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 No. 17 
 
 LECTURES ON 
 
 TEN BRITISH MATHEMATICIANS 
 
 OF THE Nineteenth Century 
 
 BY 
 
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 Late President of the International Association for Promoting 
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PREFACE 
 
 DxjRiNG the years 1901-1904 Dr. Alexander Macfarlane 
 delivered, at Lehigh University, lectures on twenty-five British 
 mathematicians of the nineteenth century. The manuscripts 
 of twenty of these lectures have been found to be almost ready 
 for the printer, although some marginal notes by the author 
 indicate that he had certain additions in view. The editors 
 have felt free to disregard such notes, and they here present 
 ten lectures on ten pure mathematicians in essentially the same 
 form as delivered. In a future volume it is hoped to issue 
 lectures on ten mathematicians whose main work was in physics 
 and astronomy. 
 
 These lectures were given to audiences composed of students, 
 instructors and townspeople, and each occupied less than an 
 hour in delivery. It should hence not be expected that a lecture 
 can fully treat of all the activities of a mathematician, much 
 less give critical analyses of his work and careful estimates of 
 his influence. It is felt by the editors, however, that the lectures 
 will prove interesting and inspiring to a wide circle of readers 
 who have no acquaintance at first hand with the works of the 
 men who are discussed, while they cannot fail to be of special 
 interest to older readers who have such acquaintance. 
 
 It should be borne in mind that expressions such as " now," 
 " recently," " ten years ago," etc., belong to the year when a 
 lecture was delivered. On the first page of each lecture will 
 be found the date of its delivery. 
 
 For six of the portraits given in the frontispiece the 
 editors are indebted to the kindness of Dr. David Eugene 
 Smith, of Teachers College, Columbia University. 
 
 3 
 
4 PREFACE 
 
 Alexander Macfarlane was born April 21, 185 1, at Blairgowrie, 
 Scotland. From 1871 to 1884 he was a student, instructor and 
 examiner in physics at the University of Edinburgh, from 1885 
 to 1894 professor of physics in the University of Texas, and from 
 1895 to 1908 lecturer in electrical engineering and mathematical 
 physics in Lehigh University. He was the author of papers on 
 algebra of logic, vector analysis and quaternions, and of Mono- 
 graph No. 8 of this series. He was twice secretary of the sec- 
 tion of physics of the American Association for the Advancement 
 of Science, and twice vice-president of the section of mathematics 
 and astronomy. He was one of the founders of the International 
 Association for Promoting the Study of Quaternions, and its 
 president at the time of his death, which occured at Chatham, 
 Ontario, August 28, 1913. His personal acquaintance with 
 British mathematicians of the nineteenth century imparts to 
 many of these lectures a personal touch which greatly adds 
 to their general interest. 
 
 Alexander Macfarlane 
 From a photograph of 189; 
 
CONTENTS 
 
 Portraits of Mathematicians Frontispiece 
 
 George Peacock (1791-1858) page 7 
 
 A Lecture del Vered Apri 12,1901. 
 
 Augustus De Morgan (1806-1871) 19 
 
 A Lecture delivered April 13, igoi. 
 
 Sir William Rowan Hamilton (1805-1865) 34 
 
 A Lecture delivered April 16, 1901. 
 
 George Boole (1815-1864) 50 
 
 A Lecture de ivered April 19, 1901. 
 
 Arthur Cayley (1821-1895) 64 
 
 A Lecture delivered April 20, 1901. 
 
 William Kingdon Clifford (1845-1879) 78 
 
 A Lecture delivered April 23, 1901. 
 
 Henry John Stephen Smith (1826-1883) 92 
 
 A Lecture delivered March 15, 1902. 
 
 James Joseph Sylvester (1814-1897) 107 
 
 A Lecture delivered March 21, 1902. 
 
 Thomas Penyngton Kirkman (1806-1895 122 
 
 A Lecture delivered April 20, 1903. 
 
 Isaac Todhunter (1820-1884) 134 
 
 A Lecture de.ivered April 13, 1904. 
 
 Index i47 
 
 5 
 
TEN BRITISH MATHEMATICIANS 
 
 GEORGE PEACOCK* 
 
 (1791-1858) 
 
 George Peacock was born on April 9, 1791, at Denton 
 in the north of England, 14 miles from Richmond in Yorkshire. 
 His father, the Rev. Thomas Peacock, was a clergyman of the 
 Church of England, incumbent and for 50 years curate of the 
 parish of Denton, where he also kept a school. In early life 
 Peacock did not show any precocity of genius, and was more 
 remarkable for daring feats of climbing than for any special 
 attachment to study. He received his elementary education 
 from his father, and at 17 years of age, was sent to Richmond, 
 to a school taught by a graduate of Cambridge University to 
 receive instruction preparatory to entering that University. 
 At this school he distinguished himself greatly both in classics 
 and in the rather elementary mathematics then required for 
 entrance at Cambridge. In 1809 he became a student of Trinity 
 College, Cambridge. 
 
 Here it may be well to give a brief account of that Uni- 
 versity, as it was the alma mater of four out of the six mathe- 
 maticians discussed in this course of lectures. f 
 
 At that time the University of Cambridge consisted of seven- 
 teen colleges, each of which had an independent endowment, 
 buildings, master, fellows and scholars. The endowments, gen- 
 erally in the shape of lands, have come down from ancient times; 
 for example, Trinity College was founded by Henry VIII in 
 
 * This Lecture was delivered April 12, 1901. — Editors. 
 t Dr. Macfarlane's first course included the first six lectures given in this 
 volxime. — Editors. 
 
 7 
 
8 TEN BRITISH MATHEMATICIANS 
 
 1546, and at the beginning of the 19th century it consisted of a 
 master, 60 fellows and 72 scholars. Each college was provided 
 with residence halls, a dining hall, and a chapel. Each college 
 had its own staff of instructors called tutors or lecturers, and 
 the function of the University apart from the colleges was 
 mainly to examine for degrees. Examinations for degrees con- 
 sisted of a pass examination and an honors examination, the 
 latter called a tripos. Thus, the mathematical tripos meant 
 the examinations of candidates for the degree of Bachelor of 
 Arts who had made a special study of mathematics. The 
 examination was spread over a week, and those who obtained 
 honors were divided into three classes, the highest class being 
 called wranglers, and the highest man among the wranglers, 
 senior wrangler. In more recent times this examination de- 
 veloped into what De Morgan called a " great writing race;" 
 the questions being of the nature of short problems. A candidate 
 put himself under the training of a coach, that is, a mathema- 
 tician who made it a business to study the kind of problems 
 likely to be set, and to train men to solve and write out the 
 solution of as many as possible per hour. As a consequence 
 the lectures of the University professors and the instruction of 
 the college tutors were neglected, and nothing was studied ex- 
 cept what would pay in the tripos examination. Modifications 
 have been introduced to counteract these evils, and the con- 
 ditions have been so changed that there are now no senior 
 wranglers. The tripos examination used to be followed almost 
 immediately by another examination in higher mathematics to 
 determine the award of two prizes named the Smith's prizes. 
 " Senior wrangler " was considered the greatest academic dis- 
 tinction in England. 
 
 In 18 1 2 Peacock took the rank of second wrangler, and the 
 second Smith's prize, the senior wrangler being John Herschel. 
 Two years later he became a candidate for a fellowship in his 
 college and won it immediately, partly by means of his exten- 
 sive and accurate knowledge of the classics. A fellowship then 
 meant about £200 a year, tenable for seven years provided 
 the Fellow did not marry meanwhile, and capable of being 
 
GEORGE PEACOCK 9 
 
 extended after the seven years provided the Fellow took clerical 
 Orders. The limitation to seven years, although the Fellow 
 devoted himself exclusively to science, cut short and prevented 
 by anticipation the career of many a laborer for the advance- 
 ment of science. Sir Isaac Newton was a Fellow of Trinity 
 College, and its limited terms nearly deprived the world of the 
 Principia. 
 
 The year after taking a Fellowship, Peacock was appointed 
 a tutor and lecturer of his college, which position he continued 
 to hold for many years. At that time the state of mathematical 
 learning at Cambridge was discreditable. How could that be? 
 you may ask; was not Newton a professor of mathematics in 
 that University? did he not write the Principia in Trinity 
 College? had his influence died out^so soon? The true reason 
 was he was worshipped too much as an authority; the Univer- 
 sity had settled down to the study of Newton instead of Nature, 
 and they had followed him in one grand mistake — the ignoring 
 of the differential notation in the calculus. Students of the 
 differential calculus are more or less familiar with the controversy 
 which raged over the respective claims of Newton and Leibnitz 
 to the invention of the calculus ; rather over the question whether 
 Leibnitz was an independent inventor, or appropriated the 
 fundamental ideas from Newton's writings and correspondence, 
 merely giving them a new clothing in the form of the differential 
 notation. Anyhow, Newton's countrymen adopted the latter 
 alternative; they clung to the fluxional notation of Newton; 
 and following Newton, they ignored the notation of Leibniz 
 and everything written in that notation. The Newtonian 
 notation is as follows: If y denotes a fluent, then y denotes its 
 fluxion, and y the fluxion of >'; if y itself be considered a fluxion, 
 then y' denotes its fluent, and y" the fluent of y' and so on; 
 a differential is denoted by o. In the notation of Leibnitz y 
 
 is written -t-, y is written — ^, y' is | ydx, and so on. The 
 ax dx^ J 
 
 result of this Chauvinism on the part of the British mathema- 
 ticians of the eighteenth century was that the developments of 
 the calculus were made by the contemporary mathematicians 
 
10 TEN BRITISH MATHEMATICIANS 
 
 of the Continent, namely, the BernouUis, Euler, Clairault, 
 Delambre, Lagrange, Laplace, Legendre. At the beginning 
 of the 19th century, there was only one mathematician in Great 
 Britain (namely Ivory, a Scotsman) who was familiar with the 
 achievements of the Continental mathematicians. Cambridge 
 University in particular was wholly given over not merely to the 
 use of the fiuxional notation but to ignoring the differential 
 notation. The celebrated saying of Jacobi was then literally 
 true, although it had ceased to be true when he gave it utterance. 
 He visited Cambridge about 1842. When dining as a guest at 
 the high table of one of the colleges he was asked who in his 
 opinion was the greatest of the living mathematicians of England ; 
 his reply was " There is none." 
 
 Peacock, in common with many other students of his own 
 standing, was profoundly impressed with the need of reform, 
 and while still an undergraduate formed a league with Babbage 
 and Herschel to adopt measures to bring it about. In 18 15 they 
 formed what they called the Analytical Society, the object of 
 which was stated to be to advocate the d'ism of the Continent 
 versus the dot-a.ge of the University. Evidently the members 
 of the new society were armed with wit as well as mathematics. 
 Of these three reformers, Babbage afterwards became celebrated 
 as the inventor of an analytical engine, which could not only 
 perform the ordinary processes of arithmetic, but, when set 
 with the proper data, could tabulate the values of any function 
 and print the results. A part of the machine was constructed, 
 but the inventor and the Government (which was supplying the 
 funds) quarrelled, in consequence of which the complete machine 
 exists only in the form of drawings. These are now in the 
 possession of the British Government, and a scientific commis- 
 sion appointed to examine them has reported that the engine 
 could be constructed. The third reformer — Herschel — was a 
 son of Sir William Herschel, the astronomer who discovered 
 Uranus, and afterwards as Sir John Herschel became famous 
 as an astronomer and scientific philosopher. 
 
 The first movement on the part of the Analytical Society 
 was to translate from the French the smaller work of Lacroix on 
 
GEORGE PEACOCK 11 
 
 the differential and integral calculus; it was published in 1816. 
 At that time the best manuals, as well as the greatest works on 
 mathematics, existed in the French language. Peacock followed 
 up the translation with a volume containing a copious Collection 
 of Examples of the Application of the Differential and Integral 
 Calculus, which was pubHshed in 1820. The sale of both books 
 was rapid, and contributed materially to further the object of 
 the Society. Then high wranglers of one year became the 
 examiners of the mathematical tripos three or four years after- 
 wards. Peacock was appointed an examiner in 1817, and he did 
 not fail to make use of the position as a powerful lever to advance 
 the cause of reform. In his questions set for the examination 
 the differential notation was for the first time officially employed 
 in Cambridge. The innovation did not escape censure, but he 
 wrote to a friend as follows: " I assure you that I shall never 
 cease to exert myself to the utmost in the cause of reform, and 
 that I will never decline any office which may increase my 
 power to effect it. I am nearly certain of being nominated to 
 the office of Moderator in the year 1818-1819, and as I am an 
 examiner in virtue of my office, for the next year I shall pursue 
 a course even more decided than hitherto, since I shall feel that 
 men have been prepared for the change, and will then be 
 enabled to have acquired a better system by the publication of 
 improved elementary books. I have considerable influence as 
 a lecturer, and I will not neglect it. It is by silent perseverance 
 only, that we can hope to reduce the many-headed monster of 
 prejudice and make the University answer her character as the 
 loving mother of good learning and science." These few sen- 
 tences give an insight into the character of Peacock: he was 
 an ardent reformer and a few years brought success to the cause 
 of the Analytical Society. 
 
 Another reform at which Peacock labored was the teaching 
 of algebra. In 1830 he pubUshed a Treatise on Algebra which 
 had for its object the placing of algebra on a true scientific 
 basis, adequate for the development which it had received at 
 the hands of the Continental mathematicians. As to the state 
 of the science of algebra in Great Britain, it may be judged 
 
12 TEN BRITISH MATHEMATICIANS 
 
 of by the following facts. Baron Maseres, a Fellow of Clare 
 College, Cambridge, and William Frend, a second wrangler, 
 had both written books protesting against the use of the nega- 
 tive quantity. Frend published his Principles of Algebra in 1 796, 
 and the preface reads as follows: " The ideas of number are the 
 clearest and most distinct of the human mind; the acts of the 
 mind upon them are equally simple and clear. There cannot 
 be confusion in them, unless numbers too great for the com- 
 prehension of the learner are employed, or some arts are used 
 which are not justifiable. The first error in teaching the first 
 principles of algebra is obvious on perusing a few pages only 
 of the first part of Maclaurin's Algebra. Numbers are there 
 divided into two sorts, positive and negative; and an attempt 
 ismade to explain the nature of negative numbers by allusion 
 to book debts and other arts. Now when a person cannot 
 explain the principles of a science without reference to a meta- 
 phor, the probability is, that he has never thought accurately 
 upon the subject. A number may be greater or less than another 
 number; it may be added to, taken from, multiplied into, or 
 divided by, another number; but in other respects it is very 
 intractable; though the whole world should be destroyed, one 
 will be one, and three will be three, and no art whatever can 
 change their nature. You may put a mark before one, which 
 it wUl obey; it submits to be taken away from a number greater 
 than itself, but to attempt to take it away from a number less 
 than itself is ridiculous. Yet this is attempted by algebraists 
 who talk of a number less than nothing ; of multiplying a negative 
 number into a negative number and thus producing a positive 
 number; of a number being imaginary. Hence they talk of 
 two roots^to every equation of the second order, and the learner 
 is to try which will succeed in a given equation; they talk of 
 solving an equation which requires two impossible roots to make 
 it soluble; they can find out some impossible numbers which 
 being multiplied together produce unity. This is all jargon, 
 at which common sense recoils; but from its having been once 
 adopted, like many other figments, it finds the most strenuous 
 supporters among those who love to take things upon trust and 
 
GEORGE PEACOCK 13 
 
 hate the colour of a serious thought." So far, Frend. Peacock 
 knew that Argand, Franjais and Warren had given what 
 seemed to be an explanation not only of the negative quantity 
 but of the imaginary, and his object was to reform the teaching 
 of algebra so as to give it a true scientific basis. 
 
