development+method

усовершенствование

с. improvement; development; bringing-up to date

последние усовершенствования — recent development

показатель усовершенствования — improvement factor

техническое усовершенствование — technical improvement

технологическое усовершенствование — method improvement

усовершенствования техники — technological improvements

Синонимический ряд:

улучшение (сущ.) улучшение

Albert, Wilhelm August Julius

SUBJECT AREA: Mining and extraction technology

[br]

b. 24 January 1787 Hannover, Germany

d. 4 July 1846 Clausthal, Harz, Germany

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German mining official, successful applier of wire cable.

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After studying law at the University of Göttingen, Albert turned to the mining industry and in 1806 started his career in mining administration in the Harz district, where he became Chief Inspector of mines thirty years later. His influence on the organization of the mining industry was considerable and he contributed valuable ideas for the development of mining technology. For example, he initiated experiments with Reichenbach's water-column pump in Harz when it had been working successfully in the transportation of brine in Bavaria, and he encouraged Dörell to work on his miner's elevator.

The increasing depths of shafts in the Harz district brought problems with hoisting as the ropes became too heavy and tended to break. At the beginning of the nineteenth century, iron link chains replaced the hempen ropes which were expensive and wore out too quickly, especially in the wet conditions in the shafts. After he had experimented for six years using counterbalancing iron link chains, which broke too easily, in 1834 he conceived the idea of producing stranded cables from iron wires. Their breaking strength and flexibility depended greatly on the softness of the iron and the way of laying the strands. Albert produced the cable by attaching the wires to strings which he turned evenly; this method became known as "Albert lay". He was not the first to conceive the idea of metal cables: there exists evidence for such cables as far back as Pompeii; Leonardo da Vinci made sketches of cables made from brass wires; and in 1780 the French engineer Reignier applied iron cables for lightning conductors. The idea also developed in various other mining areas, but Albert cables were the first to gain rapidly direct common usage worldwide.

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Bibliography

1835, "Die Anfertigung von Treibseilen aus geflochtenem Eisendraht", Karstens Archiv 8: 418–28.

Further Reading

K.Karmarsch, "W.A.J.Albert", Allgemeine deutsche Biographie 1:212–3.

W.Bornhardt, 1934, W.A.J.Albert und die Erfindung der Eisendrahtseile, Berlin (a detailed description of his inventions, based on source material).

C.Bartels, 1992, Vom frühneuzeitlichen Montangewerbe zur Bergbauindustrie, Bochum: Deut sches Bergbau-Museum (evaluates his achievements within the framework of technological development in the Harz mining industry).

WK

Bentham, Sir Samuel

SUBJECT AREA: Ports and shipping

[br]

b. 11 January 1757 England

d. 31 May 1831 London, England

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English naval architect and engineer.

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He was the son of Jeremiah Bentham, a lawyer. His mother died when he was an infant and his early education was at Westminster. At the age of 14 he was apprenticed to a master shipwright at Woolwich and later at Chatham Dockyard, where he made some small improvements in the fittings of ships. In 1778 he completed his apprenticeship and sailed on the Bienfaisant on a summer cruise of the Channel Fleet where he suggested and supervised several improvements to the steering gear and gun fittings.

Unable to find suitable employment at home, he sailed for Russia to study naval architecture and shipbuilding, arriving at St Petersburg in 1780, whence he travelled throughout Russia as far as the frontier of China, examining mines and methods of working metals. He settled in Kritchev in 1782 and there established a small shipyard with a motley work-force. In 1784 he was appointed to command a battalion. He set up a yard on the "Panopticon" principle, with all workshops radiating from his own central office. He increased the armament of his ships greatly by strengthening the hulls and fitting guns without recoil, which resulted in a great victory over the Turks at Liman in 1788. For this he was awarded the Cross of St George and promoted to Brigadier- General. Soon after, he was appointed to a command in Siberia, where he was responsible for opening up the resources of the country greatly by developing river navigation.

In 1791 he returned to England, where he was at first involved in the development of the Panopticon for his brother as well as with several other patents. In 1795 he was asked to look into the mechanization of the naval dockyards, and for the next eighteen years he was involved in improving methods of naval construction and machinery. He was responsible for the invention of the steam dredger, the caisson method of enclosing the entrances to docks, and the development of non-recoil cannonades of large calibre.

