**Arthur Cayley** (August 16, 1821 - January 26, 1895) was a British mathematician. He helped found the modern British school of pure mathematics. This image has been released into the public domain by the copyright holder, its copyright has expired, or it is ineligible for copyright. ...
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Year 1821 (MDCCCXXI) was a common year starting on Monday (link will display the full calendar) of the Gregorian Calendar (or a common year starting on Saturday of the 12-day slower Julian calendar). ...
Richmond is a suburb and the principal settlement of the London Borough of Richmond upon Thames in south west London, England. ...
This article is about the English county. ...
is the 26th day of the year in the Gregorian calendar. ...
Year 1895 (MDCCCXCV) was a common year starting on Tuesday (link will display full calendar) of the Gregorian calendar (or a common year starting on Sunday of the 12-day-slower Julian calendar). ...
This article is about the city in England. ...
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Leonhard Euler, considered one of the greatest mathematicians of all time A mathematician is a person whose primary area of study and research is the field of mathematics. ...
The University of Cambridge is the second-oldest university in the English-speaking world, with one of the most selective sets of entry requirements in the United Kingdom. ...
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The University of Cambridge is the second-oldest university in the English-speaking world, with one of the most selective sets of entry requirements in the United Kingdom. ...
George Peacock George Peacock (April 9, 1791 â€“ November 8, 1858) was an English mathematician. ...
William Hopkins (February 2, 1793 â€“ October 13, 1866) was an English mathematician and geologist. ...
Henry Frederick Baker (July 3, 1866 - March 17, 1956) was a British mathematician, working mainly in algebraic geometry, but also remembered for contributions to partial differential equations (related to what would become known as solitons), and Lie groups. ...
Andrew Forsyth was a Scottish mathematician and was Professor Emeritus at the Imperial College of Science. ...
Charlotte Angas Scott D.Sc. ...
Projective geometry is a non-metrical form of geometry. ...
Group theory is that branch of mathematics concerned with the study of groups. ...
The Copley Medal is a scientific award for work in any field of science, the highest award granted by the Royal Society of London. ...
is the 228th day of the year (229th in leap years) in the Gregorian calendar. ...
Year 1821 (MDCCCXXI) was a common year starting on Monday (link will display the full calendar) of the Gregorian Calendar (or a common year starting on Saturday of the 12-day slower Julian calendar). ...
is the 26th day of the year in the Gregorian calendar. ...
Year 1895 (MDCCCXCV) was a common year starting on Tuesday (link will display full calendar) of the Gregorian calendar (or a common year starting on Sunday of the 12-day-slower Julian calendar). ...
Leonhard Euler, considered one of the greatest mathematicians of all time A mathematician is a person whose primary area of study and research is the field of mathematics. ...
Broadly speaking, pure mathematics is mathematics motivated entirely for reasons other than application. ...
As a child, Cayley enjoyed solving complex math problems for amusement. At eighteen, he entered Trinity College, Cambridge, where he excelled in Greek, French, German, and Italian, as well as mathematics. He worked as a lawyer for 14 years. Full name The College of the Holy and Undivided Trinity Motto Virtus vera nobilitas Virtue is true Nobility Named after The Holy Trinity Previous names Kingâ€™s Hall and Michaelhouse (until merged in 1546) Established 1546 Sister College(s) Christ Church Master The Lord Rees of Ludlow Location Trinity Street...
For other meanings of mathematics or uses of math and maths, see Mathematics (disambiguation) and Math (disambiguation). ...
For the fish called lawyer, see Burbot. ...
He was consequently able to prove the Cayley-Hamilton theorem -- that every square matrix is a root of its own characteristic polynomial. He was the first to define the concept of a group in the modern way -- as a set with a binary operation satisfying certain laws. Formerly, when mathematicians spoke of "groups", they had meant permutation groups. In linear algebra, the Cayley-Hamilton theorem (named after the mathematicians Arthur Cayley and William Hamilton) states that every square matrix over the real or complex field, satisfies its own characteristic equation. ...
This picture illustrates how the hours on a clock form a group under modular addition. ...
In mathematics, a permutation group is a group G whose elements are permutations of a given set M, and whose operation is the composition of permutations in G (which are thought of as bijective functions from the set M to itself); the relationship is often written as (G,M). ...
