university+of+st.+andrews+-+6

University of St Andrews-1

Chemistry: STA-1

University of St, Andrews - 1

Chemistry: SAO

University of St. Andrews - 2

Chemistry: SAT

University of St. Andrews - 6

Chemistry: SAS

University of St. Andrews - 7

Chemistry: SAV

Andrews University

Abbreviation: AU

Universidad Andrews

f.

Andrews University.

Watson-Watt, Sir Robert Alexander

SUBJECT AREA: Aerospace, Electronics and information technology, Weapons and armour

[br]

b. 13 April 1892 Brechin, Angus, Scotland

d. 6 December 1973 Inverness, Scotland

[br]

Scottish engineer and scientific adviser known for his work on radar.

[br]

Following education at Brechin High School, Watson-Watt entered University College, Dundee (then a part of the University of St Andrews), obtaining a BSc in engineering in 1912. From 1912 until 1921 he was Assistant to the Professor of Natural Philosophy at St Andrews, but during the First World War he also held various posts in the Meteorological Office. During. this time, in 1916 he proposed the use of cathode ray oscillographs for radio-direction-finding displays. He joined the newly formed Radio Research Station at Slough when it was opened in 1924, and 3 years later, when it amalgamated with the Radio Section of the National Physical Laboratory, he became Superintendent at Slough. At this time he proposed the name "ionosphere" for the ionized layer in the upper atmosphere. With E.V. Appleton and J.F.Herd he developed the "squegger" hard-valve transformer-coupled timebase and with the latter devised a direction-finding radio-goniometer.

In 1933 he was asked to investigate possible aircraft counter-measures. He soon showed that it was impossible to make the wished-for radio "death-ray", but had the idea of using the detection of reflected radio-waves as a means of monitoring the approach of enemy aircraft. With six assistants he developed this idea and constructed an experimental system of radar (RAdio Detection And Ranging) in which arrays of aerials were used to detect the reflected signals and deduce the bearing and height. To realize a practical system, in September 1936 he was appointed Director of the Bawdsey Research Station near Felixstowe and carried out operational studies of radar. The result was that within two years the East Coast of the British Isles was equipped with a network of radar transmitters and receivers working in the 7–14 metre band—the so-called "chain-home" system—which did so much to assist the efficient deployment of RAF Fighter Command against German bombing raids on Britain in the early years of the Second World War.

In 1938 he moved to the Air Ministry as Director of Communications Development, becoming Scientific Adviser to the Air Ministry and Ministry of Aircraft Production in 1940, then Deputy Chairman of the War Cabinet Radio Board in 1943. After the war he set up Sir Robert Watson-Watt \& Partners, an industrial consultant firm. He then spent some years in relative retirement in Canada, but returned to Scotland before his death.

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Principal Honours and Distinctions

Knighted 1942. CBE 1941. FRS 1941. US Medal of Merit 1946. Royal Society Hughes Medal 1948. Franklin Institute Elliot Cresson Medal 1957. LLD St Andrews 1943. At various times: President, Royal Meteorological Society, Institute of Navigation and Institute of Professional Civil Servants; Vice-President, American Institute of Radio Engineers.

Bibliography

1923, with E.V.Appleton \& J.F.Herd, British patent no. 235,254 (for the "squegger"). 1926, with J.F.Herd, "An instantaneous direction reading radio goniometer", Journal of

the Institution of Electrical Engineers 64:611.

1933, The Cathode Ray Oscillograph in Radio Research.

1935, Through the Weather Hours (autobiography).

1936, "Polarisation errors in direction finders", Wireless Engineer 13:3. 1958, Three Steps to Victory.

1959, The Pulse of Radar.

1961, Man's Means to his End.

Further Reading

S.S.Swords, 1986, Technical History of the Beginnings of Radar, Stevenage: Peter Peregrinus.

KF

Bell, Revd Patrick

SUBJECT AREA: Agricultural and food technology

[br]

b. 1799 Auchterhouse, Scotland

d. 22 April 1869 Carmyllie, Scotland

[br]

Scottish inventor of the first successful reaping machine.

[br]

The son of a Forfarshire tenant farmer, Patrick Bell obtained an MA from the University of St Andrews. His early association with farming kindled an interest in engineering and mechanics and he was to maintain a workshop not only on his father's farm, but also, in later life, at the parsonage at Carmyllie.

He was still studying divinity when he invented his reaping machine. Using garden shears as the basis of his design, he built a model in 1827 and a full-scale prototype the following year. Not wishing the machine to be seen during his early experiments, he and his brother planted a sheaf of oats in soil laid out in a shed, and first tried the machine on this. It cut well enough but left the straw in a mess behind it. A canvas belt system was devised and another secret trial in the barn was followed by a night excursion into a field, where corn was successfully harvested.

Two machines were at work during 1828, apparently achieving a harvest rate of one acre per hour. In 1832 there were ten machines at work, and at least another four had been sent to the United States by this time. Despite their success Bell did not patent his design, feeling that the idea should be given free to the world. In later years he was to regret the decision, feeling that the many badly-made imitations resulted in its poor reputation and prevented its adoption.

Bell's calling took precedence over his inventive interests and after qualifying he went to Canada in 1833, spending four years in Fergus, Ontario. He later returned to Scotland and be-came the minister at Carmyllie, with a living of £150 per annum.

[br]

Principal Honours and Distinctions

Late in the day he was honoured for his part in the development of the reaping machine. He received an honorary degree from the University of St Andrews and in 1868 a testimonial and £1,000 raised by public subscription by the Highland and Agricultural Society of Scotland.

Bibliography

1854, Journal of Agriculture (perhaps stung by other claims, Bell wrote his own account).

