William Oughtred

English mathematician (1575–1660)

Oughtred was born at Eton and educated at the famous school there (where his father taught writing) and at Cambridge University. He was ordained a priest in 1603 and eventually became rector of Albury.

Despite his clerical post he found time to work on mathematics and he produced what was to become a very famous book on mathematics, the Clavis mathematicae (1631; The Key to Mathematics). This work dealt with arithmetic and algebra, and it is of historical importance because Oughtred managed to put into it more or less everything that was known at that time in those areas of mathematics. It rapidly became an influential and widely used textbook and held in high regard by mathematicians of the stature of Isaac Newton and John Wallis, himself a pupil of Oughtred. A number of mathematical symbols that are still used were first introduced by Oughtred. Among these were the sign ‘×’ for multiplication, and the ‘sin’ and ‘cos’ notation for trigonometrical functions. Oughtred also invented the earliest form of the slide rule in 1622 but only published this discovery in 1632. As a result, he became embroiled in a violent dispute with one of his former students, Richard Delamain, who had made the same invention independently.

Anglican clergyman William Oughtred (1574-1660) is considered one of the world's great mathematiciansdue to his writings on the subject and his invention of the logarithmic slide rule.

Although William Oughtred was by profession an Anglican clergyman, he devoted many years of his life to expanding human understanding in the areas of algebra and calculus as well as to teaching mathematics to gifted students. Oughtred was the author of several books on mathematics and has also been credited by most historians with inventing both the linear and circular slide rules. His innovations extended to the use of many unique mathematical shorthand notations, including the notation "X" for multiplication and "::" for proportion.

Raised in Academic Environment

Oughtred was born in Eton, Buckinghamshire, England, on March 5, 1574. His father, Benjamin Oughtred, was a scholar who taught writing at Eton School, and through Benjamin's connections the younger Oughtred was educated as a king's scholar at Eton. At age 15 he entered King's College of Cambridge University and became a fellow there in 1595. Oughtred went on to receive his bachelor's degree from King's College, Cambridge, in 1596, followed by a masters of arts degree four years later. Despite the fact that Oughtred's studies at Cambridge consisted predominately of philosophy and theology, as early as age 12 he had demonstrated an extraordinary interest and talent in all things mathematical. As a college student, he had built on the rudimentary mathematical study provided to him at Eton, studying late into the night after completing his required regular studies. By the time of his graduation from Cambridge, Oughtred had already completed his first work, titled Easy Method of Mathematical Dialling.

In 1603 the 29-year-old Oughtred was ordained an Episcopal minister, a common and well-respected career option for an educated man. Applying to the church soon afterward, he gained an appointment as vicar of Shalford in 1604. In 1610 Oughtred was promoted to a position as rector of Albury, near Guilford, Surrey, in which post he served at an annual salary of 100 pounds. During his first years at Albury Oughtred married and set about tending to his parish. Despite the fame he would eventually acquire as a well-known mathematician, he remained dedicated to his flock and held his position as rector of Albury for nearly half a century, until his death in 1660.

Although never formally trained in mathematics, Oughtred clearly had a genius for the subject. Through his writings, he quickly gained renown as a mathematician and soon began to divide the time left to him after his church duties between personal study and the instruction of others. During the 1620s he began to take on as private pupils young men interested in the study of mathematics. These students - among whom were future mathematicians Richard Delamain and John Wallis as well as Christopher Wren, the future architect of St. Paul's Cathedral - shared the home and hospitality of their teacher during their mathematical studies. Eager to impart his mathematical knowledge to these brilliant young minds, Oughtred refused payment, maintaining that he was adequately provided for by his salary as a clergyman. A small man with black hair and a quick, penetrating gaze, he became known for impatiently etching mathematical diagrams in the dust that settled on tables and floors. It was not unusual, in the Oughtred home, to find its owner dressed and awake in the middle of the night while hard at work solving a mathematical problem. On his bed he had permanently affixed an ink-horn, while on the nightstand nearby a candle and tinderbox lay in easy reach, ready for the many nights when a mathematical quandary would demand a solution before Oughtred would allow himself to sleep.