See also Cayley's theorem. In group theory, Cayleys theorem, named in honor of Arthur Cayley, states that every group G is isomorphic to a subgroup of the symmetric group on G. This can be understood as an example of the group action of G on the elements of G. A permutation of a...
## Early years
Arthur Cayley was born in Richmond, London, England, on August 16 1821. His father, Henry Cayley, was a distant cousin of Sir George Cayley the aeronautics innovator, and descended from an ancient Yorkshire family. He settled in St. Petersburg, Russia, as a merchant. His mother was Maria Antonia Doughty, daughter of William Doughty. According to some writers she was Russian, but her father's name indicates an English origin. His brother was the linguist Charles Bagot Cayley. Arthur spent his first eight years in St. Petersburg. In 1829 his parents settled permanently at Blackheath, near London. Arthur was sent to a private school. He early showed great liking for, and aptitude in, numerical calculation. At age 14 he was sent to King's College School. The school's master observed indications of mathematical genius and advised the father to educate his son not for his own business, as he had intended, but to enter the University of Cambridge. Richmond is a suburb and the principal settlement of the London Borough of Richmond upon Thames in south west London, England. ...
For other uses, see England (disambiguation). ...
Sir George Cayley, 6th Baronet (December 27, 1773 â€“ December 15, 1857) was a prolific English engineer from Brompton-by-Sawdon, near Scarborough in Yorkshire. ...
Six F-16 Fighting Falcons with the U.S. Air Force Thunderbirds aerial demonstration team fly in delta formation in front of the Empire State Building. ...
Yorkshire is a historic county of northern England. ...
Saint Petersburg (Russian: Санкт-Петербу́рг, English transliteration: Sankt-Peterburg), colloquially known as Питер (transliterated Piter), formerly known as Leningrad (Ленингра́д, 1924–1991) and...
Merchants function as professionals who deal with trade, dealing in commodities that they do not produce themselves, in order to produce profit. ...
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William Doughty was a United States naval architect who designed many of the sailing 74s. ...
Charles Bagot Cayley (1823 - 1883) was a linguist best known for translating Dante into the metre of the original, with annotations, besides metrical versions of the Iliad, the Prometheus of Ã†schylus, the Canzoniere of Petrarch. ...
Johann Wolfgang von Goethe 1829 was a common year starting on Thursday (see link for calendar). ...
Blackheath is a suburb of London, divided between the London Borough of Lewisham and the London Borough of Greenwich. ...
Kings College School Wimbledon, or KCS, is an independent boys school in Wimbledon, south-west London. ...
The University of Cambridge (often Cambridge University), located in Cambridge, England, is the second-oldest university in the English-speaking world and has a reputation as one of the worlds most prestigious universities. ...
## Education At the unusually early age of 17 Cayley began residence at Trinity College, Cambridge. The cause of the Analytical Society had now triumphed, and the *Cambridge Mathematical Journal* had been instituted by Gregory and Leslie Ellis. To this journal, at the age of twenty, Cayley contributed three papers, on subjects which had been suggested by reading the *Mécanique analytique* of Lagrange and some of the works of Laplace. Full name The College of the Holy and Undivided Trinity Motto Virtus vera nobilitas Virtue is true Nobility Named after The Holy Trinity Previous names Kingâ€™s Hall and Michaelhouse (until merged in 1546) Established 1546 Sister College(s) Christ Church Master The Lord Rees of Ludlow Location Trinity Street...
The Analytical Society was a group of individuals in early-19th century Britain whose aim was to promote the use of Leibnizian or analytical calculus as opposed to Newtonian calculus. ...
Joseph-Louis, comte de Lagrange (January 25, 1736 Turin, Kingdom of Sardinia - April 10, 1813 Paris) was an Italian-French mathematician and astronomer who made important contributions to all fields of analysis and number theory and to classical and celestial mechanics as arguably the greatest mathematician of the 18th century. ...
Pierre-Simon Laplace Pierre-Simon Laplace (March 23, 1749 – March 5, 1827) was a French mathematician and astronomer, the discoverer of the Laplace transform and Laplaces equation. ...
Cayley finished his undergraduate course by winning the place of Senior Wrangler, and the first Smith's prize. His next step was to take the M.A. degree, and win a Fellowship by competitive examination. His tutor at Cambridge was George Peacock and his private coach was William Hopkins. He continued to reside at Cambridge for four years; during which time he took some pupils, but his main work was the preparation of 28 memoirs to the *Mathematical Journal*. At the University of Cambridge in England, a wrangler is a student who has completed the third year (called Part II) of the mathematical tripos with first-class honours. ...