 At that time every part of exact science was languishing in 
 Great Britain. Here is the description given by Sir John 
 Herschel: "The end of the i8th and the beginning of the 19th 
 century were remarkable for the small amount of scientific move- 
 ment going on in Great Britain, especially in its more exact 
 departments. Mathematics were at the last gasp, and Astronomy 
 nearly so — I mean in those members of its frame which depend 
 upon precise measurement and systematic calculation. The 
 chilling torpor of routine had begun to spread itself over all 
 those branches of Science which wanted the excitement of 
 experimental research." To elevate astronomical science the 
 Astronomical Society of London was founded, and our three 
 reformers Peacock, Babbage and Herschel were prime movers 
 in the undertaking. Peacock was one of the most zealous 
 promoters of an astronomical observatory at Cambridge, and 
 one of the founders of the Philosophical Society of Cambridge. 
 
 The year 1831 saw the beginning of one of the greatest 
 scientific organizations of modern times. That year the British 
 Association for the Advancement of Science (prototype of the 
 American, French and Australasian Associations) held its first 
 meeting in the ancient city of York. Its objects were stated 
 to be: first, to give a stronger impulse and a more systematic 
 direction to scientific enquiry; second, to promote the inter- 
 course of those who cultivate science in different parts of the 
 British Empire with one another and with foreign philosophers; 
 third, to obtain a more general attention to the objects of 
 science, and the removal of any disadvantages of a public kind 
 which impede its progress. One of the first resolutions adopted 
 was to procure reports on the state and progress of particular 
 sciences, to be drawn up from time to time by competent per- 
 sons for the information of the annual meetings, and the first 
 to be placed on the list was a report on the progress of mathe- 
 
14 TEN BRITISH MATHEMATICIANS 
 
 matical science. Dr. Whewell, the mathematician and phil- 
 osopher, was a Vice-president of the meeting : he was instructed 
 to select the reporter. He first asked Sir W. R. Hamilton, who 
 declined; he then asked Peacock, who accepted. Peacock had 
 his report ready for the third meeting of the Association, which 
 was held in Cambridge in 1833; although limited to Algebra, 
 Trigonometry, and the Arithmetic of Sines, it is one of the best 
 of the long series of valuable reports which have been prepared 
 for and printed by the Association. 
 
 In 1837 he was appointed Lowndean professor of astronomy 
 in the University of Cambridge, the chair afterwards occupied 
 by Adams, the co-discoverer of Neptune, and now occupied by 
 Sir Robert Ball, celebrated for his Theory of Screws. In 1839 
 he was appointed Dean of Ely, the diocese of Cambridge. While 
 holding this position he wrote a text book on algebra in two 
 volumes, the one called Arithmetical Algebra, and the other 
 Symbolical Algebra. Another object of reform was the stat- 
 utes of the University; he worked hard at it and was made 
 a member of a commission appointed by the Government for 
 the purpose; but he died on November 8, 1858, in the 68th year 
 of his age. His last public act was to attend a meeting of the 
 Commission. 
 
 Peacock's main contribution to mathematical analysis is his 
 attempt to place algebra on a strictly logical basis. He founded 
 what has been called the philological or symbolical school of 
 mathematicians; to which Gregory, De Morgan and Boole 
 belonged. His answer to Maseres and Frend was that the 
 science of algebra consisted of two parts — arithmetical algebra 
 and symbolical algebra — and that they erred in restricting the 
 science to the arithmetical part. His view of arithmetical 
 algebra is as follows: " In arithmetical algebra we consider 
 symbols as representing numbers, and the operations to which 
 they are submitted as included in the same definitions as in 
 common arithmetic; the signs -t- and - denote the operations 
 of addition and subtraction in their ordinary meaning only, 
 and those operations are considered as impossible in all cases 
 where the symbols subjected to them possess values which 
 
GEORGE PEACOCK 15 
 
 would render them so in case they were replaced by digital 
 numbers; thus in expressions such as a+b we must suppose 
 a and b to be quantities of the same kind; in others, like a — b, 
 we must suppose a greater than b and therefore homogeneous 
 
 with it; in products and quotients, like ab and - we must suppose 
 
 the multiplier and divisor to be abstract numbers; all results 
 whatsoever, including negative quantities, which are not strictly 
 deducible as legitimate conclusions from the definitions of the 
 several operations must be rejected as impossible, or as foreign 
 to the science." 
 
 Peacock's principle may be stated thus: the elementary 
 symbol of arithmetical algebra denotes a digital, i.e., an integer 
 number; and every combination of elementary symbols must 
 reduce to a digital number, otherwise it is impossible or foreign 
 to the science. If a and b are numbers, then a+b is always 
 a number; but a—b is a number only when b is less than a. 
 Again, under the same conditions, ab is always a number, but 
 
 - is really a number only when b is an exact divisor of a. 
 b 
 
 Hence we are reduced to the following dilemma : Either - must 
 
 
 
 be held to be an impossible expression in general, or else the 
 meaning of the fundamental symbol of algebra must be extended 
 so as to include rational fractions. If the former horn of the 
 dilemma is chosen, arithmetical algebra becomes a mere shadow; 
 if the latter horn is chosen, the operations of algebra cannot 
 be defined on the supposition that the elementary symbol is an 
 integer number. Peacock attempts to get out of the difificulty 
 by supposing that a symbol which is used as a multiplier is 
 always an integer number, but that a symbol in the place of the 
 multiplicand may be a fraction. For instance, in ab, a can denote 
 only an integer number, but b may denote a rational fraction. 
 Now there is no more fundamental principle in arithmetical 
 algebra than that ab = ba; which would be illegitimate on 
 Peacock's principle. 
 
 One of the earliest English writers on arithmetic is Robert 
 
16 TEN BRITISH MATHEMATICIANS 
 
 Record, who dedicated his work to King Edward the Sixth. 
 The author gives his treatise the form of a dialogue between 
 master and scholar. The scholar battles long over this diffi- 
 culty, — that multiplying a thing could make it less. The master 
 attempts to explain the anomaly by reference to proportion; 
 that the product due to a fraction bears the same proportion to 
 the thing multiplied that the fraction bears to unity. But the 
 scholar is not satisfied and the master goes on to say: " If I 
 multiply by more than one, the thing is increased; if I take it 
 but once, it is not changed, and if I take it less than once, it 
 cannot be so much as it was before. Then seeing that a fraction 
 is less than one, if I multiply by a fraction, it follows that I do 
 take it less than once." Whereupon the scholar replies, " Sir, 
 I do thank you much for this reason, — and I trust that I do per- 
 ceive the thing." 
 
 The fact is that even in arithmetic the two processes of 
 multiplication and division are generalized into a common mul- 
 tiplication ; and the difficulty consists in passing from the origi- 
 nal idea of multiplication to the generalized idea of a tensor, 
 which idea includes compressing the magnitude as well as 
 stretching it. Let m denote an integer number; the next step 
 
 is to gain the idea of the reciprocal of m, not as — but simply as 
 
 m 
 
 /m. When m and /n are compounded we get the idea of a 
 rational fraction ; for in general m/n will not reduce to a number 
 nor to the reciprocal of a number. 
 
 Suppose, however, that we pass over this objection; how 
 does Peacock lay the foundation for general algebra? He calls 
 it symbolical algebra, and he passes from arithmetical algebra 
 to symbolical algebra in the following manner: " Symbolical 
 algebra adopts the rules of arithmetical algebra but removes 
 altogether their restrictions; thus symbolical subtraction dif- 
 fers from the same operation in arithmetical algebra in being 
 possible for all relations of value of the symbols or expressions 
 employed. All the results of arithmetical algebra which are 
 deduced by the application of its rules, and which are general 
 in form though particular in value, are results likewise of 
 
GEORGE PEACOCK 17 
 
 symbolical algebra where they are general in value as well as in 
 form; thus the product of a"* and a" which is a""*"" when m 
 and n are whole numbers and therefore general in form though 
 particular in value, will be their product likewise when m and 
 n are general in value as well as in form; the series for (a +6)" 
 determined by the principles of arithmetical algebra when n 
 is any whole number, if it he exhibited in a general form, without 
 reference to a final term, may be shown upon the same principle 
 to the equivalent series for (a+b)" when n is general both in 
 form and value." 
 
 The principle here indicated by means of examples was 
 named by Peacock the " principle of the permanence of equiva- 
 lent forms," and at page 59 of the Symbolical Algebra it is thus 
 enunciated: " Whatever algebraical forms are equivalent when- 
 the symbols are general in form, but specific in value, will be 
 equivalent likewise when the symbols are general in value as 
 well as in form." 
 
 For example, let a, b, c, d denote any integer numbers, but 
 subject to the restrictions that b is less than a, and d less than 
 c; it may then be shown arithmetically that 
 
 {a — b){c—d) =ac-{-bd — ad—bc. 
 
 Peacock's principle says that the form on the left side is equiva- 
 lent to the form on the right side, not only when the said 
 restrictions of being less are removed, but when a, b, c, d denote 
 the most general algebraical symbol. It means that a, b, c, d 
 may be rational fractions, or surds, or imaginary quantities, 
 
 or indeed operators such as — . The equivalence is not estab- 
 
 lished by means of the nature of the quantity denoted; the 
 equivalence is assumed to be true, and then it is attempted 
 to find the different interpretations which may be put onthe 
 symbol. 
 
 It is not difficult to see that the problem before us 
 involves the fundamental problem of a rational logic or 
 theory of knowledge; namely, how are we able to ascend from 
 particular truths to more general truths. If a, b, c, d denote 
 
18 TEN BRITISH MATHEMATICIANS 
 
 integer numbers, of which b is less than a and d less than c, 
 then 
 
 (a — b) {c—d)—ac+bd — ad — bc. 
 
 It is first seen that the above restrictions may be removed, 
 and still the above equation hold. But the antecedent is still 
 too narrow; the true scientific problem consists in specifying 
 the meaning of the symbols, which, and only which, will admit 
 of the forms being equal. It is not to find some meanings, but 
 the most general meaning, which allows the equivalence to be 
 true. Let us examine some other cases; we shall find that 
 Peacock's principle is not a solution of the difficulty; the great 
 logical process of generalization cannot be reduced to any such 
 easy and arbitrary procedure. When a, m, n denote integer 
 numbers, it can be shown that 
 
 According to Peacock the form on the left is always to be equal to 
 the form on the right, and the meanings of a, m, n are to be found 
 by interpretation. Suppose that a takes the form of the incom- 
 mensurate quantity e, the base of the natural system of logar- 
 ithms. A n umber is a degraded form of a complex quantity 
 {p+q'\'—i) and a complex quantity is a degraded form of a 
 quaternion; consequently one meaning which may be assigned 
 to m and n is that of quaternion. Peacock's principle would 
 lead us to suppose that e'"e" = e'"+'', m and n denoting qua- 
 ternions; but that is just what Hamilton, the inventor of the 
 quaternion generalization, denies. There are reasons for believ- 
 ing that he was mistaken, and that the forms remain equivalent 
 even under that extreme generalization of m and n; but the 
 point is this: it is not a question of conventional definition and 
 formal truth; it is a question of objective definition and real 
 truth. Let the symbols have the prescribed meaning, does or 
 does not the equivalence still hold? And if it does not hold, 
 what is the higher or more complex form which the equivalence 
 assumes? 
 
AUGUSTUS DE MORGAN* 
 (1806-1871) 
 
 AtTGTJSTUS De Morgan was born in the month of June at 
 Madura in the presidency of Madras, India; and the year of 
 his birth may be found by solving a conundrum proposed by 
 himself, " I was x years of age in the year x^." The problem 
 is indeterminate, but it is made strictly determinate by the 
 century of its utterance and the limit to a man's life. His father 
 was Col. De Morgan, who held various appointments in the service 
 of the East India Company. His mother was descended from 
 James Dodson, who computed a table of anti-logarithms, that is, 
 the numbers corresponding to exact logarithms. It was the time 
 of the Sepoy rebellion in India, and Col. De Morgan removed 
 his family to England when Augustus was seven months old. 
 As his father and grandfather had both been born in India, 
 De Morgan used to say that he was neither English, nor Scottish, 
 nor Irish, but a Briton " unattached," using the technical 
 term applied to an undergraduate of Oxf )rd or Cambridge who 
 is not a member of any one of the Colleges. 
 
 WhenDe Morgan was ten years old, his father died. Mrs. 
 De Morgan resided at various places in the southwest of England, 
 and her son received his elementary education at various schools 
 of no great account. His mathematical talents were unnoticed 
 till he had reached the age of fourteen. A friend of the family 
 accidentally discovered him making an elaborate drawing of 
 a figure in Euclid with ruler and compasses, and explained to 
 him the aim of Euclid, and gave him an initiation into demon- 
 stration. 
 
 De Morgan suffered from a physical defect — one of his eyes 
 was rudimentary and useless. As a consequence, he did not 
 
 * This Lecture was delivered April 13, 1901. — Editors. 
 19 
 
20 TEN BRITISH MATHEMATICIANS 
 
 join in the sports of the other boys, and he was even made the 
 victim of cruel practical jokes by some schoolfellows. Some 
 psychologists have held that the perception of distance and of 
 solidity depends on the action of two eyes, but De Morgan 
 testified that so far as he could make out he perceived with his 
 one eye distance and solidity just like other people. 
 
 He received his secondary education from Mr. Parsons, 
 a Fellow of Oriel College, Oxford, who could appreciate 
 classics much better than mathematics. His mother was an 
 active and ardent member of the Church of England, and 
 desired that her son should become a clergyman; but by this 
 time De Morgan had begun to show his non-grooving dispo- 
 sition, due no doubt to some extent to his physical infirmity. 
 At the age of sixteen he was entered at Trinity College, Cam- 
 bridge, where he immediately came under the tutorial influence 
 of Peacock and Whewell. They became his life-long friends; 
 from the former he derived an interest in the renovation of 
 algebra, and from the latter an interest in the renovation of 
 logic — the two subjects of his future life work. 
 
 At college the flute, on which he played exquisitely, was his 
 recreation. He took no part in athletics but was prominent 
 in the musical clubs. His love of knowledge for its own sake 
 interfered with training for the great mathematical race; as 
 a consequence he came out fourth wrangler. This entitled him 
 to the degree of Bachelor of Arts; but to take the higher degree 
 of Master of Arts and thereby become eligible for a fellowship 
 it was then necessary to pass a theological test. To the sign- 
 ing of any such test De Morgan felt a strong objection, although 
 he had been brought up in the Church of England. About 
 1875 theological tests for academic degrees were abolished in 
 the Universities of Oxford and Cambridge. 
 
 As no career was open to him at his own university, he 
 decided to go to the Bar, and took up residence in London; 
 but he much preferred teaching mathematics to reading law. 
 About this time the movement for founding the London Uni- 
 versity took shape. The two ancient universities were so 
 guarded by theological tests that no Jew or Dissenter from the 
 
AUGUSTUS DE MORGAN 21 
 
 Church of England could enter as a student; still less be 
 appointed to any ofSce. A body of liberal-minded men resolved 
 to meet the difficulty by establishing in London a University 
 on the principle of religious neutrality. De Morgan, then 22 
 years of age, was appointed Professor of Mathematics. His 
 introductory lecture " On the study of mathematics " is a dis- 
 course upon mental education of permanent value which has 
 been recently reprinted in the United States. 
 
 The London University was a new institution, and the 
 relations of the Council of management, the Senate of professors 
 and the body of students were not well defined. A dispute 
 arose between the professor of anatomy and his students, and in 
 consequence of the action taken by the Council, several of the 
 professors resigned, headed by De Morgan. Another professor 
 of mathematics was appointed, who was accidentally drowned 
 a few years later. De Morgan had shown himself a prince of 
 teachers : he was invited to return to his chair, which thereafter 
 became the continuous center of his labors for thirty years. 
 