In 1628 Oughtred became math tutor to Lord William Howard, son of the earl of Arundel. Desiring a suitable text to supplement his instruction of the young aristocrat, Oughtred wrote out, in summary form, all that was currently known about arithmetic and algebra. Pleased by the mathematician's efforts on behalf of his son, the earl of Arundel became a patron of Oughtred's and encouraged the rector of Albury to publish his work. The 88-page Arithmeticae in numeris et speciebus instituto … quasi clavis mathematicae est - known more commonly as Clavis mathematicae - was first published in Latin in 1631. Despite its condensed format, the book quickly drew interest from Oughtred's fellow mathematicians. By the time the second edition of the work was released in 1658, its author's reputation had been cemented in the larger community of European scientists.

In his Clavis mathematicae Oughtred describes the Hindu-Arabic system of mathematical notation, sets forth the theory of decimal fractions, and includes a detailed discussion of algebra. Throughout the work he incorporates a number of mathematical shorthand notations he had devised as a way to denote powers, relationships, ratios, and the like. While much of Oughtred's mathematical shorthand was rejected by readers as being too complicated, two of his symbols - "X" for multiplication and "::" for proportion - have gone on to become part of universal mathematical shorthand, along with those of contemporary mathematician and scientist Thomas Harriot (circa 1530-1621). Although Oughtred utilized the notation π as one of his symbols, its use signified only the circumference of a circle, not the ratio of the circumference to the diameter as it has come to denote.

Developed Logarithmic Slide Rule

The logarithmic slide rule was designed in response to the demands of the scientific renaissance that overtook Europe during Oughtred's lifetime. The astronomical calculus that grew from the work of such men as German astronomer Johann Kepler (1571-1630) and which would appear throughout the work of English scientist Sir Isaac Newton (1624-1727) demanded a means by which the multiplication and division of both extremely small and extremely large numbers could be performed quickly. These scientific and technical calculations were performed with ease using logarithms, which raise or reduce one number to an abbreviated form through the use of exponents.

The invention of logarithms is usually credited to Scottish mathematician and inventor John Napier, baron of Merchiston (1550-1617), who described his invention in 1614 in Logarithmorum canonis descriptio, although Swiss watchmaker and mathematician Justus Byrgius (1552-1633) also compiled such a system of mathematical shorthand. Napier's invention was simplified by a colleague at the University of London, professor Henry Briggs (1561-1631), who suggested that the system be designed in base 10 rather than Napier's base "e." Logarithms paved the way for the expanded scientific revolution that followed, allowing that complex operations of products and quotients be completed using simpler additions and subtractions. Their use continued until the advent of the digital calculator and the electronic computer of the twentieth century.

The use of logarithms immediately suggested an instrument that could speed calculations, and that instrument was the slide rule, an analogic calculator that through its mechanism allows for the processing of the variable data represented by logarithms. In 1620 astronomer and mathematician Edmund Gunter (1581-1626) devised "Gunter's Line," a two-foot-long ruler marked with a logarithmic scale. For operations such as the multiplication or division of numbers to several places, lengths along the ruler that are equivalent to the logarithms of the relevant numbers are added and subtracted using a pair of calipers and the result converted back to numeric form through the use of the logarithmic table. Oughtred is believed to have designed the first linear slide rule after less than a year spent wrestling with Gunter's Line and its calipers. Using two rules placed parallel to one another and connected, the position of the numbers relative to each other could now be used to calculate the desired results. By discarding the calipers, Oughtred created the prototype of the modern slide rule.

In its earliest manufactured form slide rules were made of wood, ivory, and even bamboo. They also were designed in several versions: Oughtred's linear and circular versions came first, followed by a cylindrical version, each version adapted for a particular academic discipline. The slide rule quickly gained prominence as a calculating device in every field of science and technology, from astronomy to topography to chemistry to mechanical engineering. However, it was not until the end of the eighteenth century that its importance was made clear by inventor James Watt (1736-1819), who revalued it as a tool of the Industrial Revolution. Demand for slide rules became such that by 1850 they had supplanted the use of Galileo's compass of proportions, an instrument initially intended for military use. In 1850 French army officer Victor Mayer Amdée Mannheim (1831-1906) introduced a transparent slab movable cursor; other modifications and improvements continued to be introduced in the decades that followed, resulting in the slide rule of the twentieth century.