Further Reading

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

L.J.Jones, 1979, History of Technology, pp. 101–48 (gives a critical assessment of the various claims regarding the originality of the invention).

J.Hendrick, 1928, Transactions of the Highland and Agricultural Society of Scotland, pp.

51–69 (provides a celebration of Bell's achievement on its centenary).

AP

Stuart, James

SUBJECT AREA: Mechanical, pneumatic and hydraulic engineering

[br]

b. 2 January 1843 Balgonie, Fife, Scotland

d. 12 October 1913 Norwich, Norfolk, England

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Scottish engineer and educator.

[br]

James Stuart established the teaching of engineering as a university discipline at Cambridge. He was born at Balgonie in Fife, where his father managed a linen mill. He attended the University of St Andrews and then studied mathematics at Cambridge University. In 1867 he took up a post as Assistant Tutor at Trinity College, Cambridge, where his skills as a teacher were quickly recognized. The University was at that time adapting itself to the new systems of instruction recommended by the Royal Commission on university reform in the 1850s, and Stuart took an active part in the organization of a new structure of inter-collegiate lecture courses. He made an even more significant contribution to the establishment of extramural courses from which the Cambridge University extension lecture programme developed. This began in 1867, when Stuart took adult classes in Manchester and Crewe. The latter, in particular, brought him into close contact with those involved in practical mechanics and stimulated his interest in the applied sciences. In 1875 he was elected to the newly created Chair of Mechanism and Engineering in Cambridge, and he set out energetically to recruit students and to build up a flourishing unit with its own workshop and foundry, training a new generation of engineers in the applied sciences.

In November 1884 Stuart was elected to Parliament and embarked on an active but somewhat undistinguished career in politics as a radical Liberal, becoming amongst other things a keen supporter of the women's suffrage movement. This did not endear him to his academic colleagues, and the Engineering School suffered from neglect by Stuart until he resigned the Chair in 1890. By the time he left, however, the University was ready to recognize Engineering as a Tripos subject and to accept properly equipped teaching laboratories, so that his successor J.A. Ewing was able to benefit from Stuart's pioneering work. Stuart continued his political activities and was appointed a Privy Councillor in 1909. He married Elizabeth Colman after resigning the Chair, and on the death of his father-in-law in 1898 he moved to Norwich to take on the direction of the family mustard firm, J. \& J.Colman Ltd.

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Further Reading

Hilken, 1967, Engineering at Cambridge, Ch. 3, pp. 58–106.

AB

Randall, Sir John Turton

SUBJECT AREA: Medical technology

[br]

b. 23 March 1905 Newton-le-Willows, Lancashire, England

d. 16 June 1984 Edinburgh, Scotland

[br]

English physicist and biophysicist, primarily known for the development, with Boot of the cavity magnetron.

[br]

Following secondary education at Ashton-inMakerfield Grammar School, Randall entered Manchester University to read physics, gaining a first class BSc in 1925 and his MSc in 1926. From 1926 to 1937 he was a research physicist at the General Electric Company (GEC) laboratories, where he worked on luminescent powders, following which he became Warren Research Fellow of the Royal Society at Birmingham University, studying electronic processes in luminescent solids. With the outbreak of the Second World War he became an honorary member of the university staff and transferred to a group working on the development of centrimetric radar. With Boot he was responsible for the development of the cavity magnetron, which had a major impact on the development of radar.

When Birmingham resumed its atomic research programme in 1943, Randall became a temporary lecturer at the Cavendish Laboratory in Cambridge. The following year he was appointed Professor of Natural Philosophy at the University of St Andrews, but in 1946 he moved again to the Wheatstone Chair of Physics at King's College, London. There his developing interest in biophysical research led to the setting up of a multi-disciplinary group in 1951 to study connective tissues and other biological components, and in 1950– 5 he was joint Editor of Progress in Biophysics. From 1961 until his retirement in 1970 he was Professor of Biophysics at King's College and for most of that time he was also Chairman of the School of Biological Sciences. In addition, for many years he was honorary Director of the Medical Research Council Biophysics Research Unit.

After he retired he returned to Edinburgh and continued to study biological problems in the university zoology laboratory.

[br]

Principal Honours and Distinctions

Knighted 1962. FRS 1946. FRS Edinburgh 1972. DSc Manchester 1938. Royal Society of Arts Thomas Gray Memorial Prize 1943. Royal Society Hughes Medal 1946. Franklin Institute John Price Wetherill Medal 1958. City of Pennsylvania John Scott Award 1959. (All jointly with Boot for the cavity magnetron.)

Bibliography

1934, Diffraction of X-Rays by Amorphous Solids, Liquids \& Gases (describes his early work).

1953, editor, Nature \& Structure of Collagen.

1976, with H.Boot, "Historical notes on the cavity magnetron", Transactions of the Institute of Electrical and Electronics Engineers ED-23: 724 (gives an account of the cavity-magnetron development at Birmingham).

Further Reading

M.H.F.Wilkins, "John Turton Randall"—Bio-graphical Memoirs of Fellows of the Royal Society, London: Royal Society.

KF

Сент-Эндрюсский университет

Education: ( the) University of St Andrews (Великобритания www.st-andrews.ac.uk)

Carnegie, Andrew

SUBJECT AREA: Metallurgy

[br]

b. 25 November 1835 Dunfermline, Fife, Scotland

d. 11 August 1919 Lenox, Massachusetts, USA

[br]

Scottish industrialist and philanthropist.