 The same body of reformers — headed by Lord Brougham, 
 a Scotsman eminent both in science and politics— who had 
 instituted the London University, founded about the same time 
 a Society for the Diffusion of Useful Knowledge. Its object 
 was to spread scientific and other knowledge by means of cheap 
 and clearly written treatises by the best writers of the time. 
 One of its most voluminous and effective writers was De Morgan. 
 He wrote a great work on The Diferential and Integral Calculus 
 which was published by the Society; and he wrote one-sixth of 
 the articles in the Penny Cyclopedia, published by the Society, 
 and issued in penny numbers. When De Morgan came to reside 
 in London he found a congenial friend in William Frend, not- 
 withstanding his mathematical heresy- about negative quan- 
 tities. Both were arithmeticians and actuaries, and their 
 religious views were somewhat similar. Frend lived in what 
 was then a suburb of London, in a country-house formerly 
 occupied by Daniel Defoe and Isaac Watts. De Morgan with 
 his flute was a welcome visitor; and in 1837 he married Sophia 
 Elizabeth, one of Frend's daughters. 
 
22 TEN BRITISH MATHEMATICIANS 
 
 The London University of which De Morgan was a pro- 
 fessor was a different institution from the University of London. 
 The University of London was founded about ten years later 
 by the Government for the purpose of granting degrees after 
 examination, without any qualification as to residence. The 
 London University was affiliated as a teaching college with the 
 University of London, and its name was changed to University 
 College. The University of London was not a success as an 
 examining body; a teaching University was demanded. De 
 Morgan was a highly successful teacher of mathematics. It was 
 his plan to lecture for an hour, and at the close of each lecture 
 to give out a number of problems and examples illustrative 
 of the subject lectured on; his students were required to sit 
 down to them and bring him the results, which he looked over 
 and returned revised before the next lecture. In De Morgan's 
 opinion, a thorough comprehension and mental assimilation of 
 great principles far outweighed in importance any merely 
 analytical dexterity in the application of half-understood prin- 
 ciples to particular cases. 
 
 De Morgan had a son George, who acquired great distinction 
 in mathematics both at University College and the University 
 of London. He and another like-minded alumnus conceived 
 the idea of founding a Mathematical Society in London, where 
 mathematical papers would be not only received (as by the 
 Royal Society) but actually read and discussed. The first 
 meeting was held in University College; De Morgan was the 
 first president, his son the first secretary. It was the beginning 
 of the London Mathematical Society. In the year 1866 the 
 chair of mental philosophy in University College fell vacant. 
 Dr. Martineau, a Unitarian clergyman and professor of mental 
 philosophy, was recommended formally by the Senate to the 
 Council; but in the Council there were some who objected to 
 a Unitarian clergyman, and others who objected to theistic 
 philosophy. A layman of the school of Bain and Spencer was 
 appointed. De Morgan considered that the old standard of 
 religious neutrality had been hauled down, and forthwith 
 resigned. He was now 60 years of age. His pupils secured a 
 
AUGUSTUS DE MORGAN 23 
 
 pension of $500 for him, but misfortunes followed. Two years 
 later his son George— the younger Bernoulli, as he loved to 
 hear him called, in allusion to the two eminent mathematicians 
 of that name, related as father and son — died. This blow was 
 followed by the death of a daughter. Five years after his resig- 
 nation from University College De Morgan died of nervous 
 prostration on March 18, 1871, in the 65th year of his age. 
 
 De Morgan was a brilliant and witty writer, whether as a 
 controversialist or as a correspondent. In his time there flour- 
 ished two Sir William Hamiltons who have often been con- 
 founded. The one Sir William was a baronet (that is, inherited 
 the title) , a Scotsman, professor of logic and metaphysics in the 
 University of Edinburgh; the other was a knight (that is, won 
 the title), an Irishman, professor of astronomy in the University 
 of Dublin. The baronet contributed to logic the doctrine of the 
 quantification of the predicate; the knight, whose full name 
 was William Rowan Hamilton, contributed to mathematics the 
 geometric algebra called Quaternions. De Morgan was inter- 
 ested in the work of both, and corresponded with both; but the 
 correspondence with the Scotsman ended in a public controversy, 
 whereas that with the Irishman was marked by friendship and 
 terminated onl}- by death. In one of his letters to Rowan, 
 De Morgan says, "Be it known unto you that I have discovered 
 that you and the other Sir W. H. are reciprocal polars with 
 respect to me (intellectually and morally, for the Scottish 
 baronet is a polar bear, and you, I was going to say, are a polar 
 gentleman). When I send a bit of investigation to Edinburgh, 
 the W. H. of that ilk says I took it from him. When I send 
 you one, you take it from me, generalize it at a glance, bestow 
 it thus generalized upon society at large, and make me the second 
 discoverer of a known theorem." 
 
 The correspondence of De Morgan with Hamilton the mathe- 
 matician extended over twenty-four years; it contains discus- 
 sions not only of mathematical matters, but also of subjects 
 of general interest. It is marked by geniality on the part of 
 Hamilton and by wit on the part of De Morgan. The following 
 is a specimen: Hamilton wrote, " My copy of Berkeley's work 
 
24 TEN BRITISH MATHEMATICIANS 
 
 is not mine; like Berkeley, you know, I am an Irishman." De 
 Morgan replied, " Your phrase ' my copy is not mine ' is not 
 a bull. It is perfectly good English to use the same word in 
 two different senses in one sentence, particularly when there is 
 usage. Incongruity of language is no bull, for it expresses mean- 
 ing. But incongruity of ideas (as in the case of the Irishman 
 who was pulling up the rope, and finding it did not finish, cried 
 out that somebody had cut off the other end of it) is the genuine 
 bull." 
 
 De Morgan was full of personal pecuharities. We have 
 noticed his almost morbid attitude towards religion, and the 
 readiness with which he would resign an office. On the occasion 
 of the installation of his friend, Lord Brougham, as Rector of 
 the University of Edinburgh, the Senate offered to confer on 
 him the honorary degree of LL.D.; he decUned the honor as 
 a misnomer. He once printed his name : Augustus De Morgan, 
 
 H-O-MO • PAU-C-ARUM • L-IT-E-R-A-R-U-M. 
 
 He disliked the country, and while his family enjoyed the sea- 
 side, and men of science were having a good time at a meeting 
 of the British Association in the country he remained in the hot 
 and dusty libraries of the metropolis. He said that he felt 
 like Socrates, who declared that the farther he got from Athens 
 the farther was he from happiness. He never sought to become 
 a Fellow of the Royal Society, and he never attended a meeting 
 of the Society; he said that he had no ideas or sympathies in 
 common with the physical philosopher. His attitude was 
 doubtless due to his physical infirmity, which prevented him 
 from being either an observer or an experimenter. He never 
 voted at an election, and he never visited the House of Commons, 
 or the Tower, or Westminster Abbey. 
 
 Were the writings of De Morgan published in the form of 
 collected works, they would form a small library. We have 
 noticed his writings for the Useful Knowledge Society. Mainly 
 through the efforts of Peacock and Whewell, a Philosophical 
 Society had been inaugurated at Cambridge; and to its Trans- 
 actions De Morgan contributed four memoirs on the foundations 
 
AUGUSTUS DE MORGAN 25 
 
 of algebra, and an equal number on formal logic. The best 
 presentation of his view of algebra is found in a volume, entitled 
 Trigonometry and Double Algebra, published in 1849; ^^^ his 
 earlier view of formal logic is found in a volume pubUshed in 
 1847. His most unique work is styled a Budget of Paradoxes; 
 it originally appeared as letters in the columns of the AthencBum 
 Journal ; it was revised and extended by De Morgan in the last 
 years of his life, and was published posthumously by his widow. 
 " If you wish to read something entertaining," said Professor 
 Tait to me, " get De Morgan's Budget of Paradoxes out of the 
 library." We shall consider more at length his theory of 
 algebra, his contribution to exact logic, and his Budget of 
 Paradoxes. 
 
 In my last lecture I explained Peacock's theory of algebra. 
 It was much improved by D. F. Gregory, a younger member 
 of the Cambridge School, who laid stress not on the permanence 
 of equivalent forms, but on the permanence of certain formal 
 laws. This new theory of algebra as the science of symbols 
 and of their laws of combination was carried to its logical issue 
 by De Morgan; and his doctrine on the subject is still followed 
 by English algebraists in general. Thus Chrystal founds his 
 Textbook of Algebra on De Morgan's theory; although an 
 attentive reader may remark that he practically abandons it 
 when he takes up the subject of infinite series. De Morgan's 
 theory is stated in his volume on Trigonometry and Double 
 Algebra. In the chapter (of the book) headed " On symboUc 
 algebra " he writes: " In abandoning the meaning of symbols, 
 we also abandon those of the words which describe them. Thus 
 addition is to be, for the present, a sound void of sense. It 
 is a mode of combination represented by + ; when + receives 
 its meaning, so also will the word addition. It is most impor- 
 tant that the student should bear in mind that, with one exception, 
 no word nor sign of arithmetic or algebra has one atom of mean- 
 ing throughout this chapter, the object of which is symbols, 
 and their laws of combination, giving a symbolic algebra which 
 may hereafter become the grammar of a hundred distinct sig- 
 nificant algebras. If any one were to assert that -\- and — 
 
26 TEN BRITISH MATHEMATICIANS 
 
 might mean reward and punishment, and A, B, C, etc., might 
 stand for virtues and vices, the reader might believe him, or 
 contradict him, as he pleases, but not out of this chapter. The 
 one exception above noted, which has some share of meaning, 
 is the sign = placed between two symbols as in ^ =5. It indi- 
 cates that the two symbols have the same resulting meaning, 
 by whatever steps attained. That A and B, if quantities, 
 are the same amount of quantity; that if operations, they are 
 of the same effect, etc." 
 
 Here, it may be asked, why does the symbol = prove refrac- 
 tory to the symbolic theory? De Morgan admits that there 
 is one exception; but an exception proves the rule, not in the 
 usual but illogical sense of establishing it, but in the old and 
 logical sense of testing its validity. If an exception can be 
 established, the rule must fall, or at least must be modified. 
 Here I am talking not of grammatical rules, but of the rules 
 of science or nature. 
 
 De Morgan proceeds to give an inventory of the fundamental 
 symbols of algebra, and also an inventory of the laws of algebra. 
 The symbols are o, i, +, -, X, -^, Q^', and letters; these 
 only, all others are derived. His inventory of the fundamental 
 laws is expressed under fourteen heads, but some of them are 
 merely definitions. The laws proper may be reduced to the 
 following, which, as he admits, are not all independent of one 
 another: 
 
 I. Law of signs. -f-|-=+, 4-- = -, - + = -, ==+, XX=X, 
 
 X-^=-H, -HX=-^, H---=X. 
 II. Commutative law. a+b=b+a, ab = ba. 
 
 III. Distributive law. a{b+c)=ab+ac. 
 
 IV. Index laws. a''Xa'=J'+', {a'')'=a}", {aby=aV. 
 V. a—a=o, a-i-a—i. 
 
 The last two may be called the rules of reduction. De Morgan 
 professes to give a complete inventory of the laws which the 
 symbols of algebra must obey, for he says, " Any system of 
 symbols which obeys these laws and no others, except they be 
 formed by combination of these laws, and which uses the pre- 
 ceding symbols and no others, except they be new symbols 
 
AUGUSTUS DE MORGAN 27 
 
 invented in abbreviation of combinations of these symbols, is 
 symbolic algebra." From his point of view, none of the above 
 principles are rules; they are formal laws, that is, arbitrarily 
 chosen relations to which the algebraic symbols must be subject. 
 He does not mention the law, which had already been pointed 
 out by Gregory, namely, {a+b)+c = a + (b+c), (ab)c = a(bc) and 
 to which was afterwards given the name of the law of association. 
 If the commutative law fails, the associative may hold good; 
 but not vice versa. It is an unfortunate thing for the symbolist 
 or formalist that in universal arithmetic m" is not equal to w"; 
 for then the commutative law would have full scope. Why 
 does he not give it full scope? Because the foundations of 
 algebra are, after all, real not formal, material not symbolic. 
 To the formaHsts the index operations are exceedingly refrac- 
 tory, in consequence of which some take no account of them, 
 but relegate them to applied mathematics. To give an inventory 
 of the laws which the symbols of algebra must obey is an impos- 
 sible task, and reminds one not a little of the task of those 
 philosophers who attempt to give an inventory of the a priori 
 knowledge of the mind. 
 
 De Morgan's work entitled Trigonometry and Double Algebra 
 consists of two parts; the former of which is a treatise on 
 Trigonometry, and the latter a treatise on generalized algebra 
 which he calls Double Algebra. But what is meant by Double 
 as applied to algebra? and why should Trigonom-etry be also 
 treated in the same textbook? The first stage in the develop- 
 ment of algebra is arithmetic, where numbers only appear and 
 symbols of operations such as -|-, X, etc. The next stage is 
 universal arithmetic, where letters appear instead of numbers, 
 so as to denote numbers universally, and the, processes are con- 
 ducted without knowing the values of the symbols. Let a and 
 b denote any numbers; then such an expression as a — 6 may 
 be impossible; so that in universal arithmetic there is always 
 a proviso, provided the operation is possible. The third stage is 
 single algebra, where the symbol may denote a quantity forwards 
 or a quantity backwards, and is adequately represented by 
 segments on a straight line passing through an origin. Negative 
 
28 
 
 TEN BRITISH MATHEMATICIANS 
 
 quantities are then no longer impossible; they are represented 
 by the backward segment. But an impossibility still remains 
 in the latter part of such an expression as a+bw —i which arises 
 in the solution of the quadratic equation. The fourth stage 
 is double algebra; the algebraic symbol denotes in general a 
 segment of a line in a given plane; it is a double symbol because 
 it involves two specifications, namely, length and direction; 
 and V — I is interpreted as denoting a quadrant. The expres- 
 sion a+bV—i then represents a line in the plane having an 
 abscissa a and an ordinate b. Argand and Warren carried 
 double algebra so far; but they were unable to interpret on 
 this theory such an expression as eiV^. De Morgan attempted 
 it by reducing such an expression to the form b+qV —i, and 
 he considered that he had shown that it could be always so 
 reduced. The remarkable fact is that this double algebra 
 satisfies all the fundamental laws above enumerated, and as 
 every apparently impossible combination of symbols has been 
 interpreted it looks hke the complete form of algebra. 
 
 If the above theory is true, the next stage of development 
 ought to be triple algebra and if a-f JV — i truly represents a line 
 in a given plane, it ought to be possible to find a third term which 
 added to the above would represent a line in space. Argand 
 and some others guessed that it was a-f JV — i+cV — iV — i; 
 although this contradicts the truth established by Euler that 
 V — i^~^ = e~^'. De Morgan and many others worked hard 
 at the problem, but nothing came of it until the problem was 
 taken up by Hamilton. We now see the reason clearly: the 
 symbol of double algebra denotes not a length and a direction; 
 but a multiplier and an angle. In it the angles are confined 
 to one plane; hence the next stage will be a quadruple algebra, 
 when the axis of the plane is made variable. And this gives 
 the answer to the first question; double algebra is nothing but 
 analytical plane trigonometry, and this is the reason why it 
 has been found to be the natural analysis for alternating 
 currents. But De Morgan never got this far; he died 
 with the belief " that double algebra must remain as the full 
 development of the conceptions of arithmetic, so far as 
 
AUGUSTUS DE MORGAN 29 
 
 those symbols are concerned which arithmetic immediately 
 suggests." 
 
 When the study of mathematics revived at the University 
 of Cambridge, so also did the study of logic. The moving 
 spirit was Whewell, the Master of Trinity College, whose prin- 
 cipal writings were a History of the Inductive Sciences, and 
 Philosophy of the Inductive Sciences. Doubtless De Morgan 
 was influenced in his logical investigations by Whewell; but 
 other contemporaries of influence were Sir W. Hamilton of 
 Edinburgh, and Professor Boole of Cork. De Morgan's work 
 on Formal Logic, published in 1847, is principally remarkable 
 for his development of the numerically definite syllogism. The 
 followers of Aristotle say and say truly that from two par- 
 ticular propositions such as Some M's, are A's, and Some M's 
 are B's nothing follows of necessity about the relation of the 
 ^'s and B's. But they go further and say in order that any 
 relation about the ^'s and B's may follow of necessity, the mid- 
 dle term must be taken universally in one of the premises. De 
 Morgan pointed out that from Most M's are A's and Most M's 
 are B's it follows of necessity that some ^'s are B's and he 
 formulated the numerically definite syllogism which puts this 
 principle in exact quantitative form. Suppose that the number 
 of the M's is m, of the M's that are A's is a, and of the M's that 
 are B's is b; then there are at least {a+b~m) A's that area's. 
 Suppose that the number of souls on board a steamer was 1000, 
 that 500 were in the saloon, and 700 were lost; it follows of 
 necessity, that at least 700-^500 — 1000, that is, 200, saloon 
 passengers were lost. This single principle suffices to prove 
 the validity of all the Aristotelian moods ; it is therefore a funda- 
 mental principle in necessary reasoning. 
 