Later Career Overshadowed by Controversy

The positive reception of his Clavis mathematicae within the scientific community prompted Oughtred to write several other books on mathematics. His 1632 work, titled Circles of Proportion and the Horizontal Instrument, described both a sundial and a circular form of slide rule that operated like Oughtred's linear slide rule: it was constructed using two concentric rings, one seated inside the other and both of which were inscribed with calibrated logarithmic scales. Ironically, this concentric slide rule, which Oughtred designed for use as a navigational instrument, had been described in a book titled Grammelogia; or, The Mathematical Ring published in 1630 by Oughtred's former student, Richard Delamain. Credit for the invention of the circular slide rule was claimed by both teacher and pupil, resulting in an enmity that lasted for the rest of Oughtred's life. Despite the likelihood that Oughtred and Delamain each individually devised the instrument, history has ultimately granted Oughtred credit for the circular slide rule.

During the final decades of his life Oughtred published six more books, among them 1657's Trigonometria, which supplements its discussion of two-and three-dimensional triangles with symbolism and tables setting forth the values of trigonometric and logarithmic functions to seven places. His 1651 work, The Solution of All Spherical Triangles, discusses the means by which the relative measurements of three-dimensional triangles can be determined; other books by Oughtred cover such subjects as the methods by which the position of the sun can be calculated and a discussion of the art of watchmaking.

Oughtred lived during tumultuous times in England. A staunch supporter of the English crown, he was shocked by the execution of the unpopular King Charles I in January of 1649. Like many who supported the cause of Charles I's son, the Prince of Wales (later Charles II), Oughtred was viewed with suspicion by the Presbyterian-influenced government that desired to take the place of the monarchy through the will of its leader, Oliver Cromwell. During the English Civil War (1642-1646) Oughtred was sequestered and scheduled for trial before Cromwell's puritanical commissioners. Due to the quick action of the astrologer Lilly and the insistence of influential friends, however, the mathematician and teacher was spared. He remained in England throughout Cromwell's reign, despite offers from foreign rulers who had heard of his fame. Oughtred died on June 30, 1660, at the parsonage in Albury. Tradition holds that he died of joy at learning that King Charles II had returned to England from Scotland and been restored to the English throne.

Books

Biographical Dictionary of Mathematicians, Scribner's, 1991.

Notable Mathematicians, Gale, 1998.

Online

Oughtred Society website,http://www.oughtred.org (March 15, 2003).

William Oughtred
William Oughtred (1575-1660).
Born	5 March 1575(1575-03-05) Eton, Buckinghamshire, England
Died	30 June 1660 (aged 85) Albury, Surrey, England
Residence	England
Nationality	English
Fields	Mathematician
Alma mater	Eton College King's College, Cambridge
Doctoral students	John Wallis Christopher Wren Richard Delamain Seth Ward
Known for	Slide rule Multiplication "×" sign
Religious stance	Anglican

William Oughtred (5 March 1574 – 30 June 1660) was an English mathematician.

After John Napier invented logarithms, and Edmund Gunter created the logarithmic scales (lines, or rules) upon which slide rules are based, it was Oughtred who first used two such scales sliding by one another to perform direct multiplication and division; and he is credited as the inventor of the slide rule in 1622. Oughtred also introduced the "×" symbol for multiplication as well as the abbreviations "sin" and "cos" for the sine and cosine functions.^[1]

Contents 1 Life 2 Interest in the occult 3 Works 3.1 Books 3.2 Slide rules 3.3 Sun dials 4 References 5 Further reading 6 External links

Life

Oughtred was born at Eton in Buckinghamshire (now part of Berkshire), and educated there and at King's College, Cambridge, of which he became fellow.^[2] Being admitted to holy orders, he left the University of Cambridge about 1603, for a living at Shalford; he was presented in 1610 to the rectory of Albury, near Guildford in Surrey, where he settled. About 1628 he was appointed by the Earl of Arundel to instruct his son in mathematics.