The Smiths Prize is a prize awarded to research students in theoretical Physics, mathematics and applied mathematics at the University of Cambridge, Cambridge, England. ...
George Peacock George Peacock (April 9, 1791 â€“ November 8, 1858) was an English mathematician. ...
William Hopkins (February 2, 1793 â€“ October 13, 1866) was an English mathematician and geologist. ...
## As a lawyer Because of the limited tenure of his fellowship it was necessary to choose a profession; like De Morgan, Cayley chose law, and at age 25 entered at Lincoln's Inn, London. He made a specialty of conveyancing. It was while he was a pupil at the bar examination that he went to Dublin to hear Hamilton's lectures on quaternions. The tone or style of this article or section may not be appropriate for Wikipedia. ...
Lincolns Inn is one of four Inns of Court in London to which barristers of England and Wales belong and where they are called to the Bar. ...
Conveyancing is the act of transferring the legal title in a property from one person to another. ...
A bar examination is an examination to determine whether a candidate is qualified to practice law in a given jurisdiction. ...
For other uses, see Dublin (disambiguation). ...
For other persons named William Hamilton, see William Hamilton (disambiguation). ...
In mathematics, the quaternions are a non-commutative extension of the complex numbers. ...
His friend Sylvester, his senior by five years at Cambridge, was then an actuary, resident in London; they used to walk together round the courts of Lincoln's Inn, discussing the theory of invariants and covariants. During this period of his life, extending over fourteen years, Cayley produced between two and three hundred papers. James Joseph Sylvester James Joseph Sylvester (September 3, 1814 London - March 15, 1897 Oxford) was an English mathematician. ...
Damage from Hurricane Katrina. ...
In mathematics, invariant theory refers to the study of invariant algebraic forms (equivalently, symmetric tensors) for the action of linear transformations. ...
## As professor At Cambridge University the ancient professorship of pure mathematics is denominated the Lucasian, and is the chair which had been occupied by Isaac Newton. Around 1860, certain funds bequeathed by Lady Sadleir to the University, having become useless for their original purpose, were employed to establish another professorship of pure mathematics, called the Sadlerian. The duties of the new professor were defined to be *"to explain and teach the principles of pure mathematics and to apply himself to the advancement of that science."* To this chair Cayley was elected when 42 years old. He gave up a lucrative practice for a modest salary; but he never regretted the exchange, for the chair at Cambridge enabled him to end the divided allegiance between law and mathematics, and to devote his energies to the pursuit which he liked best. He at once married and settled down in Cambridge. More fortunate than Hamilton in his choice, his home life was one of great happiness. His friend and fellow investigator, Sylvester, once remarked that Cayley had been much more fortunate than himself; that they both lived as bachelors in London, but that Cayley had married and settled down to a quiet and peaceful life at Cambridge; whereas he had never married, and had been fighting the world all his days. The incumbent of the Lucasian Chair of Mathematics, the Lucasian Professor is the holder of a mathematical professorship at Cambridge University. ...
Sir Isaac Newton FRS (4 January 1643 â€“ 31 March 1727) [ OS: 25 December 1642 â€“ 20 March 1727][1] was an English physicist, mathematician, astronomer, natural philosopher, and alchemist. ...
The Sadleirian Chair is a Professorship in pure mathematics at Cambridge University. ...
At first the teaching duty of the Sadlerian professorship was limited to a course of lectures extending over one of the terms of the academic year; but when the University was reformed about 1886, and part of the college funds applied to the better endowment of the University professors, the lectures were extended over two terms. For many years the attendance was small, and came almost entirely from those who had finished their career of preparation for competitive examinations; after the reform the attendance numbered about fifteen. The subject lectured on was generally that of the memoir on which the professor was for the time engaged. The other duty of the chair - the advancement of mathematical science - was discharged in a handsome manner by the long series of memoirs which he published, ranging over every department of pure mathematics. But it was also discharged in a much less obtrusive way; he became the standing referee on the merits of mathematical papers to many societies both at home and abroad. In 1876 he published a *Treatise on Elliptic Functions*, which was his only book. He took great interest in the movement for the University education of women. At Cambridge the women's colleges are Girton and Newnham. In the early days of Girton College he gave direct help in teaching, and for some years he was chairman of the council of Newnham College, in the progress of which he took the keenest interest to the last. In complex analysis, an elliptic function is, roughly speaking, a function defined on the complex plane which is periodic in two directions. ...