[br]

Andrew Carnegie was a highly successful entrepreneur and steel industrialist rather than an engineer, but he made a significant contribution to engineering both through his work in industry and through his philanthropic and educational activities. His parents emigrated to the United States in 1848 and the family settled in Pennsylvania. Beginning as a telegraph boy in Pittsburgh in 1850, the young Carnegie rose through successful enterprises in railways, bridges, locomotives and rolling stock, pursuing a process of "Vertical integration" in the iron and steel industry which led to him becoming the leading American ironmaster by 1881. His interests in the Carnegie Steel Company were incorporated in the United States Steel Corporation in 1901, when Carnegie retired from business and devoted himself to philanthropy. He was particularly involved in benefactions to provide public libraries in the United States, Great Britain and other English-speaking countries. Remembering his ancestry, he was especially generous toward Scottish universities, as a result of which he was elected Rector of the University of St Andrews, Scotland's oldest university, by its students. Other large endowments were made for funds in recognition of heroic deeds, and he financed the building of the Temple of Peace at The Hague.

[br]

Bibliography

1889, The Gospel of Wealth (sets out his views on the responsible use of riches).

Further Reading

J.F.Wall, 1989, Andrew Carnegie, Pittsburgh: University of Pittsburgh Press.

AB

Russell, John Scott

SUBJECT AREA: Ports and shipping

[br]

b. 9 May 1808 Parkhead, near Glasgow, Scotland

d. 8 June 1882 Isle of Wight, England

[br]

Scottish engineer, naval architect and academic.

[br]

A son of the manse, Russell was originally destined for the Church and commenced studies at the University of St Andrews, but shortly afterwards he transferred to Glasgow, graduating MA in 1825 when only 17 years old. He began work as a teacher in Edinburgh, working up from a school to the Mechanics Institute and then in 1832 to the University, where he took over the classes in natural philosophy following the death of the professor. During this period he designed and advised on the application of steam power to road transport and to the Forth and Clyde Canal, thereby awakening his interest in ships and naval architecture.

Russell presented papers to the British Association over several years, and one of them, The Wave Line Theory of Ship Form (although now superseded), had great influence on ship designers of the time and helped to establish the formal study of hydromechanics. With a name that was becoming well known, Russell looked around for better opportunities, and on narrowly missing appointment to the Chair of Mathematics at Edinburgh University he joined the upand-coming Clyde shipyard of Caird \& Co., Greenock, as Manager in 1838.

Around 1844 Russell and his family moved to London; following some business problems he was in straitened circumstances. However, appointment as Secretary to the Committee setting up the Great Exhibition of 1851 eased his path into London's intellectual society and allowed him to take on tasks such as, in 1847, the purchase of Fairbairn's shipyard on the Isle of Dogs and the subsequent building there of I.K. Brunel's Great Eastern steamship. This unhappy undertaking was a millstone around the necks of Brunel and Russell and broke the health of the former. With the yard failing to secure the order for HMS Warrior, the Royal Navy's first ironclad, Russell pulled out of shipbuilding and for the remainder of his life was a designer, consultant and at times controversial, but at all times polished and urbane, member of many important committees and societies. He is remembered as one of the founders of the Institution of Naval Architects in 1860. His last task was to design a Swiss Lake steamer for Messrs Escher Wyss, a company that coincidentally had previously retained Sir William Fairbairn.

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Principal Honours and Distinctions

FRS 1847.

Bibliography

John Scott Russell published many papers under the imprint of the British Association, the Royal Society of Arts and the Institution of Naval Architects. His most impressive work was the mammoth three-volume work on shipbuilding published in London in 1865 entitled The Modern System of Naval Architecture. Full details and plans of the Great Eastern are included.

Further Reading

G.S.Emmerson, 1977, John Scott Russell, a Great Victorian Engineer and Naval Architect, London: Murray

FMW

Appleton, Sir Edward Victor

SUBJECT AREA: Broadcasting, Telecommunications

[br]

b. 6 September 1892 Bradford, England

d. 21 April 1965 Edinburgh, Scotland

[br]

English physicist awarded the Nobel Prize for Physics for his discovery of the ionospheric layer, named after him, which is an efficient reflector of short radio waves, thereby making possible long-distance radio communication.

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After early ambitions to become a professional cricketer, Appleton went to St John's College, Cambridge, where he studied under J.J.Thompson and Ernest Rutherford. His academic career interrupted by the First World War, he served as a captain in the Royal Engineers, carrying out investigations into the propagation and fading of radio signals. After the war he joined the Cavendish Laboratory, Cambridge, as a demonstrator in 1920, and in 1924 he moved to King's College, London, as Wheatstone Professor of Physics.

In the following decade he contributed to developments in valve oscillators (in particular, the "squegging" oscillator, which formed the basis of the first hard-valve time-base) and gained international recognition for research into electromagnetic-wave propagation. His most important contribution was to confirm the existence of a conducting ionospheric layer in the upper atmosphere capable of reflecting radio waves, which had been predicted almost simultaneously by Heaviside and Kennelly in 1902. This he did by persuading the BBC in 1924 to vary the frequency of their Bournemouth transmitter, and he then measured the signal received at Cambridge. By comparing the direct and reflected rays and the daily variation he was able to deduce that the Kennelly- Heaviside (the so-called E-layer) was at a height of about 60 miles (97 km) above the earth and that there was a further layer (the Appleton or F-layer) at about 150 miles (240 km), the latter being an efficient reflector of the shorter radio waves that penetrated the lower layers. During the period 1927–32 and aided by Hartree, he established a magneto-ionic theory to explain the existence of the ionosphere. He was instrumental in obtaining agreement for international co-operation for ionospheric and other measurements in the form of the Second Polar Year (1932–3) and, much later, the International Geophysical Year (1957–8). For all this work, which made it possible to forecast the optimum frequencies for long-distance short-wave communication as a function of the location of transmitter and receiver and of the time of day and year, in 1947 he was awarded the Nobel Prize for Physics.