His intervention in the maladministration of the naval dockyards resulted in an enquiry that brought about the clearing-away of much corruption, making him very unpopular. As a result he was sent to St Petersburg to arrange for the building of a number of ships for the British navy, in which the Russians had no intention of co-operating. On his return to England after two years he was told that his office of Inspector-General of Navy Works had been abolished and he was appointed to the Navy Board; he had several disagreements with John Rennie and in 1812 was told that this office, too, had been abolished. He went to live in France, where he stayed for thirteen years, returning in 1827 to arrange for the publication of some of his papers.

There is some doubt about his use of his title: there is no record of his having received a knighthood in England, but it was assumed that he was authorized to use the title, granted to him in Russia, after his presentation to the Tsar in 1809.

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Further Reading

Mary Sophia Bentham, Life of Brigadier-General Sir Samuel Bentham, K.S.G., Formerly Inspector of Naval Works (written by his wife, who died before completing it; completed by their daughter).

IMcN

Bettini, Gianni

SUBJECT AREA: Recording

[br]

b. 1860 Novara, Italy

d. 27 February 1938 San Remo, Italy

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Italian developer of equipment for recording, duplicating and reproducing phonograph cylinders.

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He was a nobleman and an Italian cavalry lieutenant and went to the USA, where he married Daisy Abbott (of Stamford, Connecticut). From 1888 he made amateur recordings of a wide circle of artistic acquaintances and improved the recording diaphragm attachment by the development of a "spider" (a mechanical link that attacks the diaphragm in several points on its surface, rather than in the centre only). From 1892, through the Bettini Phonograph Laboratories, he published recordings of operatic artists and selections, and this led to the development of improved duplicating techniques by the so-called pantographic method. In 1901 he sold his US company and moved to Paris, although he continued to publish both cylinders and discs. In 1908 Bettini made a venture into cinematography, without success.

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Bibliography

US patent no. 409,003 (the "spider" device). US patent no. 488,381 (duplication).

Further Reading

O.Read and W.L.Welch, 1959, From Tin Foil to Stereo, Indianapolis: Howard W.Sams, pp. 69–78.

GB-N

Birdseye, Clarence

SUBJECT AREA: Agricultural and food technology

[br]

b. 9 December 1886 Brooklyn, New York, USA

d. 7 October 1956 USA

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American inventor of the fast-freezing method of food preservation.

[br]

Clarence Birdseye went to high school at Montclair in New Jersey, and from there to Amherst College between 1906 and 1910. He became a field naturalist on the US Department of Agriculture's survey of 1910 to 1912, and during the following five years worked as a fur trader. He was the Purchasing Agent for the US Navy Corps between 1917 and 1919, and acted as Assistant to the President of the US Fisherman's Association between 1920 and 1922.

Birdseye was a keen fisherman, and during his time in Labrador learnt how to fast-freeze his catch in the wind. He formed the Birdseye Seafood Company in 1923 and pioneered the development of quick-freezing methods for the preservation of dressed seafood. His first company went bankrupt, but he quickly formed the General Seafoods Corporation. He filed his first patent in 1924 for the plate freezer, and in the late 1920s developed the double belt freezer. In 1929 Birdseye's company was bought out for $22 million, Birdseye himself receiving $1 million. He was an active member of the American Fisherman's Society, the American Society of Refrigeration Engineers, the American Society of Mechanical Engineers, the American Society of Mammalogists and the Institute of Food Technologists.

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Principal Honours and Distinctions

Nutrition Foundation Stephen M.Babcock Award 1949.

Further Reading

W.H.Clark and J.Moynahan, Famous Leaders of Industry (gives a brief account of Birdseye's life).

1982, Frozen Food Age (August) (an account of the development of the industry he created).

AP

Brown, Charles Eugene Lancelot

SUBJECT AREA: Electricity, Public utilities, Railways and locomotives

[br]

b. 17 June 1863 Winterthur, Switzerland

d. 2 May 1924 Montagnola, Italy

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English engineer who developed polyphase electrical generation and transmission plant.