Full name Girton College Motto - Named after Girton Village Previous names The College for Women (1869), Girton College (1872) Established 1869 Sister College Somerville College Mistress Dame Marylin Strathern Location Huntingdon Road Undergraduates 503 Graduates 201 Homepage Boatclub Girton College lies on the extremity of Cambridge Girton College was established...
Full name Newnham College Motto - Named after - Previous names Newnham Hall Established 1871 Sister College St Cross College Principal The Lady ONeill of Bengarve Location Sidgwick Avenue Undergraduates 396 Graduates 120 Homepage Boatclub A view of part of Newnham College. ...
In 1872 he was made an honorary fellow of Trinity College, and three years later an ordinary fellow, which meant stipend as well as honor. About this time his friends subscribed for a presentation portrait. Maxwell wrote an address to the committee of subscribers who had charge of the Cayley portrait fund. The verses refer to the subjects investigated in several of Cayley's most elaborate memoirs; such as, Chapters on the Analytical Geometry of *n* dimensions; On the theory of Determinants; Memoir on the theory of Matrices; Memoirs on skew surfaces, otherwise Scrolls; On the delineation of a Cubic Scroll, etc. James Clerk Maxwell (13 June 1831 â€“ 5 November 1879) was a Scottish mathematician and theoretical physicist. ...
In algebra, a determinant is a function depending on n that associates a scalar, det(A), to every nÃ—n square matrix A. The fundamental geometric meaning of a determinant is as the scale factor for volume when A is regarded as a linear transformation. ...
In 1881 he received from the Johns Hopkins University, Baltimore, where Sylvester was then professor of mathematics, an invitation to deliver a course of lectures. He accepted the invitation, and lectured at Baltimore during the first five months of 1882 on the subject of the *Abelian and Theta Functions*.
## BMA
| **This article or section may contain an unpublished synthesis of published material that conveys ideas not attributable to the original sources.** Please help Wikipedia by adding sources whose main topic is "Arthur Cayley". See the talk page for details.(October 2007) | The next year Cayley came prominently before the world, as President of the British Association for the Advancement of Science. The meeting was held at Southport, in the north of England. As the President's address is one of the great popular events of the meeting, and brings out an audience of general culture, it is usually made as little technical as possible. Hamilton was the kind of mathematician to suit such an occasion, but he never got the office, on account of his occasional breaks. Cayley had not the oratorical, the philosophical, or the poetical gifts of Hamilton, but then he was an eminently safe man. He took for his subject the Progress of Pure Mathematics; and he opened his address in the following naive manner: Image File history File links Ambox_emblem_question. ...
- I wish to speak to you to-night upon Mathematics. I am quite aware of the difficulty arising from the abstract nature of my subject; and if, as I fear, many or some of you, recalling the providential addresses at former meetings, should wish that you were now about to have from a different President a discourse on a different subject, I can very well sympathize with you in the feeling. But be that as it may, I think it is more respectful to you that I should speak to you upon and do my best to interest you in the subject which has occupied me, and in which I am myself most interested. And in another point of view, I think it is right that the address of a president should be on his own subject, and that different subjects should be thus brought in turn before the meetings. So much the worse, it may be, for a particular meeting: but the meeting is the individual, which on evolution principles, must be sacrificed for the development of the race.
I daresay that after this introduction, all the evolution philosophers listened to him attentively, whether they understood him or not. But Cayley doubtless felt that he was addressing not only the popular audience then and there before him, but the mathematicians of distant places and future times; for the address is a valuable historical review of various mathematical theories, and is characterized by freshness, independence of view, suggestiveness, and learning.*(OPINION)*
## The *Collected Papers* In 1889 the Cambridge University Press requested him to prepare his mathematical papers for publication in a collected form--a request which he appreciated very much. They are printed in magnificent quarto volumes, of which seven appeared under his own editorship. While editing these volumes, he was suffering from a painful internal malady, to which he succumbed on January 26, 1895, in the 74th year of his age. When the funeral took place, a great assemblage met in Trinity Chapel, comprising members of the University, official representatives of Russia and America, and many of the most illustrious philosophers of Britain. The remainder of his papers were edited by Prof. Forsyth, his successor in the Sadlerian chair. The Collected Mathematical papers number thirteen quarto volumes, and contain 967 papers. His writings are his best monument, and certainly no mathematician has ever had his monument in grander style. De Morgan's works would be more extensive, and much more useful, but he did not have behind him a University Press. As regards fads, Cayley retained to the last his fondness for novel-reading and for travelling. He also took special pleasure in paintings and architecture, and he practiced water-color painting, which he found useful sometimes in making mathematical diagrams.