 Here then De Morgan had made a great advance by intro- 
 ducing quantification of the terms. At that time Sir W. Hamilton 
 was teaching at Edinburgh a doctrine of the quantification of 
 the predicate, and a correspondence sprang up. However, De 
 Morgan soon perceived that Hamilton's quantification was of 
 a different character; that it meant for example, substituting 
 the two forms The whole of A is the whole of B, and The whole of 
 
30 TEN BRITISH MATHEMATICIANS 
 
 A is a part of B for the Aristotelian form All ^'s are B's. 
 Philosophers generally have a large share of intolerance; they 
 are too apt to think that they have got hold of the whole truth, 
 and that everything outside of their system is error. Hamilton 
 thought that he had placed the keystone in the Aristotelian 
 arch, as he phrased it; although it must have been a curious 
 arch which could stand 2000 years without a keystone. As 
 a consequence he had no room for De Morgan's innovations. 
 He accused De Morgan of plagiarism, and the controversy 
 raged for years in the columns of the Athenceum, and in the 
 publications of the two writers. 
 
 The memoirs on logic which De Morgan contributed to the 
 Transactions of the Cambridge Philosophical Society subsequent 
 to the publication of his book on Formal Logic are by far the 
 most important contributions which he made to the science, 
 especially his fourth memoir, in which he begins work in the 
 broad field of the logic of relatives. This is the true field for the 
 logician of the twentieth century, in which work of the greatest 
 importance is to be done towards improving language and 
 facilitating thinking processes which occur aU the time in prac- 
 tical hfe. Identity and difference are the two relations which 
 have been considered by the logician; but there are many 
 others equally deserving of study, such as equality, equivalence, 
 consanguinity, affinity, etc. 
 
 In the introduction to the Budget of Paradoxes De Morgan 
 explains what he means by the word. " A great many indi- 
 viduals, ever since the rise of the mathematical method, have, 
 each for himself, attacked its direct and indirect consequences. 
 I shall call each of these persons a paradoxer, and his system a 
 paradox. I use the word in the old sense : a paradox is some- 
 thing which is apart from general opinion, either in subject 
 matter, method, or conclusion. Many of the things brought 
 forward would now be called crotchets, which is the nearest word 
 we have to old paradox. But there is this difference, that by 
 calling a thing a crotchet we mean to speak Hghtly of it; which 
 was not the necessary sense of paradox. Thus in the i6th 
 century many spoke of the earth's motion as the paradox of 
 
AUGUSTUS DE MORGAN 31 
 
 Copernicus and held the ingenuity of that theory in very high 
 esteem, and some I think who even inclined towards it. In the 
 seventeenth century the depravation of meaning took place, 
 in England at least." 
 
 How can the sound paradoxer be distinguished from the false 
 paradoxer? De Morgan supplies the following test: " The 
 manner in which a paradoxer will show himself, as to sense 
 or nonsense, will not depend upon what he maintains, but upon 
 whether he has or has not made a sufficient knowledge of what 
 has been done by others, especially as to the mode of doing it, 
 a preliminary to inventing knowledge for himself. . . . New 
 knowledge, when to any purpose, must come by contemplation 
 of old knowledge, in every matter which concerns thought; 
 mechanical contrivance sometimes, not very often, escapes this 
 rule. All the men who are now called discoverers, in every 
 matter ruled by thought, have been men versed in the minds 
 of their predecessors and learned in what had been before them. 
 There is not one exception." 
 
 I remember that just before the American Association met at 
 Indianapolis in 1890, the local newspapers heralded a great discov- 
 ery which was to be laid before the assembled savants — a young 
 man living somewhere in the country had squared the circle. 
 While the meeting was in progress I observed a young man going 
 about with a roll of paper in his hand. He spoke to me and com- 
 plained that the paper containing his discovery had not been 
 received. I asked him whether his object in presenting the 
 paper was not to get it read, printed and published so that 
 everyone might inform himself of the result; to all of which 
 he assented readily. But, said I, many men have worked at 
 this question, and their results have been tested fully, and 
 they are printed for the benefit of anyone who can read; have 
 you informed yourself of their results? To this there was no 
 assent, but the sickly smile of the false paradoxer. 
 
 The Budget consists of a review of a large collection of 
 paradoxical books which De Morgan had accumulated in his 
 own library, partly by purchase at bookstands, partly from 
 books sent to him for review, partly from books sent to him by 
 
32 TEN BRITISH MATHEMATICIANS 
 
 the authors. He gives the following classification : squarers of 
 the circle, trisectors of the angle, duplicators of the cube, con- 
 structors of perpetual motion, subverters of gravitation, stag- 
 nators of the earth, builders of the universe. You will still 
 find specimens of all these classes in the New World and in the 
 new century. 
 
 De Morgan gives his personal knowledge of paradoxers. " I 
 suspect that I know more of the English class than any man in 
 Britain. I never kept any reckoning: but I know that one 
 year with another — and less of late years than in earlier time — 
 I have talked to more than five in each year, giving more than 
 a hundred and fifty specimens. Of this I am sure, that it is 
 my own fault if they have not been a thousand. Nobody 
 knows how they swarm, except those to whom they naturally 
 resort. They are in all ranks and occupations, of all ages and 
 characters. They are very earnest people, and their purpose 
 is bona fide, the dissemination of their paradoxes. A great many 
 — the mass, indeed — are illiterate, and a great many waste their 
 means, and are in or approaching penury. These discoverers 
 despise one another." 
 
 A paradoxer to whom De Morgan paid the compliment 
 which Achilles paid Hector — to drag him round the walls again 
 and again — was James Smith, a successful merchant of Liver- 
 pool. He found 7r = 3|. His mode of reasoning was a curious 
 caricature of the reductio ad absurdum of Euclid. He said let 
 x = 3|, and then showed that on that supposition, every other 
 value of TT must be absurd ; consequently tt = 3I is the true value. 
 The following is a specimen of De Morgan's dragging round 
 the walls of Troy: " Mr. Smith continues to write me long 
 letters, to which he hints that I am to answer. In his last of 
 31 closely written sides of note paper, he informs me, with refer- 
 ence to my obstinate silence, that though I think myself and 
 am thought by others to be a mathematical Gohath, I have 
 resolved to play the mathematical snail, and keep within my 
 shell. A mathematical snail! This cannot be the thing so called 
 which regulates the striking of a clock ; for it would mean that 
 I am to make Mr. Smith sound the true time of day, which I 
 
AUGUSTUS DE MORGAN 33 
 
 would by no means undertake upon a clock that gains 19 seconds 
 odd in every hour by false quadrative value of tt. But he 
 ventures to tell me that pebbles from the sling of simple truth 
 and common sense will ultimately crack my shell, and put 
 me hors de combat. The confusion of images is amusing: 
 Goliath turning himself into a snail to avoid 7r = 3| and James 
 Smith, Esq., of the Mersey Dock Board: and put hors de combat 
 by pebbles from a sling. If Goliath had crept into a snail shell, 
 David would have cracked the Philistine with his foot. There 
 is something like modesty in the implication that the crack-shell 
 pebble has not yet taken effect; it might have been thought 
 that the slinger would by this time have been singing — And 
 thrice [and one-eighth] I routed all my foes. And thrice [and one- 
 eighth] I slew the slain." 
 
 In the region of pure mathematics De Morgan could detect 
 easily the false from the true paradox; but he was not so pro- 
 ficient in the field of physics. His father-in-law was a para- 
 doxer, and his wife a paradoxer; and in the opinion of the 
 physical philosophers De Morgan himself scarcely escaped. 
 His wife wrote a book describing the phenomena of spiritualism, 
 table-rapping, table-turning, etc.; and De Morgan wrote a 
 preface in which he said that he knew some of the asserted 
 facts, believed others on testimony, but did not pretend to know 
 whether they were caused by spirits, or had some unknown 
 and unimagined origin. From this alternative he left out ordi- 
 nary material causes. Faraday delivered a lecture on Spirit- 
 ualism, in which he laid it down that in the investigation we 
 ought to set out with the idea of what is physically possible, 
 or impossible; De Morgan could not understand this. 
 
SIR WILLIAM ROWAN HAMILTON* 
 
 (1805-1865) 
 
 William Rowan Hamilton was born in Dublin, Ireland, 
 on the 3d of August, 1805. His father, Archibald Hamilton, 
 was a solicitor in the city of Dublin; his mother, Sarah Hutton, 
 belonged to an intellectual family, but she did not live to exer- 
 cise much influence on the education of her son. There has 
 been some dispute as to how far Ireland can claim Hamilton; 
 Professor Tait of Edinburgh in the Encyclopaedia Brittanica 
 claims him as a Scotsman, while his biographer, the Rev. Charles 
 Graves, claims him as essentially Irish. The facts appear to 
 be as follows: His father's mother was a Scotch woman; his 
 father's father was a citizen of Dublin. But the name "Hamil- 
 ton" points to Scottish origin, and Hamilton himself said that his 
 family claimed to have come over from Scotland in the time 
 of James I. Hamilton always considered himself an Irishman; 
 and as Burns very early had an ambition to achieve something 
 for the renown of Scotland, so Hamilton in his early years had 
 a powerful ambition to do something for the renown of Ireland. 
 In later life he used to say that at the beginning of the century 
 people read French mathematics, but that at the end of it they 
 would be reading Irish mathematics. 
 
 Hamilton, when three years of age, was placed in the charge 
 of his uncle, the Rev. James Hamilton, who was the curate of 
 Trim, a country town, about twenty miles from Dublin, and 
 who was also the master of the Church of England school. 
 From his uncle he received all his primary and secondary edu- 
 cation and also instruction in Oriental languages. As a child 
 Hamilton was a prodigy; at three years of age he was a superior 
 reader of English and considerably advanced in arithmetic; 
 
 * This Lecture was delivered April 16, 1901. — Editors. 
 34 
 
SIR WILLIAM ROWAN HAMILTON 35' 
 
 at four a good geographer; at five able to read and translate 
 Latin, Greek, and Hebrew, and liked to recite Dryden, Collins, 
 Milton and Homer; at eight a reader of Italian and French 
 and giving vent to his feelings in extemporized Latin; at ten 
 a student of Arabic and Sanscrit. When twelve years old he 
 met Zerah Colburn, the American calculating boy, and engaged 
 with him in trials of arithmetical skill, in which trials Hamilton 
 came off with honor, although Colburn was generally the victor. 
 These encounters gave Hamilton a decided taste for arithmetical 
 computation, and for many years afterwards he loved to perform 
 long operations in arithmetic in his mind, extracting the square 
 and cube root, and solving problems that related to the proper- 
 ties of numbers. When thirteen he received his initiation into 
 algebra from Clairault's Algebra in the French, and he made 
 an epitome, which he ambitiously entitled " A Compendious 
 Treatise on Algebra by William Hamilton." 
 
 When Hamilton was fourteen years old, his father died and 
 left his children slenderly provided for. Henceforth, as the elder 
 brother of three sisters, Hamilton had to act as a man. This 
 year he addressed a letter of welcome, written in the Persian 
 language, to the Persian Ambassador then on a visit to Dublin; 
 and he met again Zerah Colburn. In the interval Zerah had 
 attended one of the great public schools of England. Hamilton 
 had been at a country school in Ireland, and was now able to 
 make a successful investigation of the methods by which Zerah 
 made his lightning calculations. When sixteen, Hamilton 
 studied the Differential Calculus by the help of a French text- 
 book, and began the study of the Mecanique celeste of Laplace, 
 and he was able at the beginning of this study to detect a flaw 
 in the reasoning by which Laplace demonstrates the theorem of 
 the parallelogram of forces. This criticism brought him to the 
 notice of Dr. Brinkley, who was then the professor of astronomy 
 in the University of Dublin, and resided at Dunkirk, about 
 five miles from the centre of the city. He also began an inves- 
 tigation for himself of equations which represent systems of 
 straight lines in a plane, and in so doing hit upon ideas which 
 he afterwards developed into his first mathematical memoir to 
 
36 TEN BRITISH MATHEMATICIANS 
 
 the Royal Irish Academy. Dr. Brinkley is said to have 
 remarked of him at this time : " This young man, I do not 
 say will be, but is, the first mathematician of his age." 
 
 At the age of eighteen Hamilton entered Trinity College, 
 Dublin, the University of Dublin founded by Queen Elizabeth, 
 and differing from the Universities of Oxford and Cambridge 
 in having only one college. Unlike Oxford, which has always 
 given prominence to classics, and Cambridge, which has always 
 given prominence to mathematics, Dublin at that time gave 
 equal prominence to classics and to mathematics. In his first 
 year Hamilton won the very rare honor of optime at his exami- 
 nation in Homer. In the old Universities marks used to be and 
 in some cases still are published, descending not in percentages 
 but by means of the scale of Latin adjectives : optime, valdebene, 
 bene, satis, mediocriter , vix medi, non; optime means passed 
 with the very highest distinction; vix means passed but with 
 great difiiculty. This scale is still in use in the medical exami- 
 nations of the University of Edinburgh. Before entering col- 
 lege Hamilton had been accustomed to translate Homer into 
 blank verse, comparing his result with the translations of Pope 
 and Cowper; and he had already produced some original 
 poems. In this, his first year he wrote a poem " On college 
 ambition " which is a fair specimen of his poetical attainments. 
 
 Oh ! Ambition hath its hour 
 
 Of deep and spirit-stirring power; 
 
 Not in the tented field alone, 
 
 Nor peer-engirded court and throne; 
 
 Nor the intrigues of busy life ; 
 
 But ardent Boyhood's generous strife, 
 
 While yet the Enthusiast spirit turns 
 
 Where'er the light of Glory burns, 
 
 Thinks not how transient is the blaze, 
 
 But longs to barter Life for Praise. 
 
 Look round the arena, and ye spy 
 Pallid cheek and faded eye ; 
 Among the bands of rivals, few 
 Keep their native healthy hue: 
 Night and thought have stolen away 
 
SIR WILLIAM ROWAN HAMILTON 37 
 
 Their once elastic spirit's play. 
 A few short hours and all is o'er, 
 Some shall win one triumph more; 
 Some from the place of contest go 
 Again defeated, sad and slow. 
 
 What shall reward the conqueror then 
 
 For all his toU, for all his pain. 
 
 For every midnight throb that stole 
 
 So often o'er his fevered soul? 
 
 Is it the applaudings loud 
 
 Or wond'ring gazes of the crowd; 
 
 Disappointed envy's shame, 
 
 Or hollow voice of fickle Fame? 
 
 These may extort the sudden smile, 
 
 May swell the heart a little while; 
 
 But they leave no joy behind, 
 
 Breathe no pure transport o'er the mind, 
 
 Nor will the thought of selfish gladness 
 
 Expand the brow of secret sadness. 
 
 Yet if Ambition hath its hour 
 Of deep and spirit-stirring power. 
 Some bright rewards are all its own, 
 And bless its votaries alone: 
 The anxious friend's approving eye; 
 The generous rivals' sympathy; 
 And that best and sweetest prize 
 Given by silent Beauty's eyes! 
 These are transports true and strong, 
 Deeply felt, remembered long: 
 Time and sorrow passing o'er 
 Endear their memory but the more. 
 
