors in 1818, and Cottage Economy in 1821.

Further Reading

Albert Pell, 1902, article in Journal of the Royal Agricultural Society of England 63:1–26 (describes the life and writings of William Cobbett).

James Sambrook, 1973, William Cobbett, London: Routledge (a more detailed study).

AP

Evans, Oliver

SUBJECT AREA: Agricultural and food technology

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b. 13 September 1755 Newport, Delaware, USA

d. 15 April 1819 New York, USA

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American millwright and inventor of the first automatic corn mill.

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He was the fifth child of Charles and Ann Stalcrop Evans, and by the age of 15 he had four sisters and seven brothers. Nothing is known of his schooling, but at the age of 17 he was apprenticed to a Newport wheelwright and wagon-maker. At 19 he was enrolled in a Delaware Militia Company in the Revolutionary War but did not see active service. About this time he invented a machine for bending and cutting off the wires in textile carding combs. In July 1782, with his younger brother, Joseph, he moved to Tuckahoe on the eastern shore of the Delaware River, where he had the basic idea of the automatic flour mill. In July 1782, with his elder brothers John and Theophilus, he bought part of his father's Newport farm, on Red Clay Creek, and planned to build a mill there. In 1793 he married Sarah Tomlinson, daughter of a Delaware farmer, and joined his brothers at Red Clay Creek. He worked there for some seven years on his automatic mill, from about 1783 to 1790.

His system for the automatic flour mill consisted of bucket elevators to raise the grain, a horizontal screw conveyor, other conveying devices and a "hopper boy" to cool and dry the meal before gathering it into a hopper feeding the bolting cylinder. Together these components formed the automatic process, from incoming wheat to outgoing flour packed in barrels. At that time the idea of such automation had not been applied to any manufacturing process in America. The mill opened, on a non-automatic cycle, in 1785. In January 1786 Evans applied to the Delaware legislature for a twenty-five-year patent, which was granted on 30 January 1787 although there was much opposition from the Quaker millers of Wilmington and elsewhere. He also applied for patents in Pennsylvania, Maryland and New Hampshire. In May 1789 he went to see the mill of the four Ellicot brothers, near Baltimore, where he was impressed by the design of a horizontal screw conveyor by Jonathan Ellicot and exchanged the rights to his own elevator for those of this machine. After six years' work on his automatic mill, it was completed in 1790. In the autumn of that year a miller in Brandywine ordered a set of Evans's machinery, which set the trend toward its general adoption. A model of it was shown in the Market Street shop window of Robert Leslie, a watch-and clockmaker in Philadelphia, who also took it to England but was unsuccessful in selling the idea there.

In 1790 the Federal Plant Laws were passed; Evans's patent was the third to come within the new legislation. A detailed description with a plate was published in a Philadelphia newspaper in January 1791, the first of a proposed series, but the paper closed and the series came to nothing. His brother Joseph went on a series of sales trips, with the result that some machinery of Evans's design was adopted. By 1792 over one hundred mills had been equipped with Evans's machinery, the millers paying a royalty of $40 for each pair of millstones in use. The series of articles that had been cut short formed the basis of Evans's The Young Millwright and Miller's Guide, published first in 1795 after Evans had moved to Philadelphia to set up a store selling milling supplies; it was 440 pages long and ran to fifteen editions between 1795 and 1860.

Evans was fairly successful as a merchant. He patented a method of making millstones as well as a means of packing flour in barrels, the latter having a disc pressed down by a toggle-joint arrangement. In 1801 he started to build a steam carriage. He rejected the idea of a steam wheel and of a low-pressure or atmospheric engine. By 1803 his first engine was running at his store, driving a screw-mill working on plaster of Paris for making millstones. The engine had a 6 in. (15 cm) diameter cylinder with a stroke of 18 in. (45 cm) and also drove twelve saws mounted in a frame and cutting marble slabs at a rate of 100 ft (30 m) in twelve hours. He was granted a patent in the spring of 1804. He became involved in a number of lawsuits following the extension of his patent, particularly as he increased the licence fee, sometimes as much as sixfold. The case of Evans v. Samuel Robinson, which Evans won, became famous and was one of these. Patent Right Oppression Exposed, or Knavery Detected, a 200-page book with poems and prose included, was published soon after this case and was probably written by Oliver Evans. The steam engine patent was also extended for a further seven years, but in this case the licence fee was to remain at a fixed level. Evans anticipated Edison in his proposal for an "Experimental Company" or "Mechanical Bureau" with a capital of thirty shares of $100 each. It came to nothing, however, as there were no takers. His first wife, Sarah, died in 1816 and he remarried, to Hetty Ward, the daughter of a New York innkeeper. He was buried in the Bowery, on Lower Manhattan; the church was sold in 1854 and again in 1890, and when no relative claimed his body he was reburied in an unmarked grave in Trinity Cemetery, 57th Street, Broadway.

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Further Reading

E.S.Ferguson, 1980, Oliver Evans: Inventive Genius of the American Industrial Revolution, Hagley Museum.