He returned to Cambridge as Jacksonian Professor of Natural Philosophy in 1939, and with M.F. Barnett he investigated the possible use of radio waves for radio-location of aircraft. In 1939 he became Secretary of the Government Department of Scientific and Industrial Research, a post he held for ten years. During the Second World War he contributed to the development of both radar and the atomic bomb, and subsequently served on government committees concerned with the use of atomic energy (which led to the establishment of Harwell) and with scientific staff.

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Principal Honours and Distinctions

Knighted (KCB 1941, GBE 1946). Nobel Prize for Physics 1947. FRS 1927. Vice- President, American Institute of Electrical Engineers 1932. Royal Society Hughes Medal 1933. Institute of Electrical Engineers Faraday Medal 1946. Vice-Chancellor, Edinburgh University 1947. Institution of Civil Engineers Ewing Medal 1949. Royal Medallist 1950. Institute of Electrical and Electronics Engineers Medal of Honour 1962. President, British Association 1953. President, Radio Industry Council 1955–7. Légion d'honneur. LLD University of St Andrews 1947.

Bibliography

1925, joint paper with Barnett, Nature 115:333 (reports Appleton's studies of the ionosphere).

1928, "Some notes of wireless methods of investigating the electrical structure of the upper atmosphere", Proceedings of the Physical Society 41(Part III):43. 1932, Thermionic Vacuum Tubes and Their Applications (his work on valves).

1947, "The investigation and forecasting of ionospheric conditions", Journal of the

Institution of Electrical Engineers 94, Part IIIA: 186 (a review of British work on the exploration of the ionosphere).

with J.F.Herd \& R.A.Watson-Watt, British patent no. 235,254 (squegging oscillator).

Further Reading

Who Was Who, 1961–70 1972, VI, London: A. \& C.Black (for fuller details of honours). R.Clark, 1971, Sir Edward Appleton, Pergamon (biography).

J.Jewkes, D.Sawers \& R.Stillerman, 1958, The Sources of Invention.

KF

Marconi, Marchese Guglielmo

SUBJECT AREA: Broadcasting, Electronics and information technology, Telecommunications

[br]

b. 25 April 1874 Bologna, Italy

d. 20 July 1937 Rome, Italy

[br]

Italian radio pioneer whose inventiveness and business skills made radio communication a practical proposition.

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Marconi was educated in physics at Leghorn and at Bologna University. An avid experimenter, he worked in his parents' attic and, almost certainly aware of the recent work of Hertz and others, soon improved the performance of coherers and spark-gap transmitters. He also discovered for himself the use of earthing and of elevated metal plates as aerials. In 1895 he succeeded in transmitting telegraphy over a distance of 2 km (1¼ miles), but the Italian Telegraph authority rejected his invention, so in 1896 he moved to England, where he filed the first of many patents. There he gained the support of the Chief Engineer of the Post Office, and by the following year he had achieved communication across the Bristol Channel.

The British Post Office was also slow to take up his work, so in 1897 he formed the Wireless Telegraph \& Signal Company to work independently. In 1898 he sold some equipment to the British Army for use in the Boer War and established the first permanent radio link from the Isle of Wight to the mainland. In 1899 he achieved communication across the English Channel (a distance of more than 31 miles or 50 km), the construction of a wireless station at Spezia, Italy, and the equipping of two US ships to report progress in the America's Cup yacht race, a venture that led to the formation of the American Marconi Company. In 1900 he won a contract from the British Admiralty to sell equipment and to train operators. Realizing that his business would be much more successful if he could offer his customers a complete radio-communication service (known today as a "turnkey" deal), he floated a new company, the Marconi International Marine Communications Company, while the old company became the Marconi Wireless Telegraph Company.

His greatest achievement occurred on 12 December 1901, when Morse telegraph signals from a transmitter at Poldhu in Cornwall were received at St John's, Newfoundland, a distance of some 2,100 miles (3,400 km), with the use of an aerial flown by a kite. As a result of this, Marconi's business prospered and he became internationally famous, receiving many honours for his endeavours, including the Nobel Prize for Physics in 1909. In 1904, radio was first used to provide a daily bulletin at sea, and in 1907 a transatlantic wireless telegraphy service was inaugurated. The rescue of 1,650 passengers from the shipwreck of SS Republic in 1909 was the first of many occasions when wireless was instrumental in saving lives at sea, most notable being those from the Titanic on its maiden voyage in April 1912; more lives would have been saved had there been sufficient lifeboats. Marconi was one of those who subsequently pressed for greater safety at sea. In 1910 he demonstrated the reception of long (8 km or 5 miles) waves from Ireland in Buenos Aires, but after the First World War he began to develop the use of short waves, which were more effectively reflected by the ionosphere. By 1918 the first link between England and Australia had been established, and in 1924 he was awarded a Post Office contract for short-wave communication between England and the various parts of the British Empire.

With his achievements by then recognized by the Italian Government, in 1915 he was appointed Radio-Communications Adviser to the Italian armed forces, and in 1919 he was an Italian delegate to the Paris Peace Conference. From 1921 he lived on his yacht, the Elettra, and although he joined the Fascist Party in 1923, he later had reservations about Mussolini.