 The "silent Beauty" was not an abstraction, but a young 
 lady whose brothers were fellow-students of Trinity College. 
 This led to much effusion of poetry; but unfortunately while 
 Hamilton was writing poetry about her another young man 
 was talking prose to her ; with the result that Hamilton experi- 
 enced a disappointment. On account of his self-consciousness, 
 inseparable probably from his genius, he felt the disappointment 
 keenly. He was then known to the professor of astronomy, 
 and walking from the College to the Observatory along the Royal 
 
38 TEN BRITISH MATHEMATICIANS 
 
 Canal, he was actually tempted to terminate his life in the 
 water. 
 
 In his second year he formed the plan of reading so as 
 to compete for the highest honors both in classics and in 
 mathematics. At graduation two gold medals were awarded, 
 the one for distinction in classics, the other for distinction in 
 mathematics. Hamilton aimed at carrying off both. In his 
 junior year he received an optime in mathematical physics; 
 and, as the winner"of two optimes, the one in classics, the other 
 in mathematics, he immediately became a celebrity in the intel- 
 lectual circle of Dublin. 
 
 In his senior year he presented to the Royal Irish Academy 
 a memoir embodying his research on systems of lines. He now 
 called it a "Theory of Systems of Rays " and it was printed 
 in the Transactions. About this time Dr. Brinkley was ap- 
 pointed to the bishopric of Cloyne, and in consequence resigned 
 the professorship of astronomy. In the United Kingdom it is 
 customary when a post becomes vacant for aspirants to lodge 
 a formal application with the appointing board and to sup- 
 plement their own application by testimonial letters from com- 
 petent authorities. In the present case quite a number of can- 
 didates appeared, among them Airy, who afterwards became 
 Astronomer Royal of England, and several Fellows of Trinity 
 College, Dublin. Hamilton did not become a formal candidate, 
 but he was invited to apply, with the result that he received 
 the appointment while still an undergraduate, and not twenty- 
 two years of age. Thus was his undergraduate career signalized 
 much more than by the carrying off of the two gold medals. 
 Before assuming the duties of his chair he made a tour through 
 England and Scotland, and met for the first time the poet 
 Wordsworth at his home at Rydal Mount, in Cumberland. 
 They had a midnight walk, oscillating backwards and forwards 
 between Rydal and Ambleside, absorbed in converse on high 
 themes, and finding it almost impossible to part. Wordsworth 
 afterwards said that Coleridge and Hamilton were the two 
 most wonderful men, taking all their endowments together, 
 that he had ever met. 
 
SIR WILLIAM ROWAN HAMILTON 39 
 
 In October, 1827, he came to reside at the place which was 
 destined to be the scene of his scientific labors. I had the 
 pleasure of visiting it last summer as the guest of his successor. 
 The Observatory is situated on the top of a hill, Dunsink, about 
 five miles from Dublin. The house adjoins the observatory; 
 to the east is an extensive lawn ; to the west a garden with stone 
 wall and shaded walks; to the south a terraced field ; at the foot 
 of the hill is the Royal Canal; to the southeast the city of 
 Dublin; while the view is bounded by the sea and the Dublin 
 and Wicklow Moim tains ; a fine home for a poet or a philosopher 
 or a mathematician, and in Hamilton all three were combined. 
 
 Settled at the Observatory he started out diligently as an 
 observer, but he found it difficult to stand the low temperatures 
 incident to the work. He never attained skill as an observer, 
 and unfortunately he depended on a very poor assistant. Him- 
 self a brilliant computer, with a good observer for assistant, 
 the work of the observatory ought to have flourished. One of 
 the first distinguished visitors at the Observatory was the poet 
 Wordsworth, in commemoration of which one of the shaded 
 walks in the garden was named Wordsworth's walk. Words- 
 worth advised him to concentrate his powers on science; and, 
 not long after, wrote him as follows: " You send me showers 
 of verses which I receive with much pleasure, as do we all : yet 
 have we fears that this employment may seduce you from the 
 path of science which you seem destined to tread with so much 
 honor to yourself and profit to others. Again and again I must 
 repeat that the composition of verse is infinitely more of an 
 art than men are prepared to believe, and absolute success in 
 it depends upon innumerable minulicB which it grieves me you 
 should stoop to acquire a knowledge of. . . Again I do venture 
 to submit to your consideration, whether the poetical parts of 
 your nature would not find a field more favorable to their 
 exercise in the regions of prose; not because those regions are 
 humbler, but because they may be gracefully and profitably 
 trod, with footsteps less careful and in measures less elaborate." 
 
 Hamilton possessed the poetic imagination; what he was 
 deficient in was the technique of the poet. The imagination 
 
40 TEN BRITISH MATHEMATICIANS 
 
 of the poet is kin to the imagmation of the mathematician; 
 both extract the ideal from a mass of circumstances. In this 
 connection De Morgan wrote: " The moving power of mathe- 
 tical invention is not reasoning but imagination. We no longer 
 apply the homely term maker in hteral translation of poet; but 
 discoverers of all kinds, whatever may be their lines, are makers, 
 or, as we now say, have the creative genius." Hamilton spoke 
 of the Mecanique analytique of Lagrange as a "scientific poem"; 
 Hamilton himself was styled the Irish Lagrange. Engineers 
 venerate Rankine, electricians venerate Maxwell; both were 
 scientific discoverers and likewise poets, thatjs, amateur poets. 
 The proximate cause of the shower of verses was that Hamilton 
 had fallen in love for the second time. The young lady was 
 Miss de Vere, daughter of an accomplished Irish baronet, and 
 who like Tennyson's Lady Clara Vere de Vere could look back 
 on a long and illustrious descent. Hamilton had a pupil in 
 Lord Adare, the eldest son of the Earl of Dunraven, and it was 
 while visiting Adare Manor that he was introduced to the De 
 Vere family, who lived near by at Curragh Chase. His suit 
 was encouraged by the Countess of Dunraven, it was favorably 
 received by both father and mother, he had written many sonnets 
 of which Ellen de Vere was the inspiration, he had discussed 
 with her astronomy, poetry and philosophy; and was on the 
 eve of proposing when he gave up because the young lady inci- 
 dentally said to him that "she could not hve happily anywhere 
 but at Curragh." His action shows the working of a too self- 
 conscious mind, proud of his own intellectual achievements, 
 and too much awed by her long descent. So he failed for the 
 second time; but both of these ladies were friends of his to the 
 last. 
 
 At the age of 27 he contributed to the Irish Academy a 
 supplementary paper on his Theory of Systems of Rays, in which 
 he predicted the phenomenon of conical refraction; namely, 
 that under certain conditions a single ray incident on a biaxial 
 crystal would be broken up into a cone of rays, and likewise 
 that under certain conditions a single emergent ray would 
 appear as a cone of rays. The prediction was made by Hamilton 
 
SIR WILLIAM ROWAN HAMILTON 41 
 
 on Oct. 22nd; it was experimentally verified by his colleague 
 Prof. Lloyd on Dec. 14th. It is not experiment alone or 
 mathematical reasoning alone which has built up the splendid 
 temple of physical science, but the two working together; and 
 of this we have a notable exemplification in the discovery of 
 conical refraction. 
 
 Twice Hamilton chose well but failed ; now he made another 
 choice and succeeded. The lady was a Miss Bayly, who 
 visited at the home of her sister near Dunsink hill. The lady 
 had serious misgivings about the state of her health; but the 
 marriage took place. The kind of wife which Hamilton needed 
 was one who could govern him and efficiently supervise all 
 domestic matters; but the wife he chose was, from weakness 
 of body and mind, incapable of doing it. As a consequence, 
 Hamilton worked for the rest of his life under domestic dif- 
 ficulties of no ordinary kind. 
 
 At the age of 28 he made a notable addition to the theory 
 of Dynamics by extending to it the idea of a Characteristic 
 Function, which he had previously applied with success to 
 the science of Optics in his Theory of Systems of Rays. It 
 was contributed to the Royal Society of London, and printed 
 in their Philosophical Transactions. The Royal Society of 
 London is the great scientific society of England, founded 
 in the reign of Charles II, and of which Newton was one of 
 the early presidents; Hamilton was invited to become a fellow 
 but did not accept, as he could not afford the expense. 
 
 At the age of 29 he read a paper before the Royal Irish 
 Academy, which set forth the result of long meditation and 
 investigation on the nature of Algebra as a science; the paper 
 is entitled " Algebra as the Science of Pure Time." The main 
 idea is that as Geometry considered as a science is founded 
 upon the pure intuition of space, so algebra as a science is 
 founded upon the pure intuition of time. He was never satis- 
 fied with Peacock's theory of algebra as a " System of Signs 
 and their Combinations "; nor with De Morgan's improve- 
 ment of it; he demanded a more real foundation. In reading 
 Kant's Critique of Pure Reason he was struck by the follow- 
 
42 TEN BRITISH MATHEMATICIANS 
 
 ing passage: " Time and space are two sources of knowledge 
 from which various a priori synthetical cognitions can be 
 derived. Of this, pure mathematics gives a splendid example 
 in the case of our cognitions of space and its various relations. 
 As they are both pure forms of sensuous intuition, they render 
 synthetical propositions a priori possible." Thus, according 
 to Kant, space and time are forms of the intellect; and Ham- 
 ilton reasoned that, as geometry is the science of the former, 
 so algebra must be the science of the latter. When algebra 
 is based on any unidimensional subject, such as time, or a 
 straight line, a difficulty arises in explaining the roots of a 
 quadratic equation when they are imaginary. To get over 
 this difficulty Hamilton invented a theory of algebraic couplets, 
 which has proved a conundrum in the mathematical world. 
 Some 20 years ago there flourished in Edinburgh a mathematician 
 named Sang who had computed the most elaborate tables 
 of logarithms in existence — which still exist in manuscript. 
 On reading the theory in question he first judged that either 
 Hamilton was crazy, or else that he (Sang) was crazy, but 
 eventually reached the more comforting alternative. On the 
 other hand, Prof. Tait believes in its soundness, and endeavors 
 to bring it down to the ordinary comprehension. 
 
 We have seen that the British Association for the Advance- 
 ment of Science was founded in 1831, and that its first meeting 
 was in the ancient city of York. It was a policy of the founders 
 not to meet in London, but in the provincial cities, so that 
 thereby greater interest in the advance of science might be 
 produced over the whole land. The cities chosen for the place 
 of meeting in following years were the University towns: Ox- 
 ford, Cambridge, Edinburgh, Dublin. Hamilton was the only 
 representative of Ireland present at the Oxford meeting; and 
 at the Oxford, Cambridge, and Edinburgh meetings he not 
 only contributed scientific papers, but he acquired renown 
 as a scientific orator. In the case of the Dublin meeting 
 he was chief organizer beforehand, and chief orator when 
 it met. The week of science was closed by a grand 
 dinner given in the library of Trinity College; and an 
 
SIR WILLIAM ROWAN HAMILTON 43 
 
 incident took place which is thus described by an American 
 scientist : 
 
 " We assembled in the imposing hall of Trinity Library, 
 two hundred and eighty feet long, at six o'clock. When the 
 company was principally assembled, I observed a little stir 
 near the place where I stood, which nobody could explain, 
 and which, in fact, was not comprehended by more than two 
 or three persons present. In a moment, however, I perceived 
 myself standing near the Lord Lieutenant and his suite, in 
 front of whom a space had been cleared, and by whom was 
 Professor Hamilton, looking very much embarrassed. The 
 Lord Lieutenant then called him by name, and he stepped 
 into the vacant space. ' I am,' said his Excellency, ' about 
 to exercise a prerogative of royalty, and it gives me great 
 pleasure to do it, on this splendid pubKc occasion, which has 
 brought together so many distinguished men from all parts 
 of the empire, and from all parts even of the world where 
 science is held in honor. But, in exercising it. Professor Ham- 
 ilton, I do not confer a distinction. I but set the royal, and 
 therefore the national mark on a distinction already acquired 
 by your genius and labors.' He went on in this way for 
 three of four minutes, his voice very fine, rich and full; his 
 manner as graceful and dignified as possible; and his language 
 and allusions appropriate and combined into very ample flow- 
 ing sentences. Then, receiving the State sword from one of 
 his attendants, he said, ' Kneel down. Professor Hamilton '; 
 and laying the blade gracefully and gently first on one shoulder, 
 and then on the other, he said, ' Rise up, Sir William Rowan 
 Hamilton.' The Knight rose, and the Lord Lieutenant then 
 went up, and with an appearance of great tact in his manner, 
 shook hands with him. No reply was made. The whole 
 scene was imposing, rendered so, partly by the ceremony itself, 
 but more by the place in which it passed, by the body of very 
 distinguished men who were assembled there, and especially 
 by the extraordinarily dignified and beautiful manner in which 
 it was performed by the Lord Lieutenant. The effect at the 
 time was great, and the general impression was that, as the 
 
44 TEN BRITISH MATHEMATICIANS 
 
 honor was certainly merited by him who received it, so the 
 words by which it was conferred were so graceful and appro- 
 priate that they constituted a distinction by themselves, greater 
 than the distinction of knighthood. I was afterwards told 
 that this was the first instance in which a person had been 
 knighted by a Lord Lieutenant either for scientific or literary 
 merit." 
 
 Two years after another great honor came to Hamilton 
 — the presidency of the Royal Irish Academy. While holding 
 this office, in the year 1843, when 38 years old, he made the 
 discovery which will ever be considered his highest title to 
 fame. The story of the discovery is told by Hamilton him- 
 self in a letter to his son: " On the i6th day of October, which 
 happened to be a Monday, and Council day of the Royal 
 Irish Academy, I was walking in to attend and preside, and 
 your mother was walking with me along the Royal Canal, 
 to which she had perhaps driven ; and although she talked with 
 me now and then, yet an undercurrent of thought was going 
 on in my mind, which gave at last a result, whereof it is not 
 too much to say that I felt at once the importance. An electric 
 circuit seemed to close; and a spark flashed forth, the herald 
 (as I foresaw immediately) of many long years to come of 
 definitely directed thought and work, by myself if spared, and 
 at all events on the part of others, if I should even be allowed 
 to live long enough distinctly to communicate the discovery. 
 Nor could I resist the impulse — unphilosophical as it may 
 have been — to cut with a knife on a stone of Brougham Bridge, 
 as we passed it, the fundamental formula with the symbols 
 i,j, k; namely, 
 
 which contains the solution of the problem, but of course as 
 an inscription has long since mouldered away. A more durable 
 notice remains, however, in the Council Book of the Academy 
 for that day, which records the fact that I then asked for and 
 obtained leave to read a paper on Quaternions, at the first 
 general meeting of the session, which reading took place accord- 
 ingly on Monday the 13th of November following." 
 
SIR WILLIAM ROWAN HAMILTON 45 
 
 Last summer Prof. Joly and I took the walk here described. 
 We started from the Observatory, walked down the terraced 
 field, then along the path by the side of the Royal Canal 
 towards Dublin until we came to the second bridge spanning 
 the canal. The path of course goes under the Bridge, and 
 the inner side of the Bridge presents a very convenient surface 
 for an inscription. I have seen this incident quoted as an 
 example of how a genius strikes on a discovery all of a sudden. 
 No doubt a problem was solved then and there, but the problem 
 had engaged Hamilton's thoughts and researches for fifteen 
 years. It is rather an illustration of how genius is patience, 
 or a faculty for infinite labor. What was Hamilton struggling 
 to do all these years? To emerge from Flatland into Space; 
 in other words, Algebra had been extended so as to apply to 
 lines in a plane ; but no one had been able to extend it so as to 
 apply to lines in space. The greatness of the feat is made 
 evident by the fact that most analysts are still crawling in 
 Flatland. The same year in which he discovered Quaternions 
 the Government granted him a pension of £200 per annum 
 for life, on account of his scientific work. 
 