G.Bathe and D.Bathe, 1935, Oliver Evans: Chronicle of Early American Engineering, Philadelphia, Pa.

IMcN

Goulding, John

SUBJECT AREA: Textiles

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b. 1791 Massachusetts, USA d. 1877

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American inventor of an early form of condenser carding machine.

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The condenser method of spinning was developed chiefly by manufacturers and machine makers in eastern Massachusetts between 1824 and 1826. John Goulding, a machinist from Dedham in Massachusetts, combined the ring doffer, patented by Ezekiel Hale in 1825, and the revolving twist tube, patented by George Danforth in 1824; with the addition of twisting keys in the tubes, the carded woollen sliver could be divided and then completely and continuously twisted. He divided the carded web longitudinally with the ring doffer and twisted these strips to consolidate them into slubbings. The dividing was carried out by covering the periphery of the doffer cylinder with separate rings of card clothing and spacing these rings apart by rings of leather, so that instead of width-way detached strips leaving the card, the strips were continuous and did not require piecing. The strips were passed through rotating tubes and wound on bobbins, and although the twist was false it sufficed to compress the fibres together ready for spinning. Goulding patented his invention in both Britain and the USA in 1826, but while his condensers were very successful and within twenty years had been adopted by a high proportion of woollen mills in America, they were not adopted in Britain until much later. Goulding also worked on other improvements to woollen machinery: he developed friction drums, on which the spools of roving from the condenser cards were placed to help transform the woollen jenny into the woollen mule or jack.

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Bibliography

1826, British patent no. 5,355 (condenser carding machine).

Further Reading

D.J.Jeremy, 1981, Transatlantic Industrial Revolution. The Diffusion of Textile Technologies Between Britain and America, 1790–1830s, Oxford (provides a good explanation of the development of the condenser card).

W.English, 1969, The Textile Industry, London (a brief account).

C.Singer (ed.), 1958, A History of Technology, Vol. IV, Oxford: Clarendon Press (a brief account).

RLH

Kilby, Jack St Clair

SUBJECT AREA: Electronics and information technology

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b. 8 November 1923 Jefferson City, Missouri, USA

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American engineer who filed the first patents for micro-electronic (integrated) circuits.

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Kilby spent most of his childhood in Great Bend, Kansas, where he often accompanied his father, an electrical power engineer, on his maintenance rounds. Working in the blizzard of 1937, his father borrowed a "ham" radio, and this fired Jack to study for his amateur licence (W9GTY) and to construct his own equipment while still a student at Great Bend High School. In 1941 he entered the University of Illinois, but four months later, after the attack on Pearl Harbor, he was enlisted in the US Army and found himself working in a radio repair workshop in India. When the war ended he returned to his studies, obtaining his BSEE from Illinois in 1947 and his MSEE from the University of Wisconsin. He then joined Centralab, a small electronics firm in Milwaukee owned by Globe-Union. There he filed twelve patents, including some for reduced titanate capacitors and for Steatite-packing of transistors, and developed a transistorized hearing-aid. During this period he also attended a course on transistors at Bell Laboratories. In May 1958, concerned to gain experience in the field of number processing, he joined Texas Instruments in Dallas. Shortly afterwards, while working alone during the factory vacation, he conceived the idea of making monolithic, or integrated, circuits by diffusing impurities into a silicon substrate to create P-N junctions. Within less than a month he had produced a complete oscillator on a chip to prove that the technology was feasible, and the following year at the 1ERE Show he demonstrated a germanium integrated-circuit flip-flop. Initially he was granted a patent for the idea, but eventually, after protracted litigation, priority was awarded to Robert Noyce of Fairchild. In 1965 he was commissioned by Patrick Haggerty, the Chief Executive of Texas Instruments, to make a pocket calculator based on integrated circuits, and on 14 April 1971 the world's first such device, the Pocketronic, was launched onto the market. Costing $150 (and weighing some 2½ lb or 1.1 kg), it was an instant success and in 1972 some 5 million calculators were sold worldwide. He left Texas Instruments in November 1970 to become an independent consultant and inventor, working on, amongst other things, methods of deriving electricity from sunlight.

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Principal Honours and Distinctions

Franklin Institute Stuart Ballantine Medal 1966. Institute of Electrical and Electronics Engineers David Sarnoff Award 1966; Cledo Brunetti Award (jointly with Noyce) 1978; Medal of Honour 1986. National Academy of Engineering 1967. National Science Medal 1969. National Inventors Hall of Fame 1982. Honorary DEng Miami 1982, Rochester 1986. Honorary DSc Wisconsin 1988. Distinguished Professor, Texas A \& M University.

Bibliography

6 February 1959, US patent no. 3,138,743 (the first integrated circuit (IC); initially granted June 1964).

US patent no. 3,819,921 (the Pocketronic calculator).