## Quaternions To the third edition of P. G. Tait's *Elementary Treatise on Quaternions*, Cayley contributed a chapter entitled "Sketch of the analytical theory of quaternions." In it the √−1 reappears in all its glory, and in entire, so it is said, independence of *i*, *j*, *k*. Peter Tait Peter Guthrie Tait (April 28, 1831 - July 4, 1901) was a Scottish physicist. ...
In mathematics, the quaternions are a non-commutative extension of the complex numbers. ...
In 1894 there arose a brisk discussion between Tait and Cayley on "Coordinates versus Quaternions," the record of which is printed in the Proceedings of the Royal Society of Edinburgh. Cayley maintained the position that while coordinates are applicable to the whole science of geometry and are the natural and appropriate basis and method in the science, quaternions seemed a particular and very artificial method for treating such parts of the science of three-dimensional geometry as are most naturally discussed by means of the rectangular coordinates *x*, *y*, *z*. In the course of his paper Cayley says: The Royal Society of Edinburghs Building on the corner of George St. ...
- I have the highest admiration for the notion of a quaternion; but, as I consider the full moon far more beautiful than any moonlit view, so I regard the notion of a quaternion as far more beautiful than any of its applications. As another illustration, I compare a quaternion formula to a pocket-map—a capital thing to put in one's pocket, but which for use must be unfolded: the formula, to be understood, must be translated into coordinates.
He goes on to say, - I remark that the imaginary of ordinary algebra—for distinction call this θ—has no relation whatever to the quaternion symbols
*i*, *j*, *k*; in fact, in the general point of view, all the quantities which present themselves, are, or may be, complex values *a* + θ*b*, or in other words, say that a scalar quantity is in general of the form *a* + θ*b*. Thus quaternions do not properly present themselves in plane or two-dimensional geometry at all; but they belong essentially to solid or three-dimensional geometry, and they are most naturally applicable to the class of problems which in coordinates are dealt with by means of the three rectangular coordinates *x*, *y*, *z*. To the pocketbook illustration it may be replied that a set of coordinates is an immense wall map, which you cannot carry about, even though you should roll it up, and therefore is useless for many important purposes. In reply to the arguments, it may be said, *first*, √−1 has a relation to the symbols *i*, *j*, *k* for each of these can be analyzed into a unit axis multiplied by √−1; *second*, as regards plane geometry, the ordinary form of complex quantity is a degraded form of the quaternion in which the constant axis of the plane is left unspecified. Cayley took his illustrations from his experience as a traveller. Tait brought forward an illustration from which you might imagine he had visited the Bethlehem Iron Works, and hunted tigers in India. He says, In mathematics, plane geometry may mean: geometry of the Euclidean plane; or sometimes geometry of a projective plane, most commonly the real projective plane but possibly the complex projective plane, Fano plane or others; or geometry of the hyperbolic plane or two-dimensional spherical geometry. ...