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After attending the Technical College in Winterthur, Brown served with Emile Burgin in Basle before entering the Oerlikon engineering works near Zurich. Two years later he became Director of the electrical department of Oerlikon and from that time was involved in the development of electrical equipment for the generation and distribution of power. The Lauffen-Frankfurt 110-mile (177 km) transmission line of 1891 demonstrated the commercial feasibility of transmitting electrical power over great distances with three-phase alternating current. For this he designed a generator and early examples of oil-cooled transformers, and the scheme gave an impetus to the development of electric-power transmission throughout Europe. In 1891, in association with Walter Boveri, Brown founded the works of Brown Boveri \& Co. at Baden, Switzerland, and until his retirement in 1911 he devoted his energies to the design of polyphase alternating-current machinery. Important installations included the Frankfurt electricity works (1894), the Paderno-Milan transmission line, and the Lugano tramway of 1894, the first system in Europe to use three-phase traction motors. This tramway was followed by many other polyphase and mountain railways. The acquisition by Brown Boveri \& Co. in 1900 of the manufacturing rights of the Parsons steam turbine directed Brown's attention to problems associated with high-speed machines. Recognizing the high centrifugal stress involved, he began to employ solid cylindrical generator rotors with slots for the excitation winding, a method that has come to be universally adopted in large alternators.

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Bibliography

3 December 1901, British patent no. 24,632 (slotted rotor for alternators).

Further Reading

Obituary, 1924, The Engineer 137:543.

Ake T.Vrenthem, 1980, Jonas Wenstrom and the Three Phase System, Stockholm, pp. 26–8 (obituary).

75 Years of Brown Boveri, 1966, Baden, Switzerland (for a company history).

GW

Eccles, William Henry

SUBJECT AREA: Electronics and information technology, Telecommunications

[br]

b. 23 August 1875 Ulverston, Cumbria, England

d. 27 April 1966 Oxford, England

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English physicist who made important contributions to the development of radio communications.

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After early education at home and at private school, Eccles won a scholarship to the Royal College of Science (now Imperial College), London, where he gained a First Class BSc in physics in 1898. He then worked as a demonstrator at the college and studied coherers, for which he obtained a DSc in 1901. Increasingly interested in electrical engineering, he joined the Marconi Company in 1899 to work on oscillators at the Poole experimental radio station, but in 1904 he returned to academic life as Professor of Mathematics and Physics and Department Head at South West Polytechnic, Chelsea. There he discovered ways of using the negative resistance of galena-crystal detectors to generate oscillations and gave a mathematical description of the operation of the triode valve. In 1910 he became Reader in Engineering at University College, London, where he published a paper explaining the reflection of radio waves by the ionosphere and designed a 60 MHz short-wave transmitter. From 1916 to 1926 he was Professor of Applied Physics and Electrical Engineering at the Finsbury City \& Guilds College and a private consulting engineer. During the First World War he was a military scientific adviser and Secretary to the Joint Board of Scientific Societies. After the war he made many contributions to electronic-circuit development, many of them (including the Eccles-Jordan "flip-flop" patented in 1918 and used in binary counters) in conjunction with F.W.Jordan, about whom little seems to be known. Illness forced Eccles's premature academic retirement in 1926, but he remained active as a consultant for many years.

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Principal Honours and Distinctions

FRS 1921. President, Institution of Electrical Engineers, 1926–7. President, Physical Society 1929. President, Radio Society of Great Britain.

Bibliography

1912, "On the diurnal variation of the electric waves occurring in nature and on the propagation of electric waves round the bend of the earth", Proceedings of the Royal Society 87:79. 1919, with F.W.Jordan, "Method of using two triode valves in parallel for generating oscillations", Electrician 299:3.

1915, Handbook of Wireless Telegraphy.

1921, Continuous Wave Wireless Telegraphy.

Further Reading

1971, "William Henry Eccles, 1875–1966", Biographical Memoirs of the Royal Society, London, 17.

See also: Heaviside, Oliver; Kennelly, Arthur Edwin

KF

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

Johnson, Eldridge Reeves

SUBJECT AREA: Recording

[br]

b. 18 February 1867 Wilmington, Delaware, USA

d. 14 November 1945 Moorestown, New Jersey, USA

[br]

American industrialist, founder and owner of the Victor Talking Machine Company; developer of many basic constructions in mechanical sound recording and the reproduction and manufacture of gramophone records.