Further Reading

T.R.Reid, 1984, Microchip. The Story of a Revolution and the Men Who Made It, London: Pan Books (for the background to the development of the integrated circuit). H.Queisser, 1988, Conquest of the Microchip, Cambridge, Mass.: Harvard University Press.

KF

Meikle, Andrew

SUBJECT AREA: Agricultural and food technology

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b. 1719 Scotland

d. 27 November 1811

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Scottish millwright and inventor of the threshing machine.

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The son of the millwright James Meikle, who is credited with the introduction of the winnowing machine into Britain, Andrew Meikle followed in his father's footsteps. His inventive inclinations were first turned to developing his father's idea, and together with his own son George he built and patented a double-fan winnowing machine.

However, in the history of agricultural development Andrew Meikle is most famous for his invention of the threshing machine, patented in 1784. He had been presented with a model of a threshing mill designed by a Mr Ilderton of Northumberland, but after failing to make a full-scale machine work, he developed the concept further. He eventually built the first working threshing machine for a farmer called Stein at Kilbagio. The patent revolutionized farming practice because it displaced the back-breaking and soul-destroying labour of flailing the grain from the straw. The invention was of great value in Scotland and in northern England when the land was becoming underpopulated as a result of heavy industrialization, but it was bitterly opposed in the south of England until well into the nineteenth century. Although the introduction of the threshing machine led to the "Captain Swing" riots of the 1830s, in opposition to it, it shortly became universal.

Meikle's provisional patent in 1785 was a natural progression of earlier attempts by other millwrights to produce such a machine. The published patent is based on power provided by a horse engine, but these threshing machines were often driven by water-wheels or even by windmills. The corn stalks were introduced into the machine where they were fed between cast-iron rollers moving quite fast against each other to beat the grain out of the ears. The power source, whether animal, water or wind, had to cause the rollers to rotate at high speed to knock the grain out of the ears. While Meikle's machine was at first designed as a fixed barn machine powered by a water-wheel or by a horse wheel, later threshing machines became mobile and were part of the rig of an agricultural contractor.

In 1788 Meikle was awarded a patent for the invention of shuttered sails for windmills. This patent is part of the general description of the threshing machine, and whilst it was a practical application, it was superseded by the work of Thomas Cubitt.

At the turn of the century Meikle became a manufacturer of threshing machines, building appliances that combined the threshing and winnowing principles as well as the reciprocating "straw walkers" found in subsequent threshing machines and in conventional combine harvesters to the present day. However, he made little financial gain from his invention, and a public subscription organized by the President of the Board of Agriculture, Sir John Sinclair, raised £1,500 to support him towards the end of his life.

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Bibliography

1831, Threshing Machines in The Dictionary of Mechanical Sciences, Arts and Manufactures, London: Jamieson, Alexander.

7 March 1768, British patent no. 896, "Machine for dressing wheat, malt and other grain and for cleaning them from sand, dust and smut".

9 April 1788, British patent no. 1,645, "Machine which may be worked by cattle, wind, water or other power for the purpose of separating corn from the straw".

Further Reading

J.E.Handley, 1953, Scottish Farming in the 18th Century, and 1963, The Agricultural Revolution in Scotland (both place Meikle and his invention within their context).

G.Quick and W.Buchele, 1978, The Grain Harvesters, American Society of Agricultural Engineers (gives an account of the early development of harvesting and cereal treatment machinery).

KM / AP

Owens, Michael Joseph

SUBJECT AREA: Agricultural and food technology, Domestic appliances and interiors

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b. 1 January 1859 Mason County, Virginia, USA

d. 27 December 1923 Toledo, Ohio, USA

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American inventor of the automatic glass bottle making machine.

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To assist the finances of a coal miner's family, Owens entered a glassworks at Wheeling, Virginia, at the tender age of 10, stoking coal into the "glory hole" or furnace where glass was resoftened at various stages of the hand-forming process. By the age of 15 he had become a glassblower.

In 1888 Owens moved to the glassworks of Edward Drummond Libbey at Toledo, Ohio, where within three months he was appointed Superintendent and, not long after, a branch manager. In 1893 Owens supervised the company's famous exhibit at the World's Columbian Exposition at Chicago. He had by then begun experiments that were to lead to the first automatic bottle-blowing machine. He first used a piston pump to suck molten glass into a mould, and then transferred the gathered glass over another mould into which the bottle was blown by reversing the pump. The first patents were taken out in 1895, followed by others incorporating improvements and culminating in the patent of 8 November 1904 for an essentially perfected machine. Eventually it was capable of producing four bottles a second, thus effecting a revolution in bottle making. Owens, with Libbey and others, set up the Owens Bottle Machine Company in 1903, which Owens himself managed from 1915 to 1919, becoming Vice-President from 1915 until his death. A plant was also established in Manchester in 1905.

Besides this, Owens and Libbey first assisted Irving W.Colburn with his experiments on the continuous drawing of flat sheet glass and then in 1912 bought the patents, forming the Owens-Libbey Sheet Glass Company. In all, Owens was granted forty-five US patents, mainly relating to the manufacture and processing of glass. Owens's undoubted inventive genius was hampered by a lack of scientific knowledge, which he made good by judicious consultation.