 We have seen how Hamilton gained two optimes, one in clas- 
 sics, the other in physics, the highest possible distinction in his 
 college course; how he was appointed professor of astronomy 
 while yet an undergraduate ; how he was a scientific chief in the 
 British Association at 27; how he was knighted for his scientific 
 achievements at 30; how he was appointed president of the 
 Royal Irish Academy at 32; how he discovered Quaternions 
 and received a Government pension at 38; can you imagine 
 that this brilliant and successful genius would fall a victim to 
 intemperance? About this time at a dinner of a scientific society 
 in Dublin he lost control of himself, and was so mortified that, 
 on the advice of friends he resolved to abstain totally. This 
 resolution he kept for two years; when happening to be a 
 member of a scientific party at the castle of Lord Rosse, an 
 amateur astronomer then the possessor of the largest telescope 
 in existence, he was taunted for sticking to water, particularly 
 by Airy the Greenwich astronomer. He broke his good reso- 
 
46 TEN BRITISH MATHEMATICIANS 
 
 lution, and from that time forward the craving for alcoholic 
 stimulants clung to him. How could Hamilton with all his 
 noble aspirations fall into such a vice? The explanation lay 
 in the want of order which reigned in his home. He had no 
 regular times for his meals; frequently had no regular meals 
 at all, but resorted to the sideboard when hunger compelled 
 him. What more natural in such condition than that he should 
 refresh himself with a quaff of that beverage for which Dublin 
 is famous — porter labelled X^? After Hamilton's death the 
 dining-room was found covered with huge piles of manuscript, 
 with convenient walks between the piles; when these literary 
 remains were wheeled out and examined, china plates with the 
 relics of food upon them were found between the sheets of 
 manuscript, plates sufficient in number to furnish a kitchen. 
 He used to carry on, says his eldest son, long trains of algebraical 
 and arithmetical calculations in his mind, during which he was 
 unconscious of the earthly necessity of eating; "we used to bring 
 in a ' snack ' and leave it in his study, but a brief nod of 
 recognition of the intrusion of the chop or cutlet was often the 
 only result, and his thoughts went on soaring upwards." 
 
 In 1845 Hamilton attended the second Cambridge meeting 
 of the British Association ; and after the meeting he was lodged 
 for a week in the rooms in Trinity College which tradition 
 points out as those in which Sir Isaac Newton composed the 
 Principia. This incident was intended as a compliment and it 
 seems to have impressed Hamilton powerfully. He came back 
 to the Observatory with the fixed purpose of preparing a work 
 on Quaternions which might not unworthily compare with the 
 Principia of Newton, and in order to obtain more leisure for this 
 undertaking he resigned the office of president of the Royal 
 Irish Academy. He first of all set himself to the preparation 
 of a course of lectures on Quaternions, which were delivered in 
 Trinity College, Dublin, in 1848, and were six in number. Among 
 his hearers were George Salmon, now well known for his highly 
 successful series of manuals on Analytical Geometry; and Arthur 
 Cayley, then a Fellow of Trinity College, Cambridge. These 
 lectures were afterward expanded and published in 1853, under 
 
SIR WILLIAM 'ROWAN HAMILTON 47 
 
 the title of Lectures on Quaternions, at the expense of Trinity 
 College, Dublin. Hamilton had never had much experience 
 as a teacher; the volume was criticised for diffuseness of style, 
 and certainly Hamilton sometimes forgot the expositor in the 
 orator. The book was a paradox — a sound paradox, and of 
 his experience as a paradoxer Hamilton wrote: "It required a 
 certain capital of scientific reputation, amassed in former years, 
 to make it other than dangerously imprudent to hazard the 
 pubhcation of a work which has, although at bottom quite 
 conservative, a highly revolutionary air. It was part of the 
 ordeal through which I had to pass, an episode in the battle 
 of life, to know that even candid and friendly people secretly 
 or, as it might happen, openly, censured or 
 ridiculed me, for what appeared to them 
 my monstrous innovations." One of these 
 monstrous innovations was the principle that 
 ij is not =ji but = —ji; the truth of which 
 is evident from the diagram. Critics said 
 that he held that 3X4 is not =4X3; which proceeds on the 
 assumption that only numbers can be represented by letter 
 symbols. 
 
 Soon after the publication of the Lectures, he became aware 
 of its imperfection as a manual of instruction, and he set him- 
 self to prepare a second book on the model of Euclid's Elements. 
 He estimated that it would fill 400 pages and take two years 
 to prepare; it amounted to nearly 800 closely printed pages 
 and took seven years. At times he would work for twelve 
 hours on a stretch; and he also suffered from anxiety as to the 
 means of pubhcation. Trinity College advanced £200, he paid 
 £50 out of his own pocket, but when illness came upon him the 
 expense of paper and printing had mounted up to £400. He 
 was seized by an acute attack of gout, from which, after 
 several months of suffering, he died on Sept. 2, 1865, in the 
 6ist year of his age. 
 
 It is pleasant to know that this great mathematician received 
 during his last illness an honor from the United States, which 
 made him feel that he had realized the aim of his great labors. 
 
48 TEN BRITISH MATHEMATICIANS 
 
 While the war between the North and South was in progress, 
 the National Academy of Sciences was founded, and the news 
 which came to Hamilton was that he had been elected one of 
 ten foreign members, and that his name had been voted to 
 occupy the specially honorable position of first on the list. Sir 
 WilKam Rowan Hamilton was thus the first foreign associate 
 of the National Academy of Sciences of the United States. 
 
 As regards religion Hamilton was deeply reverential in 
 nature. He was born and brought up in the Church of England, 
 which was then the established Church in Ireland. He lived 
 in the time of the Oxford movement, and for some time he 
 sympathized with it; but when several of his friends, among 
 them the brother of Miss De Vere, passed over into the Roman 
 Catholic Church, he modified his opinion of the movement and 
 remained Protestant to the end. 
 
 The immense intellectual activity of Hamilton, especially dur- 
 ing the years when he was engaged on the enormous labor of 
 writing the Elements of Quaternions, made him a recluse, and 
 necessarily took away from his power of attending to the prac- 
 tical affairs of life. Some said that however great a master of 
 pure time he might be he was not a master of sublunary time. 
 His neighbors also took advantage of his goodness of heart. 
 Surrounding the house there is an extensive lawn affording good 
 pasture, and on it Hamilton pastured a cow. A neighbor advised 
 Hamilton that his cow would be much better contented by 
 having another cow for company and bargained with Hamilton 
 to furnish the companion provided Hamilton paid something 
 like a dollar per month. 
 
 Here is Hamilton's own estimate of himself. " I have 
 very long admired Ptolemy's description of his great astronomical 
 master, Hipparchus, as iv-qp <^iA.o7rovos koI ^tXaXjy^ijs; a labor- 
 loving and truth-loving man. Be such my epitaph." 
 
 Hamilton's family consisted of two sons and one daughter. 
 At the time of his death, the Elements of Quaternions was 
 all finished excepting one chapter. His eldest son, William 
 Edwin Hamilton, wrote a preface, and the volume was pub- 
 lished at the expense of Trinity College, Dublin. Only 500 
 
SIR WILLIAM ROWAN HAMILTON 49 
 
 copies were printed, and many of those were presented. In 
 consequence it soon became a scarce book, and as much as 
 $35.00 has been paid for a copy. A new edition, in two volumes, 
 is now being published by Prof. Joly, his successor in Dunsink 
 Observatory. 
 
GEORGE BOOLE* 
 
 (181S-1864) 
 
 George Boole was born at Lincoln, England, on the 2d 
 of November, 1815. His father, a tradesman of very limited 
 means, was attached to the pursuit of science, particularly 
 of mathematics, and was skilled in the construction of optical 
 instruments. Boole received his elementary education at the 
 National School of the city, and afterwards at a commercial 
 school ; but it was his father who instructed him in the elements 
 of mathematics, and also gave him a taste for the construction 
 and adaptation of optical instruments. However, his early 
 ambition did not urge him to the further prosecution of mathe- 
 mathical studies, but rather to becoming proficient in the 
 ancient classical languages. In this direction he could receive no 
 help from his father, but to a friendly bookseller of the neigh- 
 borhood he was indebted for instruction in the rudiments of 
 the Latin Grammar. To the study of Latin he soon added 
 that of Greek without any external assistance; and for some 
 years he perused every Greek or Latin author that came within 
 his reach. At the early age of twelve his proficiency in Latin 
 made him the occasion of a literary controversy in his native 
 city. He produced a metrical translation of an ode of Horace, 
 which his father in the pride of his heart inserted in a local 
 journal, stating the age of the translator. A neighboring 
 school-master wrote a letter to the journal in which he denied, 
 from internal evidence, that the version could have been the 
 work of one so young. In his early thirst for knowledge of 
 languages and ambition to excel in verse he was like Hamilton, 
 but poor Boole was much more heavily oppressed by the res 
 angusta domi — the hard conditions of his home. Accident 
 
 * This Lecture was delivered April 19, 1901. — Editors. 
 CO 
 
GEORGE BOOLE 51 
 
 discovered to him certain defects in his methods of classical 
 study, inseparable from the want of proper early training, and 
 it cost him two years of incessant labor to correct them. 
 
 Between the ages of sixteen and twenty he taught school 
 as an assistant teacher, first at Doncaster in Yorkshire, after- 
 wards at Waddington near Lincoln; and the leisure of these 
 years he devoted mainly to the study of the principal modern 
 languages, and of patristic Kterature with the view of studying 
 to take orders in the Church. This design, however, was not 
 carried out, owing to the financial circumstances of his parents 
 and some other difficulties. In his twentieth year he de- 
 cided on opening a school on his own account in his native 
 city; thenceforth he devoted all the leisure he could com- 
 mand to the study of the higher mathematics, and solely with 
 the aid of such books as he could procure. Without other 
 assistance or guide he worked his way onward, and it was his 
 own opinion that he had lost five years of educational progress 
 by his imperfect methods of study, and the want of a helping 
 hand to get him over difficulties. No doubt it cost him much 
 time; but when he had finished studying he was already not 
 only learned but an experienced investigator. 
 
 We have seen that at this time (1835) the great masters 
 of mathematical analysis wrote in the French language; and 
 Boole was naturally led to the study of the Mecanique celeste 
 of Laplace, and the Mecanique analytique of Lagrange. While 
 studying the latter work he made notes from which there 
 eventually emerged his first mathematical memoir, entitled, 
 " On certain theorems in the calculus of variations." By the 
 same works his attention was attracted to the transformation 
 of homogeneous functions by linear substitu ions, and in the 
 course of his subsequent investigations he was led to results 
 which are now regarded as the foundation of the modern 
 Higher Algebra. In the publication of his results he received 
 friendly assistance from D. F. Gregory, a younger member of 
 the Cambridge school, and editor of the newly founded Cam- 
 bridge Mathematical Journal. Gregory and other friends sug- 
 gested that Boole should take the regular mathematical course 
 
52 TEN BRITISH MATHEMATICIANS 
 
 at Cambridge, but this he was unable to do; he continued to 
 teach school for his own support and that of his aged parents, 
 and to cultivate mathematical analysis in the leisure left by 
 a laborious occupation. 
 
 Duncan F. Gregory was one of a Scottish family already 
 distinguished in the annals of science. His grandfather was 
 James Gregory, the inventor of the refracting telescope and 
 discoverer of a convergent series for r. A cousin of his father 
 was David Gregory, a special friend and fellow worker of Sir 
 Isaac Newton. D. F. Gregory graduated at Cambridge, and 
 after graduation he immediately turned his attention to the 
 logical foundations of analysis. He had before him Peacock's 
 theory of algebra, and he knew that in the analysis as devel- 
 oped by the French school there were many remarkable phe- 
 nomena awaiting explana on; particularly theorems which 
 involved what was cal ed the separation of symbols. He 
 embodied his results in a paper " On the real Nature of sym- 
 bolical Algebra " which was printed in the Transactions of 
 the Royal Society of Edinburgh. 
 
 Boole became a master of the method of separation of 
 symbols, and by attempting to apply it to the solution of 
 differential equations with variable coefficients was led to devise 
 a general method in analysis. The account of it was printed 
 in the Transactions of the Royal Society of London, and brought 
 its author a Royal medal. Boole's study of the separation 
 of symbols naturally led him to a study of the foundations 
 of analysis, and he had before him the writings of Peacock, 
 Gregory and De Morgan. He was led to entertain very wide 
 views of the domain of mathematical analysis; in fact that it 
 was coextensive with exact analysis, and so embraced formal 
 logic. In 1848, as we have seen, the controversy arose be- 
 tween Hamilton and De Morgan about the quantification of 
 terms; the general interest which that controversy awoke in 
 the relation of mathematics to logic induced Boole to prepare 
 for publication his views on the subject, which he did that 
 same year in a small volume entitled Mathematical Analysis 
 of Logic. 
 
GEORGE BOOLE 53 
 
 About this time what are denominated the Queen's Colleges 
 of Ireland were instituted at Belfast, Cork and Galway; and 
 in 1849 Boole was appointed to the chair of mathematics in 
 the Queen's College at Cork. In this more suitable environ- 
 ment he set himself to the preparation of a more elaborate 
 work on the mathematical analysis of logic. For this pur- 
 pose he read extensively books on psychology and logic, and 
 as a result published in 1854 the work on which his fame 
 chiefly rests — " An Investigation of the Laws of Thought, on 
 which are founded the mathematical theories of logic and 
 probabilities." Subsequently he prepared textbooks on Dif- 
 ferential Equations and Finite Differences; the former of which 
 remained the best English textbook on its subject until the 
 publication of Forsyth's Differential Equations. 
 
 Prefixed to the Laws of Thought is a dedication to Dr. 
 Ryall, Vice-President and Professor of Greek in the same 
 College. In the following year, perhaps as a result of the ded- 
 ication, he married Miss Everest, the niece of that colleague. 
 Honors came: Dublin University made him an LL.D., Oxford 
 a D.C.L.; and the Royal Society of London elected him a 
 Fellow. But Boole's career was cut short in the midst of his 
 usefulness and scientific labors. One day in 1864 he walked 
 from his residence to the College, a distance of two miles, in 
 a drenching rain, and lectured in wet clothes. The result 
 was a feverish cold which soon fell upon his lungs and terminated 
 his career on December 8, 1864, in the 50th year of his age. 
 
 De Morgan was the man best qualified to judge of the value 
 of Boole's work in the field of logic; and he gave it generous 
 praise and help. In writing to the Dublin Hamilton he said, 
 " I shall be glad to see his work {Laws of Thought) out, for 
 he has, I think, got hold of the true connection of algebra and 
 logic." At another time he wrote to the same as follows: 
 " Ail metaphysicians except you and I and Boole consider 
 mathematics as four books of Euclid and algebra up to quad- 
 ratic equations." We might infer that these three contem- 
 porary mathematicians who were likewise philosophers would 
 form a triangle of friends. But it was not so; Hamilton was 
 
54 ' TEN BRITISH MATHEMATICIANS 
 
 a friend of De Morgan, and De Morgan a friend of Boole; 
 but the relation of friend, although convertible, is not neces- 
 sarily transitive. Hamilton met De Morgan only once in his 
 life, Boole on the other hand with comparative frequency; 
 yet he had a voluminous correspondence with the former 
 extending over 20 years, but almost no correspondence with 
 the latter. De Morgan's investigations of double algebra and 
 triple algebra prepared him to appreciate the quaternions, 
 whereas Boole was too much given over to the symbolic theory 
 to appreciate geometric algebra. 
 
 Hamilton's biography has appeared in three volumes, pre- 
 pared by his friend Rev. Charles Graves ; De Morgan's biography 
 has appeared in one volume, prepared by his widow; of Boole 
 no biography has appeared. A biographical notice of Boole 
 was written for the Proceedings of the Royal Society of London 
 by his friend the Rev. Robert Harley, and it is to it that I 
 am indebted for most of my biographical data. Last summer 
 when in England I learned that the reason why no adequate 
 biography of Boole had appeared was the unfortunate temper 
 and lack of sound judgment of his widow. Since her hus- 
 band's death Mrs. Boole has published a paradoxical book 
 of the false kind worthy of a notice in De Morgan's Budget. 
 