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He graduated from the Dover Academy (Delaware) in 1882 and was apprenticed in a machine-repair firm in Philadelphia and studied in evening classes at the Spring Garden Institute. In 1888 he took employment in a small Philadelphia machine shop owned by Andrew Scull, specializing in repair and bookbinding machinery. After travels in the western part of the US, in 1891 he became a partner in Scull \& Johnson, Manufacturing Machinists, and established a further company, the New Jersey Wire Stitching Machine Company. He bought out Andrew Scull's interest in October 1894 (the last instalment being paid in 1897) and became an independent general machinist. In 1896 he had perfected a spring motor for the Berliner flat-disc gramophone, and he started experimenting with a more direct method of recording in a spiral groove: that of cutting in wax. Co-operation with Berliner eventually led to the incorporation of the Victor Talking Machine Company in 1901. The innumerable court cases stemming from the fact that so many patents for various elements in sound recording and reproduction were in very many hands were brought to an end in 1903 when Johnson was material in establishing cross-licencing agreements between Victor, Columbia Graphophone and Edison to create what is known as a patent pool. Early on, Johnson had a thorough experience in all matters concerning the development and manufacture of both gramophones and records. He made and patented many major contributions in all these fields, and his approach was very business-like in that the contribution to cost of each part or process was always a decisive factor in his designs. This attitude was material in his consulting work for the sister company, the Gramophone Company, in London before it set up its own factories in 1910. He had quickly learned the advantages of advertising and of providing customers with durable equipment and records. This motivation was so strong that Johnson set up a research programme for determining the cause of wear in records. It turned out to depend on groove profile, and from 1911 one particular profile was adhered to and processes for transforming the grooves of valuable earlier records were developed. Without precise measuring instruments, he used the durability as the determining factor. Johnson withdrew more and more to the role of manager, and the Victor Talking Machine Company gained such a position in the market that the US anti-trust legislation was used against it. However, a generation change in the Board of Directors and certain erroneous decisions as to product line started a decline, and in February 1926 Johnson withdrew on extended sick leave: these changes led to the eventual sale of Victor. However, Victor survived due to the advent of radio and the electrification of replay equipment and became a part of Radio Corporation of America. In retirement Johnson took up various activities in the arts and sciences and financially supported several projects; his private yacht was used in 1933 in work with the Smithsonian Institution on a deep-sea hydrographie and fauna-collecting expedition near Puerto Rico.

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Bibliography

Johnson's patents were many, and some were fundamental to the development of the gramophone, such as: US patent no. 650,843 (in particular a recording lathe); US patent nos. 655,556, 655,556 and 679,896 (soundboxes); US patent no. 681,918 (making the original conductive for electroplating); US patent no. 739,318 (shellac record with paper label).

Further Reading

Mrs E.R.Johnson, 1913, "Eldridge Reeves Johnson (1867–1945): Industrial pioneer", manuscript (an account of his early experience).

E.Hutto, Jr, "Emile Berliner, Eldridge Johnson, and the Victor Talking Machine Company", Journal of AES 25(10/11):666–73 (a good but brief account based on company information).

E.R.Fenimore Johnson, 1974, His Master's Voice was Eldridge R.Johnson, Milford, Del.

(a very personal biography by his only son).

GB-N

Pääbo, Max

SUBJECT AREA: Textiles

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b. Estonia fl. 1950s Sweden

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Estonian inventor of one of the most successful looms, in which the weft is sent across the warp by a jet of air.

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The earliest patent for using a jet of air to propel a shuttle across a loom was granted to J.C. Brooks in 1914. A different method was tried by E.H.Ballou in 1929, but the really important patent was taken out by Max Pääbo, a refugee from Estonia. He exhibited his machine in Sweden in 1951, weaving cotton cloth 80 cm (31 1/2 in.) wide at a speed of 350 picks per minute, but it was not widely publicized until 1954. One shown in Manchester in 1958 ran at 410 picks per minute while weaving 90 cm (35 1/2 in.) cloth. His looms were called "Maxbo" after him. They had no shuttle; instead a jet of air drove a measured amount of weft drawn from a supply package across the warp threads. Efficient control of the airstream was the main reason for its success; not only was weaving much quicker, but it was also much quieter than traditional methods, and as the warp was nearly vertical the looms took up little space. Manufacture of these looms in Sweden ceased in 1962, but development continued in other countries.

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Further Reading

J.J.Vincent, 1980, Shuttle less Looms, Manchester (a good account of the development of modern looms).

RLH

Pierce, John Robinson

SUBJECT AREA: Aerospace, Electronics and information technology, Telecommunications

[br]

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

Pilkington, Sir Lionel Alexander Bethune (Alastair)

SUBJECT AREA: Chemical technology

[br]

b. 7 January 1920 Calcutta, India

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English inventor of the float-glass process.

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Pilkington was educated at Sherborne School and Trinity College, Cambridge, where he graduated in mechanical science. He spent one year at Cambridge followed by war service, which lasted until 1945. He returned to complete his degree and then joined Pilkington, the well-known glass manufacturer at St Helens' Lancashire, in 1947. Sir Alastair is not, however, related to the Pilkington family of glassmakers.