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Principal Honours and Distinctions

Nobel Prize for Physics (jointly with K.F. Braun) 1909. Russian Order of S t Anne. Commander of St Maurice and St Lazarus. Grand Cross of the Order of the Crown (i.e. Knight) of Italy 1902. Freedom of Rome 1903. Honorary DSc Oxford. Honorary LLD Glasgow. Chevalier of the Civil Order of Savoy 1905. Royal Society of Arts Albert Medal. Honorary knighthood (GCVO) 1914. Institute of Electrical and Electronics Engineers Medal of Honour 1920. Chairman, Royal Society of Arts 1924. Created Marquis (Marchese) 1929. Nominated to the Italian Senate 1929. President, Italian Academy 1930. Rector, University of St Andrews, Scotland, 1934.

Bibliography

1896, "Improvements in transmitting electrical impulses and in apparatus thereof", British patent no. 12,039.

1 June 1898, British patent no. 12,326 (transformer or "jigger" resonant circuit).

1901, British patent no. 7,777 (selective tuning).

1904, British patent no. 763,772 ("four circuit" tuning arrangement).

Further Reading

D.Marconi, 1962, My Father, Marconi.

W.J.Baker, 1970, A History of the Marconi Company, London: Methuen.

KF

Napier (Neper), John

SUBJECT AREA: Electronics and information technology

[br]

b. 1550 Merchiston Castle, Edinburgh, Scotland

d. 4 April 1617 Merchiston Castle, Edinburgh, Scotland

[br]

Scottish mathematician and theological writer noted for his discovery of logarithms, a powerful aid to mathematical calculations.

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Born into a family of Scottish landowners, at the early age of 13 years Napier went to the University of St Andrews in Fife, but he apparently left before taking his degree. An extreme Protestant, he was active in the struggles with the Roman Catholic Church and in 1594 he dedicated to James VI of Scotland his Plaine Discovery of the Whole Revelation of St John, an attempt to promote the Protestant case in the guise of a learned study. About this time, as well as being involved in the development of military equipment, he devoted much of his time to finding methods of simplifying the tedious calculations involved in astronomy. Eventually he realized that by representing numbers in terms of the power to which a "base" number needed to be raised to produce them, it was possible to perform multiplication and division and to find roots, by the simpler processes of addition, substraction and integer division, respectively.

A description of the principle of his "logarithms" (from the Gk. logos, reckoning, and arithmos, number), how he arrived at the idea and how they could be used was published in 1614 under the title Mirifici Logarithmorum Canonis Descriptio. Two years after his death his Mirifici Logarithmorum Canonis Constructio appeared, in which he explained how to calculate the logarithms of numbers and gave tables of them to eight significant figures, a novel feature being the use of the decimal point to distinguish the integral and fractional parts of the logarithm. As originally conceived, Napier's tables of logarithms were calculated using the natural number e(=2.71828…) as the base, not directly, but in effect according to the formula: Naperian logx= 107(log e 107-log e x) so that the original Naperian logarithm of a number decreased as the number increased. However, prior to his death he had readily acceded to a suggestion by Henry Briggs that it would greatly facilitate their use if logarithms were simply defined as the value to which the decimal base 10 needed to be raised to realize the number in question. He was almost certainly also aware of the work of Joost Burgi.

No doubt as an extension of his ideas of logarithms, Napier also devised a means of manually performing multiplication and division by means of a system of rods known as Napier's Bones, a forerunner of the modern slide-rule, which evolved as a result of successive developments by Edmund Gunther, William Oughtred and others. Other contributions to mathematics by Napier include important simplifying discoveries in spherical trigonometry. However, his discovery of logarithms was undoubtedly his greatest achievement.

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Bibliography

Napier's "Descriptio" and his "Constructio" were published in English translation as Description of the Marvelous Canon of Logarithms (1857) and W.R.MacDonald's Construction of the Marvelous Canon of Logarithms (1889), which also catalogues all his works. His Rabdologiae, seu Numerationis per Virgulas Libri Duo (1617) was published in English as Divining Rods, or Two Books of Numbering by Means of Rods (1667).

Further Reading

D.Stewart and W.Minto, 1787, An Account of the Life Writings and Inventions of John Napier of Merchiston (an early account of Napier's work).

C.G.Knott (ed.), 1915, Napier Tercentenary Memorial Volume (the fullest account of Napier's work).

KF

in

Präp.

1. räumlich: (wo?) in, at; einer Stadt: in; einem kleineren Ort: auch at; (innerhalb) within; im Haus in(side) the house, indoors; im ersten Stock on the first (Am. second) floor; in der Kirche / Schule at (Am. auch in) church / school; Gebäude: in the church / school; im Theater at the theat|re (Am. auch -er); in England in England; waren Sie schon in England? have you ever been to England?; ich habe in München studiert I studied at (Am. in) Munich; im Kreis in a circle

2. räumlich: (wohin?) into, in; in die Kirche / Schule to ( hinein: into the) church / school; in die Schweiz to Switzerland; gehen wir ins Haus let’s go indoors ( oder inside)

3. zeitlich: in; (während) during; (innerhalb) within; Dauer: in drei Tagen in three days; in diesem / im letzten / nächsten Jahr this / last / next year; heute in acht Tagen a week (from) today; im Jahr 2003 in (the year) 2003; im ( Monat) Februar in (the month of) February; im Frühling / Herbst in (the) spring / autumn (bes. Am. fall); in der Nacht at night, during the night; in letzter Zeit lately

4. Art und Weise: in größter Eile in a great rush; ich bin in Eile I’m in a hurry; in tiefer Trauer in Todesanzeigen: sadly missed by; wir sind in Sorge, dass... we are worried ( oder concerned) that...