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Further Reading

1923, Michael J.Owens (privately printed) (a series of memorial articles reprinted from various sources).

G.S.Duncan, 1960, Bibliography of Glass, Sheffield: Society of Glass Manufacturers (cites references to Owens's papers and patents).

LRD

Pierce, John Robinson

SUBJECT AREA: Aerospace, Electronics and information technology, Telecommunications

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b. 27 March 1910 Des Moines, Iowa, USA

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American scientist and communications engineer said to be the "father" of communication satellites.

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From his high-school days, Pierce showed an interest in science and in science fiction, writing under the pseudonym of J.J.Coupling. After gaining Bachelor's, Master's and PhD degrees at the California Institute of Technology (CalTech) in Pasadena in 1933, 1934 and 1936, respectively, Pierce joined the Bell Telephone Laboratories in New York City in 1936. There he worked on improvements to the travelling-wave tube, in which the passage of a beam of electrons through a helical transmission line at around 7 per cent of the speed of light was made to provide amplification at 860 MHz. He also devised a new form of electrostatically focused electron-multiplier which formed the basis of a sensitive detector of radiation. However, his main contribution to electronics at this time was the invention of the Pierce electron gun—a method of producing a high-density electron beam. In the Second World War he worked with McNally and Shepherd on the development of a low-voltage reflex klystron oscillator that was applied to military radar equipment.

In 1952 he became Director of Electronic Research at the Bell Laboratories' establishment, Murray Hill, New Jersey. Within two years he had begun work on the possibility of round-the-world relay of signals by means of communication satellites, an idea anticipated in his early science-fiction writings (and by Arthur C. Clarke in 1945), and in 1955 he published a paper in which he examined various possibilities for communications satellites, including passive and active satellites in synchronous and non-synchronous orbits. In 1960 he used the National Aeronautics and Space Administration 30 m (98 1/2 ft) diameter, aluminium-coated Echo 1 balloon satellite to reflect telephone signals back to earth. The success of this led to the launching in 1962 of the first active relay satellite (Telstar), which weighed 170 lb (77 kg) and contained solar-powered rechargeable batteries, 1,000 transistors and a travelling-wave tube capable of amplifying the signal 10,000 times. With a maximum orbital height of 3,500 miles (5,600 km), this enabled a variety of signals, including full bandwidth television, to be relayed from the USA to large receiving dishes in Europe.

From 1971 until his "retirement" in 1979, Pierce was Professor of Electrical Engineering at CalTech, after which he became Chief Technologist at the Jet Propulsion Laboratories, also in Pasadena, and Emeritus Professor of Engineering at Stanford University.

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Principal Honours and Distinctions

Institute of Electrical and Electronics Engineers Morris N.Liebmann Memorial Award 1947; Edison Medal 1963; Medal of Honour 1975. Franklin Institute Stuart Ballantine Award 1960. National Medal of Science 1963. Danish Academy of Science Valdemar Poulsen Medal 1963. Marconi Award 1974. National Academy of Engineering Founders Award 1977. Japan Prize 1985. Arthur C.Clarke Award 1987. Honorary DEng Newark College of Engineering 1961. Honorary DSc Northwest University 1961, Yale 1963, Brooklyn Polytechnic Institute 1963. Editor, Proceedings of the Institute of Radio Engineers 1954–5.

Bibliography

23 October 1956, US patent no. 2,768,328 (his development of the travelling-wave tube, filed on 5 November 1946).

1947, with L.M.Field, "Travelling wave tubes", Proceedings of the Institute of Radio

Engineers 35:108 (describes the pioneering improvements to the travelling-wave tube). 1947, "Theory of the beam-type travelling wave tube", Proceedings of the Institution of

Radio Engineers 35:111. 1950, Travelling Wave Tubes.

1956, Electronic Waves and Messages. 1962, Symbols, Signals and Noise.

1981, An Introduction to Information Theory: Symbols, Signals and Noise: Dover Publications.

1990, with M.A.Knoll, Signals: Revolution in Electronic Communication: W.H.Freeman.

KF

Sholes, Christopher Latham

SUBJECT AREA: Paper and printing

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b. 14 February 1819 Mooresburg, Pennsylvania, USA

d. 17 February 1890 USA

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American inventor of the first commercially successful typewriter.

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Sholes was born on his parents' farm, of a family that had originally come from England. After leaving school at 14, he was apprenticed for four years to the local newspaper, the Danville Intelligencer. He moved with his parents to Wisconsin, where he followed his trade as journalist and printer, within a year becoming State Printer and taking charge of the House journal of the State Legislature. When he was 20 he left home and joined his brother in Madison, Wisconsin, on the staff of the Wisconsin Enquirer. After marrying, he took the editorship of the Southport Telegraph, until he became Postmaster of Southport. His experiences as journalist and postmaster drew him into politics and, in spite of the delicate nature of his health and personality, he served with credit as State Senator and in the State Assembly. In 1860 he moved to Milwaukee, where he became Editor of the local paper until President Lincoln offered him the post of Collector of Customs at Milwaukee.