 The work done by Boole in applying mathematical analysis 
 to logic necessarily led him to consider the general question 
 of how reasoning is accomplished by means of symbols. The 
 view which he adopted on this point is stated at page 68 of the 
 Laws of Thought. " The conditions of valid reasoning by the 
 cid of symbols, are : First, that a fixed interpretation be assigned 
 to the symbols employed in the expression of the data; and 
 that the laws of the combination of those symbols be correctly 
 determined from that interpretation; Second, that the formal 
 processes of solution or demonstration be conducted throughout 
 in obedience to all the laws determined as above, without 
 regard to the question of the interpretability of the particular 
 results obtained; Third, that the final result be interpretable 
 in form, and that it be actually interpreted in accordance 
 with that system of interpretation which has been employed 
 
GEORGE BOOLE 55 
 
 in the expression of the data." As regards these conditions 
 it may be observed that they are very different from the for- 
 malist view of Peacock and De Morgan, and that they incline 
 towards a realistic view of analysis, as held by Hamilton. True 
 he speaks of interpretation instead of meaning, but it is a 
 fixed interpretation; and the rules for the processes of solution 
 are not to be chosen arbitrarily, but are to be found out from 
 the particular system of interpretation of the symbols. 
 
 It is Boole's second condition which chiefly calls for study 
 and examination; respecting it he observes as follows: "The 
 principle in question may be considered as resting upon a gen- 
 eral law of the mind, the knowledge of which is not given to 
 us a priori, that is, antecedently to experience, but is derived, 
 like the knowledge of the other laws of the mind, from the 
 clear manifestation of the general principle in the particular 
 mstance. A single example of reasoning, in which symbols 
 are employed in obedience to laws founded upon their inter- 
 pretation, but without any sustained reference to that inter- 
 pretation, the chain of demonstration conducting us through 
 intermediate steps which are not interpretable to a final result 
 which is interpretable, seems not only to establish the validity 
 of the particular application, but to make known to us the 
 general law manifested therein. No accumulation of instances 
 can properly add weight to such evidence. It may furnish 
 us with clearer conceptions of that common element of truth 
 upon which the application of the principle depends, and so 
 prepare the way for its reception. It may, where the imme- 
 diate force of the evidence is not felt, serve as a verification, 
 a posteriori, of the practical validity of the principle in ques- 
 tion. But this does not affect the position affirmed, viz., that 
 the general principle must be seen in the particular instance — 
 seen to be general in application as well as true in the special 
 example. The employment of the uninterpre table symbol Vi — 
 in the intermediate processes of trigonometry furnishes an 
 illustration of what has been said. I apprehend that there is 
 no mode of explaining that application which does not covertly 
 assume the very principle in question. But that principle, 
 
56 TEN BRITISH MATHEMATICIANS 
 
 though not, as I conceive, warranted by formal reasoning 
 based upon other grounds, seems to deserve a place among those 
 axiomatic truths which constitute in some sense the foundation 
 of general knowledge, and which may properly be regarded 
 as expressions of the mind's own laws and constitution." 
 
 We are all familiar with the fact that algebraic reasoning 
 may be conducted through intermediate equations without 
 requiring a sustained reference to the meaning of these equa- 
 tions; but it is paradoxical to say that these equations can, in 
 any case, have no meaning or interpretation. It may not be 
 necessary to consider their meaning, it may even be difficult 
 to find their meaning, but that they have a meaning is a dic- 
 tate of common sense. It is entirely paradoxical to say that, 
 as a general process, we can start from equations having a 
 meaning, and arrive at equations having a meaning by passing 
 through equations which have no meaning. The particular 
 instance in which Boole sees the truth of the paradoxical prin- 
 ciple is the successful employment of the uninterpretable sym- 
 bol V — I in the intermediate processes of trigonometry. So 
 soon then as this symbol is interpreted, or rather, so soon as 
 its meaning is demonstrated, the evidence for the principle 
 fails, and Boole's transcendental logic falls. 
 
 In the algebra of quantity we start from elementary symbols 
 denoting numbers, but are soon led to compound forms which 
 do not reduce to numbers; so in the algebra of logic we start 
 from elementary symbols denoting classes, but are soon intro- 
 duced to compound expressions which cannot be reduced to 
 simple classes. IMost mathematical logicians say, Stop, we do 
 not know what this combination means. Boole says. It may 
 be meaningless, go ahead all the same. The design of the Laws 
 of Thought is stated by the author to be to investigate the 
 fundamental laws of those operations of the mind by which 
 reasoning is performed; to give expression to them in the sym- 
 bolical language of a Calculus, and upon this foundation to 
 establish the Science of Logic and construct its method; to 
 make that method itself the basis of a general method for the 
 application of the mathematical doctrine of Probabilities; and, 
 
GEORGE BOOLE 57 
 
 finally to collect from the various elements of truth brought to 
 view in the course of these inquiries some probable intimations 
 concerning the nature and constitution of the human mind. 
 
 Boole's inventory of the symbols required in the algebra of 
 logic is as follows: fi.rst, Literal symbols, as x, y, etc., representing 
 things as subjects of our conceptions; second, Signs of operation, 
 as +, — , X, standing for those operations of the mind by which 
 the conceptions of things are combined or resolved so as to form 
 new conceptions involving the same elements; third, The sign 
 of identity = ; not equahty merely, but identity which involves 
 equality. The symbols x, y, etc., are used to denote classes; 
 and it is one of Boole's maxims that substantives and adjectives 
 alike denote classes. " They may be regarded," he says, " as 
 differing only in this respect, that the former expresses the sub- 
 stantive existence of the individual thing or things to which 
 it refers, the latter impHes that existence. If we attach to the 
 adjective the universally understood subject, " being " or 
 " thing," it becomes virtually a substantive, and may for all the 
 essential purposes of reasoning be replaced by the substantive." 
 Let us then agree to represent the class of individuals to which a 
 particular name is applicable by a single letter as x. If the 
 name is men for instance, let x represent all men, or the class 
 men. Again, if an adjective, as good, is employed as a term of 
 description, let us represent by a letter, as y, all things to which 
 the description good is applicable, that is, all good things or the 
 class good things. Then the combination yx will represent 
 good men. 
 
 Boole's symbolic logic was brought to my notice by Pro- 
 fessor Tait, when I was a student in the physical laboratory of 
 Edinburgh University. I studied the Laws of Thought and I 
 found that those who had written on it regarded the method 
 as highly mysterious; the results wonderful, but the processes 
 obscure. I reduced everything to diagram and model, and I 
 ventured to publish my views on the subject in a small volume 
 called Principles of the Algebra of Logic; one of the chief points 
 I made is the philological and analytical difference between 
 the substantive and the adjective. What I said was that the 
 
58 TEN BRITISH MATHEMATICIANS 
 
 word man denotes a class, but the word white does not; in the 
 former a definite unit-object is specified, in the latter no unit- 
 object is specified. We can exhibit a type of a man, we cannot 
 exhibit a type of a while. 
 
 The identification of the substantive and adjective on 
 the one hand and their discrimination on the ether hand, 
 lead to different conceptions of what De Morgan called the 
 universe. Boole's conception of the Universe is as follows 
 (Laws of Thought, p. 42) : " In every discourse, whether of 
 the mind conversing with its own thoughts, or of the indi- 
 vidual in his intercourse with others, there is an assumed or 
 expressed limit within which the subjects of its operation are 
 confined. The most unfettered discourse is that in which the 
 words we use are understood in the widest possible application, 
 and for them the limits of discourse are coextensive with those 
 of the universe itself. But more usually we confine ourselves 
 to a less spacious field. Sometimes in discoursing of men we 
 imply (without expressing the limitation) that it is of men only 
 under certain circumstances and conditions that we speak, as 
 of civilized men, or of men in the vigor of life, or of men under 
 some other condition or relation. Now, whatever may be the 
 extent of the field within which all the objects of our discourse 
 are found, that field may properly be termed the universe of 
 discourse." 
 
 Another view leads to the conception of the Universe as a 
 collection of homogeneous units, which may be finite or infinite 
 in number; and in a particular problem the mind considers the 
 relation of identity between different groups of this collection. 
 This universe corresponds to the series of events, in the theory 
 of Probability; and the characters correspond to the different 
 ways in which the event may happen. The difference is that 
 the Algebra of Logic considers necessary data and relations; 
 while the theory of Probability considers probable data and 
 relations. I will explain the elements of Boole's method on this 
 theory. 
 
 The square is a collection of points : it may serve to represent 
 any collection of homogeneous units, whether finite or infinite 
 
GEORGE BOOLE 
 
 59 
 
 Fig. t. 
 
 in number, that is, the universe of the problem. Let x denote 
 
 inside the left-hand circle, and y inside the right-hand circle. 
 
 Uxy will denote the points inside both circles 
 
 (Fig. i). In arithmetical value x may range from 
 
 I to o; so also y; while xy cannot be greater than 
 
 X or V, or less than o or x-\-y — i. This last is the 
 
 principle of the syllogism. From the co-ordinate 
 
 nature of the operations x and y, it is evident 
 
 that Uxy = Uyx; but this is a different thing from commuting, 
 
 as Boole does, the relation of U and .r, which is not that of 
 
 co-ordination, but of subordination of x to U, and which is 
 
 properly denoted by writing U first. 
 
 Suppose y to be the same character as x; we will then always 
 have Uxx=Ux; that is, an elementary selective symbol x is 
 always such that .v- = x. These are but the symbols of ordinary 
 algebra which satisfy this relation, namely i and o; these are 
 also the extreme selective symbols all and none. The law in 
 question was considered Boole's paradox; it plays a very great 
 part in the development of his method. 
 
 Let Uxy = Uz, where = means identical with, 
 not equal to; we may write :vy = n, leaving the U 
 to be understood. It does not mean that the 
 combination of characters xy is identical with the 
 character s; but that those points which have the 
 characters .v and y are identical with the points 
 which have the character z (Fig. 2). From .vy = s, we derive 
 
 Fig. 2. 
 
 x = -z\ what is the meaning of this expression? We shall return 
 
 y 
 
 to the question, after we have considered + and — . 
 
 Let us now consider the expression U{x-'ry). 
 If the X points and the y points are outside of one 
 another, it means the sum of the .v points and the 
 y points (Fig. 3). So far all are agreed. But 
 suppose that the .v points and the y points are 
 partially identical (Fig. 4); then there arises 
 difference of opinion. Boole held that the common points must 
 be taken twice over, or in other words that the svmbols .v and 
 
 Fig. 3. 
 
60 TEN BRITISH MATHEMATICIANS 
 
 y must be treated all the same as if they were independent of 
 one another; otherwise, he held, no general analysis is possible. 
 V{x+y) will not in general denote a single class 
 of points; it will involve in general a duplica- 
 tion. 
 
 Similarly, Boole held that the expression 
 U{x—y) does not involve the condition of the 
 ^''^■4- JJy being wholly included in the Ux (Fig. 5). 
 
 If that condition is satisfied, U{x—y) denotes a simple class; 
 namely, the JJx's without the Uy's. But when there is partial 
 coincidence (as in Fig. 4), the common points will be cancelled, 
 and the result will be the [/x's which are not y taken posi- 
 tively and the Uy's^ which are not x taken negatively. In 
 Boole's view Uix—y) was in general an intermediate uninter- 
 pretable form, which might be used in reasoning the same way 
 as analysts used V— i. 
 
 Most of the mathematical logicians who have come after 
 Boole are men who would have stuck at the impossible sub- 
 traction in ordinary algebra. They say virtually, " How can 
 you throw into a heap the same things twice over; and how 
 can you take from a heap things that are not there." Their 
 great principle is the impossibility of taking the pants from a 
 Highlander. Their only conception of the analytical processes 
 of addition and subtraction is throwing into a heap and taking 
 out of a heap. It does not occur to them that the processes of 
 algebra are ideal, and not subject to gross material restrctions. 
 If x+y denotes a quality without duplication, it will sat- 
 isfy the condition 
 
 {oc+yY = x+y, 
 
 x^+2xy+y'^=x+y, 
 but x^=x, y^=y, 
 
 2xy = o. 
 Similarly, if x—y denote a simple quality, then 
 
 {x-yy=x-y, 
 x^-\-y^^^2xy=x—y, 
 
 X^ = X, y2 = y^ 
 
GEORGE BOOLE 61 
 
 therefore, y — 2xy = —y, 
 
 .: y = xy. 
 
 In other words, the Uy must be included in the Ux (Fig. 5). 
 Here we have assumed that the law of signs is 
 the same as in ordinary algebra, and the result 
 comes out correct. 
 
 Suppose Uz^Uxy; then Ux = U-z. How are 
 
 y 
 
 the Ux's related to the Uy's and the Uz's? From ^^°- ^■ 
 
 the diagram (in Fig. 2) we see that the Ux's are identical with 
 all the Uyz's together with an indefinite portion of the U's, which 
 are neither y nor z. Boole discovered a general method for 
 finding the meaning of any function of elementary logical 
 symbols, which applied to the above case, is as follows: 
 When y is an elementary symbol, 
 
 Similarly i=z+(i— z). 
 
 .'. i=yz+y{i-z) + {i-y)z+{i-y){i-z), 
 
 which means that the U's either have both qualities y and z, 
 or y but not z, or z but not y, or neither y and z. Let 
 
 -z==Ayz+By{i—z)+C{i—y)z+D{i—y)(i—z), 
 
 y 
 
 it is required to determine the coefficients A, B, C, D. Sup- 
 posey = i, z = i; theni=yl. Suppose y = i, z=o, then o=£. 
 
 Suppose y=o, z = i; then - = C, and C is infinite; therefore 
 
 o 
 
 {i—y)z = o; which we see to be true from the diagram. Sup- 
 pose y=o, z=o; then -=D, or Z) is indeterminate. Hence 
 o 
 
 -2 = j'z+an indefinite portion of (1—3') (1—2). 
 
 y 
 
 Boole attached great importance to the index law x^ = x. 
 He held that it expressed a law of thought, and formed the 
 
62 TEN BRITISH MATHEMATICIANS 
 
 characteristic distinction of the operations of the mind in its 
 ordinary discourse and reasoning, as compared with its oper- 
 ations when occupied with the general algebra of quantity. 
 It makes possible, he said, the solution of a quintic or equation 
 of higher degree, when the symbols are logical. He deduces from 
 it the axiom of metaphysicians which is termed the principle 
 of contradiction, and which affirms that it is impossible for 
 any being to possess a quality, and at the same time not to 
 possess it. Let x denote an elementary quality applicable 
 to the universe U; then i—x denotes the absence of that 
 quality. But if x^ = x, then o=x—x^, o = x{i—x), that is, 
 from Ux^ = Ux we deduce Ux{i —x) =o. 
 
 He considers x(i— :k)=o as an expression of the prin- 
 ciple of contradiction. He proceeds to remark : " The above 
 interpretation has been introduced not on account of its imme- 
 diate value in the present system, but as an illustration of a 
 significant fact in the philosophy of the intellectual powers, 
 viz., that what has been commonly regarded as the funda- 
 mental axiom of metaphysics is but the consequence of a law 
 of thought, mathematical in its form. I desire to direct atten- 
 tion also to the circumstance that the equation in which that 
 fundamental law of thought is expressed is an equation of 
 the second degree. Without speculating at all in this chapter 
 upon the question whether that circumstance is necessary in 
 its own nature, we may venture to assert that if it had not 
 existed, the whole procedure of the understanding would have 
 been different from what it is." 
 
 We have seen that De Morgan investigated long and 
 published much on mathematical logic. His logical writings 
 are characterized by a display of many symbols, new alike 
 to logic and to mathematics; in the words of Sir W. Hamilton 
 of Edinburgh, they are " horrent with mysterious spicule." 
 It was the great merit of Boole's work that he used the immense 
 power of the ordinary algebraic notation as an exact language, 
 and proved its power for making ordinary language more 
 exact. De Morgan could well appreciate the magnitude of 
 the feat, and he gave generous testimony to it as follows; 
 
GEORGE BOOLE 63 
 
 " Boole's system of logic is but one of many proofs of genius 
 and patience combined. I might legitimately have entered 
 it among my paradoxes, or things counter to general opinion: 
 but it is a paradox which, like that of Copernicus, excited 
 admiration from its first appearance. That the symbolic 
 processes of algebra, invented as tools of numerical calcula- 
 tion, should be competent to express every act of thought, 
 and to furnish the grammar and dictionary of an all-containing 
 system of logic, would not have been believed until it was 
 proved. When Hobbes, in the time of the Commonwealth, 
 pubHshed his " Computation or Logique " he had a remote 
 glimpse of some of the points which are placed in the light of 
 day by Mr. Boole. The unity of the forms of thought in all 
 the applications of reason, however remotely separated, wiU 
 one day be matter of notoriety and common wonder: and 
 Boole's name will be remembered in coimection with one of 
 the most important steps towards the attainment of this 
 knowledge." 
 