The forming of perfectly flat glass that retained its fire finish had eluded glassmakers for centuries. Until the 1950s the only way of making really flat glass was to form plate glass by continuous casting between steel rollers. This destroyed the fire finish, which had to be restored by expensive grinding and polishing. The process entailed the loss of 20 per cent of good glass. The idea of floating glass on molten metal occurred to Sir Alastair in October 1952, and thereafter he remained in charge of development until commercial success had been achieved. The idea of floating molten glass on molten tin had been patented in the United States as early as 1902, but had never been pursued. The Pilkington process in essence was to float a ribbon of molten glass on a bath of molten tin in an inert atmosphere of nitrogen, to prevent oxidation of the tin. It was patented in Britain in 1957 and in the USA two years later. The first production glass issued from the plant in May 1957, although the first good glass did not appear until July 1958. The process was publicly announced the following year and was quickly taken up by the industry. It is now the universal method for manufacturing high quality flat glass.

Having seen through the greatest single advance in glassmaking and one of the most important technological developments this century, Sir Alastair became Chairman of Pilkingtons until 1980 and President thereafter.

[br]

Principal Honours and Distinctions

Knighted 1970. FRS 1969. Honorary Fellow of Trinity College, Cambridge, 1991.

Bibliography

1969, "Float glass process—the review lecture", Royal Society (13 February). 1975, "Floating windows", Proceedings of the Royal Institution, Vol. 48.

1976, "Float glass—evolution and revolution over 60 years", Glass Technology, Vol. 17, no. 5.

1963, "The development of float glass", Glass Industry, (February).

Further Reading

J.Jewkes et al., 1969, The Sources of Invention, 2nd ed., London: Macmillan.

LRD

Watkins, Alfred

SUBJECT AREA: Photography, film and optics

[br]

b. 1854 Hereford, England

d. 7 April 1935 Hereford, England

[br]

English photographer who developed the first practical exposure-measuring system.

[br]

His first patent was granted on 27 January 1890 and described a method of measuring the "actinic" value of light as a means of determining exposure. A strip of sensitized paper which darkened on exposure to light was used, and the time taken for it to darken to match a standard tint was measured. This time could be used to calculate the necessary exposure time, taking into account the speed of the plate, shutter speed and aperture. Watkins marketed a number of these actinometer designs, of which the most popular was the Watkins Bee Meter, which was in a pocket-watch form, introduced in 1903 and remaining on sale until 1939. Watkins was concerned that photographers recognize that exposure measurement had to take into account the effect of development time and temperature. In 1893 he devised the concept of the "Watkins Factor": he showed that when plates were developed by inspection, as was the practice at the time, a fixed relationship existed between the time of the first appearance of the image and the total time required to give a fully developed negative. The Watkins Factor was the figure that the first time must be multiplied by to give the second time. Watkins published tables of factors for different brands of plates and for different developers, and marketed various aids such as specially calibrated thermometers and clocks, as aids in using "Fac-torial Development" to give consistent negatives. After the early years of the twentieth century Watkins gave up direct participation in photography and devoted his time to a variety of interests, including the plotting of ley lines in England.

BC

более поздний

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The method has been used by subsequent investigators.

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A more recent development is the application of similar genetic principles to...

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Более поздний-- Preliminary indications were that a comparison of the initial and later-time noise was a good measure of the thickness of an ash deposit.

более поздний

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The method has been used by subsequent investigators.

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A more recent development is the application of similar genetic principles to...

завоёвывать права гражданства

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Structural bonding is rapidly taking its place along with bolting, rivetting, welding, and brazing as a method of fastening.

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Another on-the-horizon development that is gaining ground is the laser.

на начальной стадии развития

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This method is still in a primitive state of development.

новаторский

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Telecommunication technology can play an important role in the development of innovative systems for delivering medical care.

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A novel attempt at the description of such systems...

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A pioneering experiment has recently been carried out by...

позволять ввести

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The development of such instruments made feasible a new method for...

развитие

. в процессе развития

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Life of the geologic past shows an orderly progression of forms from primitive to advanced types.

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The advancement of science...

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There has been tremendous growth in atomic physics.

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The control of frictional heat has been one stumbling block in the progress (or development) of this method.

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In keeping with expected progression of manned space flight from single to multimanned vehicles...

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The continuous evolution of reactor technology....

II

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The VSERP theory is an outgrowth of the Pauli exclusion principle.