5. eine Situation bezeichnend: im Alter von at the age of; in Behandlung sein be having treatment; in Vorbereitung being prepared, in preparation, in the pipeline umg.; in einem Klub etc. sein be in a club etc., belong to a club etc.; in Biologie ist er schwach he’s not very good at biology

6. WIRTS. in; er macht in Textilien umg. he’s in textiles ( oder in the textile business)

—

in2

Adj.; nur präd.: in sein umg. be in, be the fashion

* * *

in; within; into; at

* * *

ịn [ɪn]

1. prep → auch im, ins

1) (räumlich) (wo? +dat) in; (innen) in(side); (wohin? +acc) in, into

sind Sie schon in Deutschland gewesen? — have you ever been to Germany?

in der Schweiz — in Switzerland

in die Schweiz — to Switzerland

er ist Professor in St. Andrews — he is a professor at St. Andrews (University)

in die Schule/Kirche gehen — to go to school/church

er ist in der Schule/Kirche — he's at or in school/church

die Heizung in der Schule/Kirche — the heating in the school/church

er ging ins Konzert — he went to the concert

2) (zeitlich: wann? +dat) in

in diesem Jahr (laufendes Jahr) — this year; (jenes Jahr) (in) that year

heute/morgen in acht Tagen/zwei Wochen — a week/two weeks today/tomorrow

bis ins 18. Jahrhundert — into or up to the 18th century

vom 16. bis ins 18. Jahrhundert — from the 16th to the 18th century

bis ins 18. Jahrhundert zurück — back to the 18th century

3)

in Englisch steht er sehr schwach — he's very weak in or at English

das ist in Englisch — it's in English

ins Englische übersetzen — to translate into English

in Geschichte haben wir einen neuen Lehrer — we've a new teacher in or for history

in die hunderte or Hunderte gehen — to run into (the) hundreds

er macht jetzt in Gebrauchtwagen (inf) — he's in the second-hand car business now

sie hat es in sich (dat) (inf) — she's quite a girl

der Text/die Rechenarbeit hat es in sich (dat) (inf) — the text/the arithmetic test is a tough one

dieser Whisky hat es in sich (dat) (inf) — this whisky packs quite a punch (inf), this whisky has quite a kick (inf)

2. adj pred (inf)

in sein — to be in (inf)

* * *

1) at

2) (state or occupation: The countries are at war; She is at work.) at

3) (describing the position of a thing etc which is surrounded by something else: My mother is in the house; in London; in bed.) in

4) (showing the direction of movement: He put his hand in his pocket.) in

5) (describing the time at, after or within which something happens: in the morning; I'll be back in a week.) in

6) (indicating amount or relative number: They arrived in large numbers.) in

7) (expressing circumstances, state, manner etc of an event, person etc: dressed in a brown coat; walking in the rain; in a hurry; written in English; He is in the army; books tied up in bundles; She is in her sixties.) in

8) (describing something which is fashionable or popular: Short skirts are in at the moment.) in

9) (to or towards the inside of; to within: The eggs were put into the box; They disappeared into the mist.) into

10) (expressing the idea of division: Two into four goes twice.) into

11) on

12) (in or into (a vehicle, train etc): We were sitting on the bus; I got on the wrong bus.) on

13) (in the state or process of: He's on holiday.) on

14) (taking part in: He is on the committee; Which detective is working on this case?) on

15) (into a particular state or condition: She tore the letter to pieces.) to

16) under

* * *

in¹

[ɪn]

präp

1. +dat (darin befindlich) in

sie wohnt \in Berlin she lives in Berlin

bist du schon mal in New York gewesen? have you ever been to New York?

ich arbeite seit einem Jahr \in dieser Firma I've been working for this company for a year

er war nie \in einer Partei he has never been a member of a party

du siehst \in diesem Kleid toll aus you look great in that dress

es stand gestern \in der Zeitung it was in the newspaper yesterday

\in der Kirche/Schule sein to be at church/school

2. +akk (hin zu einem Ziel) into

wir fahren \in die Stadt we're going into town

er warf die Reste \in den Mülleimer he threw the leftovers in the bin

\in die Kirche/Schule gehen to go to church/school

\in die Mongolei/Schweiz to Mongolia/Switzerland

\ins Theater gehen to go to the theatre

3. +dat (innerhalb von) in

\in einem Jahr bin ich 18 in a year I'll be 18

\in diesem Augenblick at this moment

\in diesem Jahr/Monat/Sommer this year/month/summer

heute \in zwei Wochen two weeks today

4. +akk (bis zu einer Zeit) until

wir haben bis \in die Nacht getanzt we danced until the early hours

bis \in das neunzehnte Jahrhundert hinein up to [or into] the nineteenth century

bis \in jds früheste Kindheit zurück back to sb's earliest childhood

5. +akk o dat (Verweis auf ein Objekt) at

er ist Fachmann \in seinem Beruf he is an expert in his field

\in Französisch haben wir eine Muttersprachlerin we have a native speaker in [or for] French

ich habe mich \in ihm getäuscht I was wrong about him

etw hat es \in sich sth has what it takes

der Schnaps hat es \in sich the schnapps packs a punch, that's some schnapps!

6. (fachspr: mit) in

er handelt \in Textilien he deals in textiles

7. +dat (auf eine Art und Weise) in

haben Sie nichts \in Blau? haven't you got anything in blue?

\in Schwierigkeiten sein [o stecken] to be in difficulties

\in Vorbereitung sein to be being prepared

\in Wirklichkeit in reality

in²

[ɪn]

adj (fam) in fam

▪ \in sein to be in

diese Musik ist gerade \in this kind of music is really in at the moment

* * *

I 1.