- A much more natural and adequate comparison would, it seems to me, liken Coordinate Geometry to a steam-hammer, which an expert may employ on any destructive or constructive work of one general kind, say the cracking of an eggshell, or the welding of an anchor. But you must have your expert to manage it, for without him it is useless. He has to toil amid the heat, smoke, grime, grease, and perpetual din of the suffocating engine-room. The work has to be brought to the hammer, for it cannot usually be taken to its work. And it is not in general, transferable; for each expert, as a rule, knows, fully and confidently, the working details of his own weapon only. Quaternions, on the other hand, are like the elephant's trunk, ready at
*any* moment for *anything*, be it to pick up a crumb or a field-gun, to strangle a tiger, or uproot a tree; portable in the extreme, applicable anywhere—like in the trackless jungle and in the barrack square—directed by a little native who requires no special skill or training, and who can be transferred from one elephant to another without much hesitation. Surely this, which adapts itself to its work, is the grander instrument. But then, *it* is the natural, the other, the artificial one. The reply which Tait makes, so far as it is an argument, is: There are two systems of quaternions, the *i*, *j*, *k* one, and another one which Hamilton developed from it; Cayley knows the first only, he himself knows the second; the former is an intensely artificial system of imaginaries, the latter is the natural organ of expression for quantities in space. Should a fourth edition of his *Elementary Treatise* be called for *i*, *j*, *k* will disappear from it, excepting in Cayley's chapter, should it be retained. Tait thus describes the first system: - Hamilton's extraordinary
*Preface* to his first great book shows how from Double Algebras, through Triplets, Triads, and Sets, he finally reached Quaternions. This was the genesis of the Quaternions of the forties, and the creature thus produced is still essentially the Quaternion of Prof. Cayley. It is a magnificent analytical conception; but it is nothing more than the full development of the system of imaginaries *i*, *j*, *k*; defined by the equations, *i*² = *j*² = *k*² = *ijk* = −1 with the associative, but *not* the commutative, law for the factors. The novel and splendid points in it were the treatment of all directions in space as essentially alike in character, and the recognition of the unit vector's claim to rank also as a quadrantal versor. These were indeed inventions of the first magnitude, and of vast importance. And here I thoroughly agree with Prof. Cayley in his admiration. Considered as an analytical system, based throughout on pure imaginaries, the Quaternion method is elegant in the extreme. But, unless it had been also something more, something very different and much higher in the scale of development, I should have been content to admire it;—and to pass it by. From "the most intensely artificial of systems, arose, as if by magic, an absolutely natural one" which Tait thus further describes. "To me Quaternions are primarily a Mode of Representation:—immensely superior to, but of essentially the same kind of usefulness as, a diagram or a model. They are, virtually, the thing represented; and are thus antecedent to, and independent of, coordinates; giving, in general, all the main relations, in the problem to which they are applied, without the necessity of appealing to coordinates at all. Coordinates may, however, easily be read into them:—when anything (such as metrical or numerical detail) is to be gained thereby. Quaternions, in a word, exist in space, and we have only to recognize them:—but we have to invent or imagine coordinates of all kinds." To meet the objection why Hamilton did not throw *i*, *j*, *k* overboard, and expound the developed system, Tait says: - Most unfortunately, alike for himself and for his grand conception, Hamilton's nerve failed him in the composition of his first great volume. Had he then renounced, for ever, all dealings with
*i*, *j*, *k*, his triumph would have been complete. He spared Agog, and the best of the sheep, and did not utterly destroy them. He had a paternal fondness for *i*, *j*, *k*; perhaps also a not unnatural liking for a meretricious title such as the mysterious word *Quaternion*; and, above all, he had an earnest desire to make the utmost return in his power for the liberality shown him by the authorities of Trinity College, Dublin. He had fully recognized, and proved to others, that his *i*, *j*, *k*, were mere excrescences and blots on his improved method:---but he unfortunately considered that their continued (if only partial) recognition was indispensable to the reception of his method by a world steeped in—Cartesianism! Through the whole compass of each of his tremendous volumes one can find traces of his desire to avoid even an allusion to *i*, *j*, *k*, and along with them, his sorrowful conviction that, should he do so, he would be left without a single reader. ## Philosophy To Cayley's presidential address we are indebted for information about the view which he took of the foundations of exact science, and the philosophy which commended itself to his mind. He quoted Plato and Kant with approval, J. S. Mill with faint praise. Although he threw a sop to the empirical philosophers at the beginning of his address, he gave them something to think of before he finished. For other uses, see Plato (disambiguation). ...
Kant redirects here. ...
John Stuart Mill (20 May 1806 â€“ 8 May 1873), British philosopher, political economist, civil servant and Member of Parliament, was an influential liberal thinker of the 19th century. ...
He first of all remarks that the connection of arithmetic and algebra with the notion of time is far less obvious than that of geometry with the notion of space; in which he, of course, made a hit at Hamilton's theory of Algebra as the science of pure time. Further on he discusses the theory directly, and concludes as follows: - Hamilton uses the term algebra in a very wide sense, but whatever else he includes under it, he includes all that in contradistinction to the Differential Calculus would be called algebra. Using the word in this restricted sense, I cannot myself recognize the connection of algebra with the notion of time; granting that the notion of continuous progression presents itself and is of importance, I do not see that it is in anywise the fundamental notion of the science. And still less can I appreciate the manner in which the author connects with the notion of time his algebraic couple, or imaginary magnitude,
*a* + *b*√−1. So you will observe that doctors differ—Tait and Cayley—about the soundness of Hamilton's theory of couples. But it can be shown that a couple may not only be represented on a straight line, but actually means a portion of a straight line; and as a line is unidimensional, this favors the truth of Hamilton's theory. Differential calculus is the theory of and computations with differentials; see also derivative and calculus. ...