That position at last gave Sholes time to develop his undoubted inventive talents. With a machinist friend, Samuel W.Soule, he obtained a patent for a paging machine and another two years later for a machine for numbering the blank pages of a book serially. At the small machine shop where they worked, there was a third inventor, Carlos Glidden. It was Glidden who suggested to Sholes that, in view of his numbering machine, he would be well equipped to develop a letter printing machine. Glidden drew Sholes's attention to an account of a writing machine that had recently been invented in London by John Pratt, and Sholes was so seized with the idea that he devoted the rest of his life to perfecting the machine. With Glidden and Soule, he took out a patent for a typewriter on June 1868 followed by two further patents for improvements. Sholes struggled unsuccessfully for five years to exploit his invention; his two partners gave up their rights in it and finally, on 1 March 1873, Sholes himself sold his rights to the Remington Arms Company for $12,000. With their mechanical skills and equipment, Remingtons were able to perfect the Sholes typewriter and put it on the market. This, the first commercially successful typewriter, led to a revolution not only in office work, but also in work for women, although progress was slow at first. When the New York Young Women's Christian Association bought six Remingtons in 1881 to begin classes for young women, eight turned up for the first les-son; and five years later it was estimated that there were 60,000 female typists in the USA. Sholes said, "I feel that I have done something for the women who have always had to work so hard. This will more easily enable them to earn a living."

Sholes continued his work on the typewriter, giving Remingtons the benefit of his results. His last patent was granted in 1878. Never very strong, Sholes became consumptive and spent much of his remaining nine years in the vain pursuit of health.

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Bibliography

23 June 1868, US patent no. 79,265 (the first typewriter patent).

Further Reading

M.H.Adler, 1973, The Writing Machine, London: Allen \& Unwin.

LRD

Wankel, Felix

SUBJECT AREA: Automotive engineering, Land transport, Steam and internal combustion engines

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b. 13 August 1902 Lahr, Black Forest, Germany

d. 9 October 1988 Lindau, Bavaria, Germany

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German internal combustion engineer, inventor of the Wankel rotary engine.

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Wankel was first employed at the German Aeronautical Research Establishment, where he worked on rotary valves and valve sealing techniques in the early 1930s and during the Second World War. In 1951 he joined NSU Motorenwerk AG, a motor manufacturer based at Neckarsulm, near Stuttgart, and began work on his rotary engine; the idea for this had first occurred to Wankel as early as 1929. He had completed his first design by 1954, and in 1957 his first prototype was tested. The Wankel engine has a three-pointed rotor, like a prism of an equilateral triangle but with the sides bowed outwards. This rotor is geared to a driveshaft and rotates within a closely fitting and slightly oval-shaped chamber so that, on each revolution, the power stroke is applied to each of the three faces of the rotor as they pass a single spark plug. Two or more rotors may be mounted coaxially, their power strokes being timed sequentially. The engine has only two moving parts, the rotor and the output shaft, making it about a quarter less in weight compared with a conventional piston engine; however, its fuel consumption is high and its exhaust emissions are relatively highly pollutant. The average Wankel engine speed is 5,500 rpm. The first production car to use a Wankel engine was the NSU Ro80, though this was preceded by the experimental NSU Spyder prototype, an open two-seater. The Japanese company Mazda is the only other automobile manufacturer to have fitted a Wankel engine to a production car, although licences were taken by Alfa Romeo, Peugeot- Citroën, Daimler-Benz, Rolls-Royce, Toyota, Volkswagen-Audi (the company that bought NSU in the mid-1970s) and many others; Daimler-Benz even produced a Mercedes C-111 prototype with a three-rotor Wankel engine. The American aircraft manufacturer Curtiss-Wright carried out research for a Wankel aero-engine which never went into production, but the Austrian company Rotax produced a motorcycle version of the Wankel engine which was fitted by the British motorcycle manufacturer Norton to a number of its models.

While Wankel became director of his own research establishment at Lindau, on Lake Constance in southern Germany, Mazda continued to improve the rotary engine and by the time of Wankel's death the Mazda RX-7 coupé had become a successful, if not high-selling, Wankel -engined sports car.

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Further Reading

N.Faith, 1975, Wankel: The Curious Story Behind the Revolutionary Rotary Engine, New York: Stein \& Day.