Präposition mit Dat

1) (räumlich, fig.) in

er hat in Tübingen studiert — he studied at Tübingen

in Deutschland/der Schweiz — in Germany/Switzerland

sind Sie schon mal in China gewesen? — have you ever been to China?

in der Schule/Kirche — at school/church

in der Schule/Kirche steht noch eine alte Orgel — there's still an old organ in the school/church

in einer Partei — in a party

2) (zeitlich) in

in zwei Tagen/einer Woche — in two days/a week

in diesem Sommer — this summer

[gerade] in dem Moment, als er kam — the [very] moment he came

in diesem Jahr/Monat — this/that year/month

3) (modal) in

in Farbe/Schwarzweiß — in colour/black and white

in deutsch/englisch — in German/English

in Mathematik/Englisch — in mathematics/English

sich in jemandem täuschen — be wrong about somebody

4) in

er hat es in sich — (ugs.) he's got what it takes (coll.)

der Schnaps/diese Übersetzung hat es in sich — (ugs.) this schnapps packs a punch (coll.) /this translation is a tough one

5) (Kaufmannsspr.)

in etwas handeln — deal in something; s. auch im

2.

Präposition mit Akk

1) (räumlich, fig.) into

in die Stadt/das Dorf — into town/the village

in die Schweiz — to Switzerland

in die Kirche/Schule gehen — go to church/school

in eine Partei eintreten — join a party

2) (zeitlich) into

bis in den Herbst — into the autumn

3) (fig.)

in die Millionen gehen — run into millions

sich in jemanden verlieben — fall in love with somebody

in etwas einwilligen — agree or consent to something; s. auch ins

II

Adjektiv (ugs.)

in sein — be in

* * *

in¹ präp

1. räumlich: (wo?) in, at; einer Stadt: in; einem kleineren Ort: auch at; (innerhalb) within;

im Haus in(side) the house, indoors;

im ersten Stock on the first (US second) floor;

in der Kirche/Schule at (US auch in) church/school; Gebäude: in the church/school;

im Theater at the theatre (US auch -er);

in England in England;

waren Sie schon in England? have you ever been to England?;

ich habe in München studiert I studied at (US in) Munich;

im Kreis in a circle

2. räumlich: (wohin?) into, in;

in die Kirche/Schule to ( hinein: into the) church/school;

in die Schweiz to Switzerland;

gehen wir ins Haus let’s go indoors ( oder inside)

3. zeitlich: in; (während) during; (innerhalb) within; Dauer:

in drei Tagen in three days;

in diesem/im letzten/nächsten Jahr this/last/next year;

heute in acht Tagen a week (from) today;

im Jahr 2003 in (the year) 2003;

im (Monat) Februar in (the month of) February;

im Frühling/Herbst in (the) spring/autumn (besonders US fall);

in der Nacht at night, during the night;

in letzter Zeit lately

4. Art und Weise:

in größter Eile in a great rush;

ich bin in Eile I’m in a hurry;

in tiefer Trauer in Todesanzeigen: sadly missed by;

wir sind in Sorge, dass … we are worried ( oder concerned) that …

5. eine Situation bezeichnend:

im Alter von at the age of;

in Behandlung sein be having treatment;

in Vorbereitung being prepared, in preparation, in the pipeline umg;

in einem Klub etc

sein be in a club etc, belong to a club etc;

in Biologie ist er schwach he’s not very good at biology

6. WIRTSCH in;

er macht in Textilien umg he’s in textiles ( oder in the textile business)

in² adj; nur präd:

in sein umg be in, be the fashion

Küper m; -s, -, in f; -, -nen; nordd

1. (Böttcher) cooper

2. obs (Warenkontrolleur) etwa port inspector

* * *

I 1.

Präposition mit Dat

1) (räumlich, fig.) in

er hat in Tübingen studiert — he studied at Tübingen

in Deutschland/der Schweiz — in Germany/Switzerland

sind Sie schon mal in China gewesen? — have you ever been to China?

in der Schule/Kirche — at school/church

in der Schule/Kirche steht noch eine alte Orgel — there's still an old organ in the school/church

in einer Partei — in a party

2) (zeitlich) in

in zwei Tagen/einer Woche — in two days/a week

in diesem Sommer — this summer

[gerade] in dem Moment, als er kam — the [very] moment he came

in diesem Jahr/Monat — this/that year/month

3) (modal) in

in Farbe/Schwarzweiß — in colour/black and white

in deutsch/englisch — in German/English

in Mathematik/Englisch — in mathematics/English

sich in jemandem täuschen — be wrong about somebody

4) in

er hat es in sich — (ugs.) he's got what it takes (coll.)

der Schnaps/diese Übersetzung hat es in sich — (ugs.) this schnapps packs a punch (coll.) /this translation is a tough one

5) (Kaufmannsspr.)

in etwas handeln — deal in something; s. auch im

2.

Präposition mit Akk

1) (räumlich, fig.) into

in die Stadt/das Dorf — into town/the village

in die Schweiz — to Switzerland

in die Kirche/Schule gehen — go to church/school

in eine Partei eintreten — join a party

2) (zeitlich) into

bis in den Herbst — into the autumn

3) (fig.)

in die Millionen gehen — run into millions

sich in jemanden verlieben — fall in love with somebody

in etwas einwilligen — agree or consent to something; s. auch ins

II

Adjektiv (ugs.)

in sein — be in

* * *

(... hinein) präp.

into prep. (hellen) Scharen ausdr.

in droves expr. (nach) Übersee adj.

overseas adj. adj.

on adj. präp.

at prep.

in prep.

into prep.

Sea Mammal Research Unit

Veterinary medicine: SMRU (St Andrews University)

κοινός

κοινός, ή, όν (s. the numerous cognates that follow this entry; Hes.+) prim. ‘common’ (opp. ἴδιος)

① pert. to being of mutual interest or shared collectively, communal, common (so gener. Gk. lit., also LXX; EpArist, Philo, Joseph., SibOr).