He corresponded with some of the most eminent scholars of his time, including William Alabaster, Sir Charles Cavendish, and William Gascoigne.^[3][4] He kept up regular contacts with Gresham College, where he knew Henry Briggs and Gunter.^[5]

He offered free mathematical tuition to pupils, who included Richard Delamain, and Jonas Moore, making him an influential teacher of a generation of mathematicians. Seth Ward resided with Oughtred for six months to learn contemporary mathematics, and the physician Charles Scarburgh also stayed at Albury; John Wallis, and Christopher Wren corresponded with him.^[6] Another Albury pupil was Robert Wood, who helped him get the Clavis through the press.^[7]

The invention of the slide rule involved Oughtred in a priority dispute with Delamain. They also disagreed on pedagogy in mathematics, with Oughtred arguing that theory should precede practice.^[8][9]

He remained rector until his death in 1660, a month after the restoration of Charles II.^[10]

Interest in the occult

Oughtred had an interest in alchemy and astrology.^[11] The testimony for his occult activities is quite slender, but there has been an accretion to his reputation based on his contemporaries.

According to John Aubrey, he was not entirely sceptical about astrology. William Lilly, an eminent astrologer, claimed in his autobiography to have intervened on behalf of Oughtred to prevent his ejection by Parliament in 1646.^[12][13] In fact Oughtred was protected at this time by Bulstrode Whitelocke.^[14]

Elias Ashmole was (according to Aubrey) a neighbour in Surrey, though Ashmole's estates acquired by marriage were over the county line in Berkshire; and Oughtred's name has been mentioned in purported histories of early freemasonry, a suggestion that Oughtred was present at Ashmole's 1646 initiation going back to Thomas De Quincey.^[15][16] It was used by George Wharton in publishing The Cabal of the Twelve Houses astrological by Morinus (Jean-Baptiste Morin) in 1659.

He expressed millenarian views to John Evelyn, as recorded in Evelyn's diary entry for 28 August, 1655.

Works

Books

He published, among other mathematical works, Clavis Mathematicae (The Key to Mathematics), in 1631. It became a classic, reprinted in several editions, and used by Wallis and Isaac Newton amongst others. It was not ambitious in scope, but an epitome aiming to represent current knowledge of algebra concisely. It argued for a less verbose style of mathematics, with a greater dependence on symbols; drawing on François Viète (though not explicitly), Oughtred also innovated freely in symbols, introducing not only the multiplication sign as now used universally, but also the proportion sign (double colon ::).^[17] The book became popular around 15 years later, as mathematics took a greater role in higher education. Wallis wrote the introduction to his 1652 edition, and used it to publicise his skill as cryptographer;^[18] in another, Oughtred promoted the talents of Wren.

Other works were a treatise on navigation entitled Circles of Proportion, in 1632, and a book on trigonometry and dialling, and his Opuscula Mathematica, published posthumously in 1676. He invented a universal equinoctial ring dial of two rings.^[19]

• Clavis Mathematicae (1631) further Latin editions 1648, 1652, 1667, 1693; first English edition 1647
• Circles of Proportion and the Horizontal Instrument (1632); this was edited by his pupil, William Forster.^[20]
• Trigonometria with Canones sinuum (1657)

Slide rules

Oughtred's invention of the slide rule consisted of taking a single "rule", already known to Gunter, and simplifying the method used to employ it. Gunter required the use of a pair of dividers, to lay off distances on his rule; Oughtred made the step of sliding two rules past each other to achieve the same ends.^[21] His original design of some time in the 1620s was for a circular slide rule; but he was not the first into print with this idea, which was published by Delamain in 1630. The conventional design of a sliding middle section for a linear rule was an invention of the 1650s.^[22]

Sun dials

He invented the double horizontal sundial, now named Oughtred-type after him.^[23] A short description The description and use of the double Horizontall Dyall (16 pages) was added to a 1653 edition (in English translation) of the pioneer book on recreational mathematics, Récréations Mathématiques (1624) by Hendrik van Etten and Jean Leurechon. That translation itself is no longer attributed to Oughtred, but (probably) to Francis Malthus.^[24]