IMcN

krok

m (G kroku) 1. (stąpnięcie) step; (odgłos) footstep

- zrobić dwa kroki to przodu/do tyłu to take two steps forward/back

- stawiać duże/małe kroki to take big/small steps

- zbliżać się wielkimi krokami [osoba] to walk fast (do kogoś/czegoś toward(s) sb/sth); przen. [dzień, termin] to approach rapidly

- stawiać pierwsze kroki [dziecko] to take one’s first steps; przen. [firma, nauka] to be in its infancy

- stawiać pierwsze kroki jako polityk przen. to take one’s first steps in the world of politics

- usłyszeć czyjeś kroki to hear sb’s footsteps

- iść krok za krokiem to go step by step a. one step at a time

- robić coś krok za krokiem a. krok po kroku to do sth step by step a. one step at a time

- krok po kroku zdobyłem jej zaufanie little by little, I won her trust

- iść za kimś krok w krok to dog sb a. sb’s footsteps, to follow sb (about a. around everywhere)

- iść przy kimś krok w krok to walk in step with sb

- kierować swoje kroki do czegoś a. ku czemuś książk. to direct one’s steps toward(s) sth

- na każdym kroku a. co krok widać było ślady wojny the traces of war were visible at every turn

- ani kroku (dalej)! don’t move!

2. (sposób chodzenia) walk, step; (tempo chodzenia) pace

- iść szybkim/wolnym krokiem to walk at a fast/slow pace

- przyspieszyć/zwolnić kroku to speed up/slow down

- mieć sprężysty/żołnierski krok to walk with a springy/soldierly step

- dotrzymywać komuś/czemuś kroku to keep up with sb/sth także przen.

- równaj krok! (rozkaz wojskowy) get in step!

- krok defiladowy the goose-step

- iść krokiem defiladowym to (do the) goose-step

3. zw. pl (w tańcu) step zw. pl

- uczyć się kroków walca/tanga to learn the steps of the waltz/tango

- mylić krok w tańcu to be a. dance out of step

4. (posunięcie) step

- podjąć stosowne/stanowcze kroki to take appropriate/decisive steps

- skłonić kogoś do desperackiego kroku to induce sb to make a desperate move

- zdecydować się na ryzykowny krok to decide to make a risky move

- ważny krok w walce z terroryzmem a major step forward in the fight against terrorism

- uczynić krok ku zgodzie to take a step toward(s) reconciliation

- ktoś musi uczynić pierwszy krok someone has to take the first step

- krok wstecz w procesie pokojowym a step backward(s) in the peace process

- milowy krok a giant step

- to odkrycie było milowym krokiem w rozwoju współczesnej nauki this discovery was a giant step in the development of modern science

- znałem jej każdy krok I was aware of her every move

5. przen. (odległość) mieszkać o parę kroków od czegoś to live (just) a stone’s throw (away) from sth

- to dwa kroki stąd it’s just around the corner; it’s just a hop, skip, and jump from here pot.

- jesteśmy o krok a. dzieli nas krok od zwycięstwa victory is just around the corner

- stąd już tylko krok do rewolucji from there its one step to revolution

- nie odstępować kogoś na krok to follow sb everywhere

- sprawa nie posunęła się nawet na a. o krok things have gone (absolutely) nowhere, things have not moved ahead at all

- on nie ustąpi ani na krok he won’t budge an inch

6. (część ciała, spodni) crotch

- być ciasnym w kroku [spodnie, bielizna] to be tight in the crotch

- spodnie cisną a. uwierają mnie w kroku my trousers are tight in the crotch

- □ krok łyżwowy Sport ski skating

* * *

- ku; -ki; instr sg - kiem; m

( ruch) step; (przen: czyn, działanie) measure, step; ( krocze) crotch

co krok — every now and then

krok po kroku — step by step

o krok lub parę kroków stąd — (just) a few steps from here

spotykać coś na każdym kroku — to run into sth at every step

podejmować (podjąć perf) kroki w celu... — to take steps lub measures to...

iść powolnym/żwawym/szybkim krokiem — to walk at a slow/brisk/quick pace

przyśpieszyć ( perf) kroku — to speed up

zwolnić ( perf) kroku — to slow down

dotrzymywać (dotrzymać perf) komuś kroku — to keep pace with sb

stawiać pierwsze kroki (w czymś) — to be taking one's first steps (at sth)

zrobić ( perf) pierwszy krok — to make the first move

* * *

krok

mi

1. (= stąpnięcie) step; ( ciężki) plod, tramp; (= sposób chodzenia) gait, walk; krok defiladowy parade step; niepewny krok unsteady gait; równać krok fall into step; dotrzymywać komuś kroku t. przen. keep pace with sb; chodzić za kimś krok w krok follow sb around, dog sb's footsteps; posuwać się krok za krokiem go step by step; przyspieszać/zwalniać kroku speed up/slow down; skierować dokądś swoje kroki turn one's steps somewhere; wlec się żółwim krokiem lag on l. move at a snail's pace; od miłości do nienawiści tylko jeden krok there's a thin line between love and hate; ani kroku dalej! freeze!, hold it right there!; nie idę ani kroku dalej! I'm not going l. moving a step further!

2. (= odcinek drogi) step; być o krok od be one step away from; co krok at every step, every step of the way; dwa kroki stąd within a stone's throw of here; nie ruszyć się ani na krok not to move a step; spotykać coś na każdym kroku l. co krok encounter sth at every step l. every step of the way; wielki/milowy krok naprzód/wstecz a great/enormous step forward/back.