As to the nature of mathematical science Cayley quoted with approval from an address of Hamilton's: - These purely mathematical sciences of algebra and geometry are sciences of the pure reason, deriving no weight and no assistance from experiment, and isolated or at least isolable from all outward and accidental phenomena. The idea of order with its subordinate ideas of number and figure, we must not call innate ideas, if that phrase be defined to imply that all men must possess them with equal clearness and fulness; they are, however, ideas which seem to be so far born with us that the possession of them in any conceivable degree is only the development of our original powers, the unfolding of our proper humanity.
It is the aim of the evolution philosopher to reduce all knowledge to the empirical status; the only intuition he grants is a kind of instinct formed by the experience of ancestors and transmitted cumulatively by heredity. Cayley first takes him up on the subject of arithmetic: - Whatever difficulty be raisable as to geometry, it seems to me that no similar difficulty applies to arithmetic; mathematician, or not, we have each of us, in its most abstract form, the idea of number; we can each of us appreciate the truth of a proposition in numbers; and we cannot but see that a truth in regard to numbers is something different in kind from an experimental truth generalized from experience. Compare, for instance, the proposition, that the sun, having already risen so many times, will rise to-morrow, and the next day, and the day after that, and so on; and the proposition that even and odd numbers succeed each other alternately
*ad infinitum*; the latter at least seems to have the characters of universality and necessity. Or again, suppose a proposition observed to hold good for a long series of numbers, one thousand numbers, two thousand numbers, as the case may be: this is not only no proof, but it is absolutely no evidence, that the proposition is a true proposition, holding good for all numbers whatever; there are in the Theory of Numbers very remarkable instances of propositions observed to hold good for very long series of numbers which are nevertheless untrue. Then he takes him up on the subject of geometry, where the empiricist rather boasts of his success. - It is well known that Euclid's fifth axiom, even in Playfair's form of it, has been considered as needing demonstration; and that Lobatschewsky constructed a perfectly consistent theory, wherein this axiom was assumed not to hold good, or say a system of non-Euclidean plane geometry. My own view is that Euclid's fifth axiom in Playfair's form of it does not need demonstration, but is part of our notion of space, of the physical space of our experience---the space, that is, which we become acquainted with by experience, but which is the representation lying at the foundation of all external experience. Riemann's view before referred to may I think be said to be that, having
*in intellectu* a more general notion of space (in fact a notion of non-Euclidean space), we learn by experience that space (the physical space of our experience) is, if not exactly, at least to the highest degree of approximation, Euclidean space. But suppose the physical space of our experience to be thus only approximately Euclidean space, what is the consequence which follows? *Not* that the propositions of geometry are only approximately true, but that they remain absolutely true in regard to that Euclidean space which has been so long regarded as being the physical space of our experience. In his address he remarks that the fundamental notion which underlies and pervades the whole of modern analysis and geometry is that of imaginary magnitude in analysis and of imaginary space (or space as a *locus in quo* of imaginary points and figures) in geometry. In the case of two given curves there are two equations satisfied by the coordinates (*x*, *y*) of the several points of intersection, and these give rise to an equation of a certain order for the coordinate *x* or *y* of a point of intersection. In the case of a straight line and a circle this is a quadratic equation; it has two roots real or imaginary. There are thus two values, say of *x*, and to each of these corresponds a single value of *y*. There are therefore two points of intersection, viz., a straight line and a circle intersect always in two points, real or imaginary. It is in this way we are led analytically to the notion of imaginary points in geometry. He asks, What is an imaginary point? Is there in a plane a point the coordinates of which have given imaginary values? He seems to say No, and to fall back on the notion of an imaginary space as the *locus in quo* of the imaginary point. a and b are parallel, the transversal t produces congruent angles. ...
Professor John Playfair FRSE (March 10, 1748 â€“ July 20, 1819) was a Scottish scientist. ...