References

1. ^ Florian Cajori (1919). A History of Mathematics. Macmillan. http://books.google.com/books?id=bBoPAAAAIAAJ&pg=PA157&dq=inauthor:cajori+william-oughtred+multiplication. 
2. ^ Oughtred, William in Venn, J. & J. A., Alumni Cantabrigienses, Cambridge University Press, 10 vols, 1922–1958.
3. ^ http://janus.lib.cam.ac.uk/db/node.xsp?id=CV%2FPers%2FOughtred%2C%20William%20(%3F%201575-1660)%20mathematician
4. ^ http://www.dspace.cam.ac.uk/handle/1810/194216
5. ^ http://www.compilerpress.atfreeweb.com/Anno%20Johnson%20Gresham.htm
6. ^ Helena Mary Pycior, Symbols, Impossible Numbers, and Geometric Entanglements: British Algebra Through the Commentaries on Newton's Universal Arithmetick (1997), p. 42.
7. ^ Toby Christopher Barnard, Cromwellian Ireland: English Government and Reform in Ireland 1649-1660 (2000), p. 223.
8. ^ Michelle Selinger, Teaching Mathematics (1994), p. 142.
9. ^ http://galileo.rice.edu/Catalog/NewFiles/delamain.html
10. ^ http://www.british-history.ac.uk/report.aspx?compid=42932
11. ^ Keith Thomas, Religion and the Decline of Magic (1973), p. 322 and note p. 452.
12. ^ http://archimedes.mpiwg-berlin.mpg.de/cgi-bin/toc/toc.cgi?page=881;dir=hutto_dicti_078_en_1795;step=textonly
13. ^ About this time, the most famous mathematician of all Europe,[16] Mr. William Oughtred, parson of Aldbury in Surry, was in danger of sequestration by the Committee of or for plundered ministers; (_Ambo-dexters_ they were;) several inconsiderable articles were deposed and sworn against him, material enough to have sequestered him, but that, upon his day of hearing, I applied myself to Sir Bolstrode Whitlock, and all my own old friends, who in such numbers appeared in his behalf, that though the chairman and many other Presbyterian members were stiff against him, yet he was cleared by the major number. from http://www.gutenberg.org/files/15835/15835-8.txt
14. ^ http://www.clas.ufl.edu/users/rhatch/pages/03-Sci-Rev/SCI-REV-Home/resource-ref-read/major-minor-ind/westfall-dsb/08-sam-1a-thghts.htm
15. ^ Historico-Critical Inquiry into the Origins of the Rosicrucians and the Free-Masons
16. ^ E.g. William Wynn Westcott, The Rosicrucians, Past and Present, at Home and Abroad, p. 426.
17. ^ Helena Mary Pycior, Symbols, Impossible Numbers, and Geometric Entanglements: British Algebra Through the Commentaries on Newton's Universal Arithmetick (1997), p. 48.
18. ^ http://www.maths.ox.ac.uk/about/oxford-figures/ch1-6a
19. ^ http://www.nmm.ac.uk/collections/explore/index.cfm/category/90107
20. ^ Dictionary of National Biography, article on Forster.
21. ^ http://www.hpmuseum.org/sliderul.htm
22. ^ http://www.powerhousemuseum.com/collection/database/theme,805,The_slide_rule_-_a_forgotten_tool
23. ^ http://dssmhi1.fas.harvard.edu/emuseumdev/code/emuseum.asp?collection=35&collectionname=PUTNAM%20GALLERY&style=browse&currentrecord=49&page=collection&profile=objects&searchdesc=PUTNAM%20GALLERY&sessionid=6B90C135-F283-4B64-A4B0-44A78572B173&action=collection&style=single&currentrecord=54
24. ^ http://logica.ugent.be/albrecht/thesis/Etten-intro.pdf

This article incorporates text from the Encyclopædia Britannica, Eleventh Edition, a publication now in the public domain.

Further reading

• Florian Cajori (1916), William Oughtred, a great seventeenth-century teacher of mathematics online text
• Jacqueline Anne Stedall, Ariadne's Thread: The Life and Times of Oughtred's Clavis, Annals of Science, Volume 57, Issue 1 January 2000, pp. 27–60.

External links

• O'Connor, John J.; Robertson, Edmund F., "William Oughtred", MacTutor History of Mathematics archive .
• Galileo Project page
• The Oughtred Society inspired by Oughtred and dedicated to the history and preservation of slide rules.
• Answers.com article with additional material on Oughtred.
• Account of Oughtred by John Aubrey

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