3. (= działanie) step; desperacki/fałszywy krok desperate/false step; krok po kroku step by step; podjąć konieczne/pilne kroki take necessary/urgent steps; podjąć odpowiednie kroki (prawn.) take due steps; zrobić pierwszy krok take the first steps.

4. pot. ( część ubrania) crotch.

ejido

m.

common land (history). (Mexican Spanish)

* * *

ejido

► nombre masculino

1 common land

* * *

SM common land

* * *

masculino

1) (Hist) common

2) ( en Méx) ( sistema) system of communal or cooperative farming; ( sociedad) cooperative; ( terreno) land belonging to a cooperative

* * *

masculino

1) (Hist) common

2) ( en Méx) ( sistema) system of communal or cooperative farming; ( sociedad) cooperative; ( terreno) land belonging to a cooperative

* * *

ejido

masculine

A ( Hist) common, area of common land

B (en Méx)

1 (sistema) system of communal or cooperative farming

2 (sociedad) cooperative

3 (terreno) land belonging to a cooperative

* * *

ejido sustantivo masculino ( en Méx) ( sistema) system of communal or cooperative farming;
( sociedad) cooperative;
( terreno) land belonging to a cooperative

* * *

ejido nm

1. Hist common land

2. Méx [institución] = system of cooperative land tenure

3. Méx [terreno] = piece of land farmed by a cooperative

4. Méx [sociedad] = farming cooperative

EJIDO

After the Mexican Revolution, the 1917 Constitution brought in land reform measures which established ejidos (government-owned farms run by a collective of farmers). This was actually a tradition dating back to pre-Columbian culture. The original implementation of the reform was far from thorough, but the huge land reform programme carried out under the presidency of Lázaro Cárdenas (1934-40) meant that around half of the country's arable land fell within the ejido system, and Article 27 of the Constitution guaranteed that the land could not be sold. This remained the case until 1992, when the neoliberal policies of President Carlos Salinas de Gortari officially allowed ejido land to be sold.

* * *

ejido

m Méx

traditional communal farming unit

* * *

ejido nm

1) : common land

2) Mex : cooperative

wheel

[(h)wiːl] 1. сущ.

1)

а) колесо

to align a wheel — отцентровывать колесо

to spin / turn a wheel— крутить, вертеть колесо

- front wheel

- mill wheel
- training wheels

б) тех. колесо, колёсико

idler wheel — неприводное колесо, колесо без самостоятельного привода

Geneva wheel — тех. мальтийский крест, мальтийский механизм

- driving wheel

2) = steering wheel рулевое колесо, баранка разг.; штурвал

to be at / behind the wheel — быть за рулём, управлять автомобилем; стоять у штурвала, вести судно

3) амер.

а) ( wheels) разг. автомобиль, машина

Syn:

automobile 1., car 1.

б) велосипед; мотоцикл с коляской

Syn:

bicycle 1., tricycle 1.

4) ( wheels) (сложный) механизм, (сложная) машина

the wheels of bureaucracy — бюрократическая машина

the wheels of state — государственная машина

5) кружение, вращение; круг, оборот

Syn:

rotation, turn 2., revolution II

6) = Catherine wheel "огненное колесо" ( фейерверк)

7) прялка

8) = potter's wheel гончарный круг

9) уст. припев, рефрен

10) уст. цикл, период, определённый временной промежуток

Syn:

cycle 1.

11)

а) = Fortune's wheel колесо фортуны

б) амер.; разг. "колесо", доллар

12) воен. заход флангом

right wheel! — правое плечо вперёд!

••

to break smb. on the wheel ист. — колесовать

to break a butterfly / fly on the wheel — стрелять из пушек по воробьям

to put one's shoulder to the wheel — энергично, решительно взяться за работу

- wheels within wheels

- go on wheels 2. гл.

1)

а) катить, толкать ( перед собой); везти

to wheel a cart — катить тележку

The nurse wheeled the patient into the ward. — Медсестра ввезла больного в палату.

б) ехать, двигаться ( на колёсах)

в) ( wheel into) ввозить, завозить, заводить (машину, велосипед и т. п. куда-л.)

She wheeled her bike into the garage. — Она завела велосипед в гараж.

2) = wheel (a)round

а) вертеть, поворачивать

to wheel a horse round — повернуть лошадь обратно

Syn:

revolve, rotate 1., whirl 1., roll 1.

б) описывать круги; двигаться кругами

Birds wheeled above us in the sky. — В небе над нами кружили птицы.

3) = wheel about

а) (резко) поворачиваться, оборачиваться

She wheeled around and started yelling at us. — Она резко обернулась и закричала на нас.

He wheeled round from the window. — Он отвернулся от окна.

Syn:

revolve, rotate 1., whirl 1.

б) (в корне) изменить своё мнение, точку зрения и т. п.