Nikolay Ivanovich Lobachevsky Nikolai Ivanovich Lobachevsky (ÐÐ¸ÐºÐ¾Ð»Ð°ÌÐ¹ Ð˜Ð²Ð°ÌÐ½Ð¾Ð²Ð¸Ñ‡ Ð›Ð¾Ð±Ð°Ñ‡ÐµÌÐ²ÑÐºÐ¸Ð¹) (December 1, 1792â€“February 24, 1856 (N.S.); November 20, 1792â€“February 12, 1856 (O.S.)) was a Russian mathematician. ...
Behavior of lines with a common perpendicular in each of the three types of geometry The term non-Euclidean geometry describes hyperbolic, elliptic and absolute geometry, which are contrasted with Euclidean geometry. ...
## List of notions named for Arthur Cayley In group theory, Cayleys theorem, named in honor of Arthur Cayley, states that every group G is isomorphic to a subgroup of the symmetric group on G. This can be understood as an example of the group action of G on the elements of G. A permutation of a...
In linear algebra, the Cayley-Hamilton theorem (named after the mathematicians Arthur Cayley and William Hamilton) states that every square matrix over the real or complex field, satisfies its own characteristic equation. ...
Linear algebra is the branch of mathematics concerned with the study of vectors, vector spaces (also called linear spaces), linear maps (also called linear transformations), and systems of linear equations. ...
Grassmann-Cayley algebra is a form of modelling algebra for projective geometry, based on work by German mathematician Hermann Grassmann on exterior algebra, and, subsequently, by British mathematician Arthur Cayleys work on matrices and linear algebra. ...
Distance geometry is the characterization and study of sets of points based only on given values of the distances between member pairs. ...
In mathematics, the Cayley-Dickson construction produces a sequence of algebras over the field of real numbers, each with twice the dimension of the previous one. ...
In mathematics, the octonions are a nonassociative extension of the quaternions. ...
The Cayley graph of the free group on two generators a and b In mathematics, a Cayley graph, named after Arthur Cayley, is a graph that encodes the structure of a group. ...
A Cayley table, after the 19th century British mathematician Arthur Cayley, describes the structure of a finite group by arranging all the possible products of all the groups elements in a square table reminiscent of an addition or multiplication table. ...
The Cayley-Purser algorithm was published in early 1999 by Irishwoman Sarah Flannery, who was sixteen years old at the time. ...
In mathematics, Cayleys formula is a result in graph theory. ...
In geometry, the Klein model, also called the projective model, the Beltrami-Klein model, the Klein-Beltrami model and the Cayley-Klein model, is a model of n-dimensional hyperbolic geometry in which the points of the geometry are in an n-dimensional disk, or ball, and the lines of...
Lines through a given point P and asymptotic to line l. ...
Cayley transform maps upper half plane to open unit disk In complex analysis, the Cayley transform is the map The Cayley transform is a linear fractional transformation. ...
## Also named after Arthur Cayley Cayley is a small lunar impact crater that is located in a basaltic-lava-flooded region to the west of Mare Tranquillitatis. ...
This article is about Earths moon. ...
The University of Waterloo (also referred to as UW, UWaterloo, or Waterloo) is a research-intensive public university in the city of Waterloo, Ontario, Canada. ...
## Works by Arthur Cayley *An element treatise on elliptic functions* (Cambridge : Deighton : Bell, 1876) *The collected mathematical papers of Arthur Cayley (Volume 1)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 2)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 3)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 4)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 5)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 6)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 7)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 8)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 9)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 10)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 11)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 12)* (Cambridge, University Press, 1889-1897) *The collected mathematical papers of Arthur Cayley (Volume 13)* (Cambridge, University Press, 1889-1897) ## Bibliography Primary: - 1883. "Presidential address to the British Association" in Ewald, William B., ed., 1996.
*From Kant to Hilbert: A Source Book in the Foundations of Mathematics*, 2 vols. Oxford Uni. Press: 542-73. Secondary: *Lectures on Ten British Mathematicans of the Nineteenth Century* by Alexander MacFarlane (complete text at Project Gutenberg) - T. Crilly, "A Victorian mathematician: Arthur Cayley (1821-1895),"
*The Mathematical Gazette,* **Vol. 79**, No. 485, 1995, pp. 259-262. Alexander Macfarlane (Blairgowrie, Scotland, April 21, 1851 â€“ Chatham, Ontario, August 28, 1913) was a Scottish-Canadian logician, physicist, and mathematician. ...
Project Gutenberg, abbreviated as PG, is a volunteer effort to digitize, archive and distribute cultural works. ...
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