ⓐ adj. (ὁ κ. πάντων πατήρ Orig., C. Cels. 8, 53, 27) τράπεζα (Diod S 4, 74, 2) Dg 5:7a. πίστις Tit 1:4. σωτηρία (cp. SIG 409, 33f [ca. 275 B.C.]; X., An. 3, 2, 32; Diod S 37, 2, 5; Polyaenus 5, 31) Jd 3. κ. ἐλπίς IEph 21:2; IPhld 5:2; 11:2. κ. ὄνομα (Philo, Abr. 7, Leg. ad Gai. 194) IEph 1:2; εἶχον ἅπαντα κ. they had everything in common (κοινὰ πάντα ἔχειν: Strabo 7, 3, 9.—Diod S 5, 9, 4: the inhabitants of Lipara τὰς οὐσίας κοινὰς ποιησάμενοι καὶ ζῶντες κατὰ συσσίτια=they made their possessions common property and lived acc. to the custom of common meals; Iambl., Vi. Pyth. 30, 168 of the Pythagoreans: κοινὰ πᾶσι πάντα … ἦν, ἴδιον δὲ οὐδεὶς οὐδὲν ἐκέκτητο. Porphyr., Vi. Pyth. 20. The word occurs in a sim. context w. ref. to the Essenes: Philo, Prob. Lib. 85; 86; Jos., Ant. 18, 20, and the Therapeutae: Philo, Vi. Cont. 32; 40; HBraun, Qumran u. d. NT, I, ’66, 43–50. Even Pla., Phdr. 279c κοινὰ τὰ τῶν φίλων) Ac 2:44; cp. 4:32 (cp. 1QS 6:2; for the recurring idea of the “other self” in antiquity s. also Persius, Satires 5, 22f; Horace, Odes 1, 3, 8; 2, 17, 5).—PSchmiedel, Die Gütergemeinschaft der ältesten Christenheit: PM 2, 1898, 367–78; EvDobschütz, Probleme des apost. Zeitalters 1904, 39ff; JBehm, Kommunismus im Urchristentum: NKZ 31, 1920, 275–97; KLake: Beginn. I/5, ’33, 140–51; Haenchen ad loc. (lit.). κοινῆς εἰκαιότητος καὶ ἀπάτης of general silliness and deceit Dg 4:6—Of body and spirit ἀμφότερα κ. ἐστιν both are in communion = belong together, cannot be separated Hs 5, 7, 4.

ⓑ subst. τὸ κοινόν what is (in) common τὸ κ. τῆς ἐλπίδος the common ground of hope 1 Cl 51:1.—τὸ κ. the society, the community (to designate all those who belong to a given group: POxy 53, 2 τὸ κ. τῶν τεκτόνων; 84, 3; Jos., Vi. 65; Orig., C. Cels. 1, 31, 26; Hippol., Ref. 9, 19, 1) διακονία εἰς τὸ κ. service for the (Christian) community IPhld 1:1. Also the common treasury (Appian, Iber. 8, §31 τὸ κ.=the state treasury) of slaves ἐλευθεροῦσθαι ἀπὸ τοῦ κ. to be freed at the expense of the common treasury (i.e. of the Christian community) IPol 4:3 (cp. X., An. 4, 7, 27; 5, 1, 12 ἀπὸ κοινοῦ=at state expense; Jos., Vi. 297 ἐκ τοῦ κ.; 298).

ⓒ adv. κοινῇ together, collectively (Soph., Thu.+; ins; PMagd 29, 2; LXX; Jos., C. Ap. 1, 70; 2, 166; Just., A I, 67, 5 and 7) IEph 20:2; ISm 12:2 (both in contrast to κατʼ ἄνδρα [‘man for man’, ‘individually’], as SIG 1073, 18); 7:2 (opp. κατʼ ἰδίαν, as Diod S 11, 24, 4; Dio Chrys. 34 [51], 9; SIG 630, 15 (restored rdg.); 2 Macc 9:26). τὸ κοινῇ συμφέρον the common good B 4:10.

② pert. to being of little value because of being common, common, ordinary, profane

ⓐ in a general sense (cp. Alcman [VII B.C.], Fgm. 49 D.² τὰ κοινά of that which ordinary people eat, in contrast to those of more refined tastes; Plut., Mor. 751b καλὸν γὰρ ἡ φιλία καὶ ἀστεῖον, ἡ δὲ ἡδονὴ κοινὸν καὶ ἀνελεύθερον [Ltzm., Hdb. on Ro 14:14]; cp. 1 Macc 1:47, 62; EpArist 315=Jos., Ant. 12, 112 κοινοὶ ἄνθρωποι; 13, 4; Iren. 4, 18, 5 [Harv. II 206, 11]). κ. ἡγεῖσθαί τι consider someth. ordinary Hb 10:29, unless this belongs in 2b.

ⓑ specifically, of that which is ceremonially impure: Rv 21:27. χεῖρες (ceremon.) impure Mk 7:2, 5 (MSmith, Tannaitic Parall. to the Gosp. ’51, 31f); οὐδὲν κ. διʼ ἑαυτοῦ nothing is unclean of itself Ro 14:14a; cp. bc of this same vs. οὐδέποτε ἔφαγον πᾶν κ. καὶ ἀκάθαρτον I have never eaten anything common or unclean (1 Macc 1:62) Ac 10:14; cp. vs. 28; 11:8 (CHouse, Andrews University Seminary Studies 21, ’83, 143–53); GJs 6:1 (s. deStrycker). Hb 10:29, s. 2a.—Dg 5:7b (see κοίτη 1b).—B. 1365. DELG. M-M. EDNT. TW. Sv.