Gabriel Cramer


Quick Info

Born
31 July 1704
Geneva, Switzerland
Died
4 January 1752
Bagnols-sur-Cèze, France

Summary
Gabriel Cramer worked on analysis and determinants. He is best known for his formula for solving simultaneous equations.

Biography

Gabriel Cramer's father was Jean Isaac Cramer, who was a medical doctor in Geneva, while his mother was Anne Mallet. Jean and Anne had three sons who all went on to academic success. Besides Gabriel, their other two sons were Jean-Antione who followed his father's profession and Jean who became a professor of law.

Gabriel certainly moved rapidly through his education in Geneva, and in 1722 while he was still only eighteen years old he was awarded a doctorate having submitted a thesis on the theory of sound. Two years later he was competing for the chair of philosophy at the Académie de Clavin in Geneva.

The competition for the chair was between three men; the eldest was Amédée de la Rive while the other two were both young men, Giovanni Ludovico Calandrini who was twenty-one years old and Cramer who was one year younger. The magistrates who were making the appointment favoured the older man with more experience but they were so impressed with brilliant two young men that they thought up a clever plan to enable them to acquire the services of all three. Clearly they were looking to the future and seeing in Cramer and Calandrini two men who would make important future contributions to the Academy.

The scheme the magistrates proposed was to split the chair of philosophy into two chairs, one chair of philosophy and one chair of mathematics. De la Rive was offered the philosophy chair, which after all was what he had applied for in the first place, while Cramer and Calandrini were offered the mathematics chair on the understanding that they shared the duties and shared the salary. The magistrates put another condition on the appointment too, namely that Cramer and Calandrini each spend two or three years travelling and while one was away the other would take on the full list of duties and the full salary. It was a good plan for not only did it successfully attract all three men to the Academy, but it also gave Cramer the opportunity to travel and meet mathematicians around Europe and he was to take full advantage of this which both benefited him and the Academy.

Cramer and Calandrini divided up the mathematics courses each would teach. Cramer taught geometry and mechanics while Calandrini taught algebra and astronomy. The two had been paired in the arrangement and their friends joking called them Castor and Pollux. Had their personalities been different the arrangement might have presented all sorts of difficulties, but given their natures things worked out remarkably well. Cramer is said to have been [1]:-
... friendly, good-humoured, pleasant in voice and appearance, and possessed of good memory, judgement and health.
We must not give the impression that Cramer just fitted into an existing pattern of teaching. He proposed a major innovation, which the Academy accepted, which was that he taught his courses in French instead of Latin, the traditional language of scholars at that time:-
... in order that persons who had a taste for these sciences but no Latin could profit.
Appointed in 1724, Cramer followed the conditions of his appointment and set out for two years of travelling in 1727. He visited leading mathematicians in many different cities and countries of Europe. He headed straight away for Basel where many leading mathematicians were working, spending five months working with Johann Bernoulli, and also Euler who soon afterwards headed off to St Petersburg to be with Daniel Bernoulli. Cramer then visited England where he met Halley, de Moivre, Stirling, and other mathematicians. His discussions with these mathematicians and the continuing correspondence with them after he returned to Geneva had a big influence on Cramer's work.

From England Cramer made his way to Leiden where he met 'sGravesande, then he moved on to Paris where he had discussions with Fontenelle, Maupertuis, Buffon, Clairaut, and others. These two years of travelling were to set the tone for Cramer's career for he was highly regarded by all the mathematicians he met, he corresponded with them throughout his life, and he was to perform many extremely valuable major tasks as an editor of their works.

Back in Geneva in 1729, Cramer was at work on an entry for the prize set by the Paris Academy for 1730, which was "Quelle est la cause de la figure elliptique des planètes et de la mobilité de leurs aphélies?" Cramer's entry was judged as the second best of those received by the Academy, the prize being won by Johann Bernoulli. In 1734 the "twins" split up when Calandrini was appointed to the chair of philosophy and Cramer became the sole holder of the Chair of Mathematics.

Cramer lived a busy life, for in addition to his teaching and correspondence with many mathematicians, he produced articles of considerable interest although these are not of the importance of the articles written by most of the top mathematicians with whom he corresponded. He published articles in various places including the Memoirs of the Paris Academy in 1734, and of the Berlin Academy in 1748, 1750 and 1752. The articles cover a wide range of subjects including the study of geometric problems, the history of mathematics, philosophy, and the date of Easter. He published an article on the aurora borealis in the Philosophical Transactions of the Royal Society of London and he also wrote an article on law where he applied probability to demonstrate the significance of having independent testimony from two or three witnesses rather than from a single witness.

His work was not confined to academic areas for he was also interested in local government and served as a member of the Council of Two Hundred in 1734 and of the Council of Seventy in 1749. His work on these councils involved him using his broad mathematical and scientific knowledge, for he undertook tasks involving artillery, fortification, reconstruction of buildings, excavations, and he acted as an archivist. He made a second trip abroad in 1747, this time only visiting Paris where he renewed his friendship with Fontenelle as well as meeting d'Alembert.