4) (wheel in / on / out) разг. привлекать (кого-л. или что-л.); представлять, выставлять; выносить на рассмотрение

The government wheeled out the same old arguments to support its election campaign. — Для поддержки своей избирательной кампании, правительство прибегали к всё тем же старым, избитым доводам.

Then the prosecution wheeled in a surprise witness. — Тогда обвинение выставило свидетеля, давшего весьма неожиданные показания.

5) легко проводить (что-л.), проходить (через что-л.)

6) воен. заходить или заезжать флангом

The battalion will have to wheel to the flank. — Батальон должен будет зайти с фланга.

7) уст. закружиться ( о голове), помутиться (о сознании, рассудке)

His head wheeled with the sudden change in his prospects. (F. Marryat) — От столь внезапного изменения перспектив голова у него пошла кругом.

••

- wheel and deal

Trade

   Owing to the Anglo-Portuguese Alliance, England ( Great Britain after 1707) was, until the 1920s, Portugal's main trading partner. The Methuen Treaty (1703) stipulated that Portuguese wines and English woolens would be exempt from custom duties. The imperial nationalist economic ideas of the Estado Novo directed Portuguese trade toward its Africa colonies of Angola, Mozambique, and Guinea- Bissau. The historical importance of the British export market to Portuguese trade necessitated Portugal becoming a charter member of the European Free Trade Area (EFTA) in 1959.

   When Britain joined the European Economic Community (EEC) in 1973, Portugal had to follow, with a trade agreement with the European Union (EU). Negotiations between Portugal and the EU produced an accord that stipulated mutual tariff reductions, until their disappearance in mid-1977 on industrial products, while EU member states were allowed to restrict some Portuguese textiles and paper and cork products. Tariffs were also reduced for Portuguese tinned tomatoes and fish, as well as for port wine. Since gaining full membership in the EU in 1986. Portugal's trade has shifted strongly toward continental EU member states. In the 1990s, EEC/EU member states purchased nearly 75 percent of Portugal's exports and supplied nearly 70 percent of its imports. Within the EEC/EU, Britain, Germany, France, and Spain are Portugal's a main trading partners. Portuguese trade with its former colonies fell sharply after the Revolution of 25 April 1974, as Portugal turned away from Africa and toward Europe.

   In 2007, Portugal's major commodity exports have been textiles, clothing, footwear, machinery, transportation equipment, paper and cork products, wine, tomato paste, chemicals, and plastic products. Portugal's comparative advantage lies in its low hourly costs for skilled labor, which are about 20 percent lower than other EU member states. Manufactured goods account for about 75 percent of merchandise imports; food and beverages about 10 percent; and raw materials (mainly petroleum) about 15 percent.

Whitehead, Robert

SUBJECT AREA: Weapons and armour

[br]

b. 3 January 1823 Bolton-le-Moors, Lancashire, England

d. 19 November 1903 Shrivenham, Wiltshire, England

[br]

English inventor of the torpedo.

[br]

At the age of 14 Whitehead was apprenticed by his father, who ran a cotton-bleaching business, to an engineering firm in Manchester. He moved in 1847 to join his uncle, who was the Manager of another engineering firm, and three years later Whitehead set up on his own in Milan, where he made mechanical improvements to the silk-weaving industry and designed drainage machines for the Lombardy marshes.

In 1848 he was forced to move from Italy because of the revolution and settled in Fiume, which was then part of Austria. There he concen-. trated on designing and building engines for warships, and in 1864 the Austrians invited him to participate in a project to develop a "floating torpedo". In those days the torpedo was synonymous with the underwater mine, and Whitehead believed that he could do better than this proposal and produce an explosive weapon that could propel itself through the water. He set to work with his son John and a mechanic, producing the first version of his torpedo in 1866. It had a range of only 700 yd (640 m) and a speed of just 7 knots (13 km/h), as well as depth-keeping problems, but even so, especially after he had reduced the last problem by the use of a "balance chamber", the Austrian authorities were sufficiently impressed to buy construction rights and to decorate him. Other navies quickly followed suit and within twenty years almost every navy in the world was equipped with the Whitehead torpedo, its main attraction being that no warship, however large, was safe from it. During this time Whitehead continued to improve on his design, introducing a servo-motor and gyroscope, thereby radically improving range, speed and accuracy.

[br]

Principal Honours and Distinctions

Order of Max Joseph (Austria) 1868. Légion d'honneur 1884. Whitehead also received decorations from Prussia, Denmark, Portugal, Italy and Greece.

Further Reading

Dictionary of National Biography, 1912, Vol. 3, Suppl. 2, London: Smith, Elder.

CM

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 Any points for which the bulk temperature rise was greater than 15 percent of the wall temperature rise were deleted.

 If the current encoder count is not within some present tolerance of the desired count, then the velocity data accumulated in the previous revolution are discarded.

— отбрасывать вариант

— отбрасывать цифры, стоящие после

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Выходить за пределы допуска на-- If the current encoder count is not within some present tolerance of the desired count, typically 0.1 percent, then the velocity data accumulated in the previous revolution are discarded.