There are two areas of Cramer's mathematical work which we should highlight. This is the editorial work which he undertook and also his major mathematical work Introduction à l'analyse des lignes courbes algébriques published in 1750.

Johann Bernoulli died in 1748, only three or so years before Cramer, but he arranged for Cramer to publish his Complete Works before his death. It shows how much respect Bernoulli had for Cramer that he insisted that no other edition of his works be published by any editor other than Cramer. Johann Bernoulli's Complete Works was published by Cramer in four volumes in 1742. Not only did Johann Bernoulli arrange for Cramer to publish his Complete Works but he also requested that he edit Jacob Bernoulli's works. Jacob Bernoulli had died 1705 and Cramer published his Works in two volumes in 1744. These are not complete since Ars conjectandi is omitted (this had been published by Nicolaus Bernoulli in 1713), but the volumes do contain previously unpublished material and the mathematical background necessary to understand them. In 1745, jointly with Johann Castillon, Cramer published the correspondence between Johann Bernoulli and Leibniz. Cramer also edited the five volume work by Christian Wolff, first published between 1732 and 1741 with a new edition appearing between 1743 and 1752.

Finally we should describe Cramer's most famous book Introduction à l'analyse des lignes courbes algébraique . It is a work which Cramer modelled on Newton's memoir on cubic curves and he praises highly a commentary on Newton's memoir written by Stirling. He also comments that had he known of Euler's Introductio in analysin infinitorum earlier he would have made great use of it. Of course Euler's book was only published in 1748 at which time much of Cramer's book might well have been written. Jones writes in [1]:-
That he made little use of Euler's work is supported by the rather surprising fact that throughout his book Cramer makes essentially no use of the infinitesimal calculus in either Leibniz's or Newton's form, although he deals with such topics as tangents, maxima and minima, and curvature, and cites Maclaurin and Taylor in footnotes. One conjectures that he never accepted or mastered the calculus.
The suggestion that Cramer never mastered the calculus must be considered doubtful, particularly given the high regard that he was held in by Johann Bernoulli.

After an introductory chapter in which types of curves are defined and techniques for drawing their graphs are discussed, Cramer goes on to a second chapter in which transformations to simplify curves are studied. The third chapter looks at a classification of curves and it is in this chapter that the now famous "Cramer's rule" is given. After giving the number of arbitrary constants in an equation of degree nn as 12n2+32n\large\frac{1}{2}\normalsize n^{2} + \large\frac{3}{2}\normalsize n, he deduces that an equation of degree nn can be made to pass through nn points. Taking n=5n = 5 he gives an example of finding the five constants involved in making an equation of degree 2 pass through 5 points. This leads to 5 linear equations in 5 unknowns and he refers the reader to an appendix containing Cramer's rule for their solution. We should remark, of course, that Cramer was certainly not the first to give this rule.

The other "well known" part of Cramer's work is his description of Cramer's paradox. He states a theorem by Maclaurin which says that an equation of degree nn intersects an equation of degree mm in nmnm points. Taking n=m=3n = m = 3 this says that two cubics intersect in 9 points, yet his own formula 12n2+32n\large\frac{1}{2}\normalsize n^{2} + \large\frac{3}{2}\normalsize n with n=3n = 3 gives 9 so a cubic is uniquely determined by 9 points. This, says Cramer, is a paradox, but his attempt to explain the paradox is incorrect.

Cramer's name has sometimes been attached to another problem, namely the Castillon-Cramer problem. This problem, proposed by Cramer to Castillon, asked how to inscribe a triangle in a circle so that it passed through three given points. Castillon solved the problem 25 years after Cramer's death, and the problem went on to various generalisations about inscribed polygons in a conic section.

Cramer had worked extremely hard over a long period with writing his Introduction à l'analyse and undertaking the large amount of editorial work in addition to all his normal duties. Always of good health, this overwork coupled with a fall from his carriage, brought on a sudden decline. He spent two months in bed recovering, and his doctor then recommended that he spend a quiet period in the south of France to completely regain his strength. Leaving Geneva on 21 December 1751 he began his journey but he died two weeks later while still on the journey.


References (show)

  1. P S Jones, G Kerstein, Biography in Dictionary of Scientific Biography (New York 1970-1990). See THIS LINK.
  2. N I Danilova, Problems of Cramer and L'Huilier in the works of Jacob Steiner (Russian), in Questions on the history of mathematical natural science (Kiev, 1979), 125-135.
  3. P Speziali, Gabriel Cramer (1704-1752) et ses correspondants, Conférences du Palais de la Découverte 59 (Paris, 1959).
  4. P Speziali, Une correspondance inédite entre Clairaut et Cramer, Rev. Hist. Sci. Appl. 8 (1955), 193-237.

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Written by J J O'Connor and E F Robertson
Last Update May 2000