ARTHUR CAYLEY* 
 
 (1821-1895) 
 
 Arthur Cayley was bom at Richmond in Surrey, England, 
 on August 16, 1821. His father, Henry Cayley, was descended 
 from an ancient Yorkshire family, but had settled in St. Peters- 
 burg, Russia, as a merchant. His mother was Maria Antonia 
 Doughty, a daughter of William Doughty; who, according 
 to some writers, was a Russian; but her father's name indi- 
 cates an English origin. Arthur spent the first eight years of 
 his life in St. Petersburg. In 1829 his parents took up their 
 permanent abode at Blackheath, near London; and Arthur 
 was sent to a private school. He early showed great Hking 
 for, and aptitude in, numerical calculations. At the age of 
 14 he was sent to King's College School, London; the master 
 of which, having observed indications of mathematical genius, 
 advised the father to educate his son, not for his own business, 
 as he had at first intended, but to enter the University of 
 Cambridge. 
 
 At the unusually early age of 17 Cayley began residence 
 at Trinity College, Cambridge. As an undergraduate he had 
 generally the reputation of being a mere mathematician; 
 his chief diversion was novel-reading. He was also fond of 
 travelling and mountain climbing, and was a member of 
 the Alpine Club. 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 
 Mecanique analytique of Lagrange and some of the works of 
 Laplace. We have already noticed how the works of Lagrange 
 
 * This Lecture was delivered April 20, 1901. — Editors. 
 64 
 
ARTHUR CAYLEY 65 
 
 and Laplace served to start investigation in Hamilton and Boole. 
 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 com- 
 petitive examination. 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 Mathe- 
 matical Journal. On account of the limited tenure of his 
 fellowship it was necessary to choose a profession; like De 
 Morgan, Cayley chose the law, and at 25 entered at Lincoln's 
 Inn, London. He made a specialty of conveyancing and became 
 very skilled at the work; but he regarded his legal occupation 
 mainly as the means of providing a livelihood, and he reserved 
 with jealous care a due portion of his time for mathematical 
 research. It was while he was a pupil at the bar that he went 
 over to Dublin for the express purpose of hearing Hamilton's 
 lectures on Quaternions. He sat alongside of Salmon (now 
 provost of Trinity College, Dublin) and the readers of Salmon's 
 books on Analytical Geometry know how much their author 
 was indebted to his correspondence with Cayley in the matter 
 of bringing his textbooks _up to date. 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 four- 
 teen years, Cayley produced between two and three hundred 
 papers. 
 
 At Cambridge University the ancient professorship of pure 
 mathematics is denominated the Lucasian, and is the chair 
 which was occupied by Sir Isaac Newton. About i860 certain 
 funds bequeathed by Lady Sadleir to the University, having 
 become useless for their original purpose, were employed to 
 estabhsh another professorship of pure mathematicas, 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 
 
63 TEN BRITISH MATHEMATICIANS 
 
 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 hfe at Cambridge; whereas he had never married, 
 and had been fighting the world all his days. The remark was 
 only too true (as may be seen in the lecture on Sylvester). 
 
 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 mathe- 
 matical 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. Many mathematicians, of whom 
 Sylvester was an example, find it irksome to study what others 
 have written, unless, perchance, it is something dealing directly 
 with their own line of work. Cayley was a man of more cos- 
 mopolitan spirit; he had a friendly sympathy with other workers, 
 and especially with young men making their first adventure in 
 the field of mathematical research. Of referee work he did an 
 
ARTHUR CAYLEY 67 
 
 immense amount; and of his kindliness to young investigators 
 I can speak from personal experience. Several papers which 
 I read before the Royal Society of Edinburgh on the Analysis 
 of Relationships were referred to him, and he recommended 
 their publication. Soon after I was invited by the Anthropo- 
 logical Society of London to address them on the subject, 
 and while there, I attended a meeting of the Mathematical 
 Society of London. The room was small, and some twelve 
 mathematicians were assembled round a table, among whom 
 was Prof. Cayley, as became evident to me from the proceed- 
 ings. At the close of the meeting Cayley gave me a cordial 
 handshake and referred in the kindest terms to my papers 
 which he had read. He was then about 60 years old, con- 
 siderably bent, and not filling his clothes. What was most 
 remarkable about hirn was the active glance of his gray eye? 
 and his peculiar boyish smile. 
 
 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. His mathematical investigations did not make him a 
 recluse; on the contrary he was of great practical usefulness, 
 especially from his knowledge of law, in the administration of 
 the University. 
 
 ' 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, which now hangs on the side wall 
 of the dining hal. of Trinity College, next to the portrait of 
 James Clerk Maxwell, while on the end wall, behind the 
 high table, hang the more ancient portraits of Sir Isaac New- 
 ton and Lord Bacon of Verulam. In the portrait Cayley is 
 represented as seated at a desk, quill in hand, after the mode 
 in which he used to write out his mathematical investigations. 
 
68 TEN BRITISH MATHEMATICIANS 
 
 The investigation, however, was all thought out in his mind 
 before he took up the quill. 
 
 Maxwell was one of the greatest electricians of the nine- 
 teenth century. He was a man of philosophical insight and 
 poetical power, not unlike Hamilton, but differing in this, that 
 he was no orator. In that respect he was more like Gold- 
 smith, who " could write like an angel, but only talked like 
 poor poll." Maxwell wrote an address to the committee of 
 subscribers who had charge of the Cayley protrait fund, wherein 
 the scientific poet with his pen does greater honor to the mathe- 
 matician than the artist, named Dickenson, could do with his 
 brush. Cayley had written on space of n dimensions, and the 
 main point in the address is derived from the artist's business 
 of depicting on a plane what exists in space : 
 
 O wretched race of men, to space confined! 
 
 What honor can ye pay to him whose mind 
 
 To that which Hes beyond hath penetrated? 
 
 The symbols he hath formed shall sound his praise, 
 
 And lead him on through unimagined ways 
 
 To conquests new, in worlds not yet created. 
 
 First, ye Determinants, in ordered row 
 And massive column ranged, before him go, 
 To form a phalanx for his safe protection. 
 Ye poweis of the «th root of — i ! 
 Around his head in endless cycles run, 
 As unembodied spirits of direction. 
 
 And you, ye undevelopable scrolls! 
 
 Above the host where your emblazoned rolls, 
 
 Ruled for the record of his bright inventions. 
 
 Ye cubic surfaces ! by threes and nines 
 
 Draw round his camp your seven and twenty lines 
 
 The seal of Solomon in three dimensions. 
 
 March on, symbolic host! with step sublime. 
 Up to the flaming bounds of Space and Time! 
 There pause, until by Dickenson depicted 
 In two dimensions, we the form may trace 
 Of him whose soul, too large for vulgar space, 
 In n dimensions flourished unrestricted. 
 
ARTHUR CAYLEY 69 
 
 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 De- 
 terminants; Memoir on the theory of Matrices; Memoirs 
 on skew surfaces, otherwise Scrolls; On the delineation of a 
 Cubic Scroll, etc. 
 
 In 1 88 1 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. 
 
 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 pos- 
 sible. 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 philo- 
 sophical, 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: " I wish to speak to you to-night upon Mathe- 
 matics. 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, recalHng 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 
 
70 TEN BRITISH MATHEMATICIANS 
 
 the ii.ee ling is the individual, which on evolution principles, 
 must be sacrificed for the development of the race." I dare- 
 say 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. 
 
 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, i'^ the 74th year of his age. 
 When the funeral took place, a great assemblage met in Trinity 
 Chapel, comprising members of the University, official rep- 
 resentatives of Russia and America, and many of the most 
 illustrious philosophers of Great Britain. 
 
 The remainder of his papers were edited by Prof. Forsyth, 
 his successor in the Sadlerian chair. The Collected Mathe- 
 matical papers number thirteen quarto volumes, and con- 
 tain 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 hitn a 
 University Press. As regards fads, Cayley retained to the 
 last his fondness for novel-reading and for travelKng. He 
 also took special pleasure in paintings and architecture, and 
 he practised water-color painting, which he found useful some- 
 times in making mathematical diagrams. 
 
 To the third edition of Tait's Elementary Treatise on Qua- 
 ternions, Cayley contributed a chapter entitled " Sketch of 
 the analytical theory of quaternions." In it the V — i re- 
 appears in all its glory, and in entire, so it is said, independence 
 
ARTHUR CAYLEY 71 
 
 of i, j, k. The remarkable thing i? that Hamilton started with 
 a quaternion theory of analysis, and that Cayley should present 
 instead an analytical theory of quaternions. I daresay that 
 Prof. Tait was sorry that he allowed the chapter to enter 
 his book, for in 1894 there arose a brisk discussion between 
 himself 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 geom- 
 etry and are the natural and appropriate basis and method 
 in the science, quaternions seemed a particular and very arti- 
 ficial 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: " 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 applica- 
 tions. 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 under- 
 stood, must be translated into coordinates." He goes on 
 to say, " I remark that the imaginary of ordinary algebra — 
 for distinction call this 6 — 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+db, or in other words, say that a scalar 
 quantity is in general of the form a-{-Oh. 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 repHed 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 argu- 
 
72 TEN BRITISH MATHEMATICIANS 
 
 ments, it may be said,^r5/, V — i has a relation to the symbols 
 i, j, k, for each of these can be analyzed into a unit axis mul- 
 tiplied by V-i; 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 un- 
 specified. 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 Iion 
 Works, and hunted tigers in India. He says, " 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 weld- 
 ing 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 — alike in the trackless 
 jungle and in the barrack square — directed by a Uttle native 
 who requires no special skill or training, and who can be trans- 
 ferred 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 arti- 
 ficial 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 
 
ARTHUR CAYLEY _ 73 
 
 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, 
 
 j2 —j2 = ^2 _ ^y^ _ _ j^ 
 
 with the associative, but not the commutative, law for the 
 factors. The novel and splendid points in it were the treat- 
 ment 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 thor- 
 oughly 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 fur- 
 ther 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. Co- 
 ordinates may, however, easily be read into them: — when any- 
 thing (such as metrcal 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." 
 
74 TEN BRITISH MATHEMATICIANS 
 
 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 con- 
 ception, 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 hking 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." 
 
 To Cayley's presidential address we are indebted for in- 
 formation 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 empiri- 
 cal philosophers at the beginning of his address, he gave them 
 something to think of before he finished. 
 
 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 Dif- 
 ferential Calculus would be called algebra. Using the word 
 
ARTHUR CAYLEY 75 
 
 in this restricted sense, I cannot myself recognize the con- 
 nection of algebra with the notion of time; granting that the 
 notion of continuous progression presents itself and is of im- 
 portance, 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 alge- 
 braical couple, or imaginary magnitude, a+bV — i." 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. 
 
 As to the nature of mathematical science Cayley quoted 
 with approval from an address of Hamilton's: 
 
 " These purely mathematical sciences of algebra and geom- 
 etry 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 difiiculty appHes 
 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 
 
76 TEN BRITISH MATHEMATICIANS 
 
 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 aU numbers 
 whatever; there are in the Theory of Numbers very remark- 
 able instances of proposit'.ons 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 twelfth axiom, even in Playfair's form of it, has 
 been considered as needing demonstration; and that Lobat- 
 schewsky 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 
 tweKth axiom in Playfair's form of it does not need demonstra- 
 tion, 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, EucHdean space. But suppose the physical 
 space of our experience to be thus only approximately Euclidean 
 space, what is the consequence which f oUows? Not that the prop- 
 ositions 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 
 
ARTHUR CAYIEY 77 
 
 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 inter- 
 section. 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 inter- 
 section, 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 imagi- 
 nary space as the locus in quo of the imaginary point. 
 
WILLIAM KINGDON CLIFFORD* 
 
 (1845-1879) 
 
 William Kingdon CLnroED was born at Exeter, England, 
 May 4, 1845. His father was a well-known and active citizen 
 and filled the honorary office of justice of the peace; his mother 
 died while he was still young. It is believed that Clifford 
 inherited from his mother not only some of his genius, but a 
 weakness in his physical constitution. He received his ele- 
 mentary education at a private school in Exeter, where examina- 
 tions were aimually held by the Board of Local Examinations 
 of the Universities of Oxford and Cambridge; at these examina- 
 tions Clifford gained numerous distinctions in widely different 
 subjects. When fifteen years old he was sent to King's College, 
 London, where he not only demonstrated his peculiar mathe- 
 matical abilities, but also gained distinction in classics and 
 English Hterature. 
 
 When eighteen, he entered Trinity College, Cambridge; the 
 college of Peacock, De Morgan, and Cayley. He already had 
 the reputation of possessing extraordinary mathematical powers; 
 and he was eccentric ia appearance, habits and opinions. He 
 was reported to be an ardent High Churchman, which was then 
 a more remarkable thing at Cambridge than it is now. His 
 undergraduate career was distinguished by eminence in mathe- 
 matics, EngUsh literature and gymnastics. One who was his com- 
 panion in gymnastics wrote : " His neatness and dexterity were 
 unusually great, but the most remarkable thing was his great 
 strength as compared with his weight, as shown in some exercises. 
 At one time he would pull up on the bar with either hand, which 
 is well known to be one of the greatest feats of strength. His 
 nerve at dangerous heights was extraordinary." In his third 
 
 * This Lecture was delivered April 23, 1901. — ^Editors. 
 78 
 
WILLIAM KINGDON CLIFFORD 79 
 
 year he won the prize awarded by Trinity College for decla- 
 mation, his subject being Sir Walter Raleigh; as a consequence 
 he was called on to deliver the annual oration at the next Com- 
 memoration of Benefactors of the College. He chose for his 
 subject, Dr. Whewell, Master of the College, eminent for his 
 philosophical and scientific attainments, whose death had 
 occurred but recently. He treated it in an original and un- 
 expected manner; Dr. Whewell's claim to admiration and 
 emulation being put on the ground of his intellectual life exem- 
 plifying in an eminent degree the active and creating faculty. 
 " Thought is powerless, except it make something outside of 
 itself; the thought which conquers the world is not contemplative 
 but active. And it is this that I am asking you to worship 
 to-day." 
 
 To obtain high honors in the Mathematical Tripos, a student 
 must put himself in special training under a mathematican, 
 technically called a coach, who is not one of the regular college 
 instructors, nor one of the University professors, but simply 
 makes a private business of training men to pass that par- 
 ticular examination. Skill consists in the rate at which one can 
 solve and more especially write out the solution of problems. 
 It is excellent training of a kind, but there is no time for study- 
 ing fundamental principles, still less for making any philosoph- 
 ical investigations. Mathematical insight is something higher 
 than skill in solving problems; consequently the senior wrangler 
 has not always turned out the most distinguished mathematician 
 in after life. We have seen that De Morgan was fourth wrangler. 
 Clifford also could not be kept to the dust of the race-course; 
 but such was his innate mathematical insight that he came 
 out second wrangler. Other instances of the second wrangler 
 turning out the better mathematician are Whewell, Sylvester, 
 Kelvin, Maxwell. 
 
 In 1868, when he was 23 years old, he was elected a Fellow 
 of his College; and while a resident fellow, he took part in the 
 eclipse expedition of 1870 to Italy, and passed through the 
 experience of a shipwreck near Catania on the coast of the 
 island of Sicily. In 1871 he was appointed professor of Ap- 
 
80 TEN BRITISH MATHEMATICIANS 
 
 plied Mathematics and Mechanics in University College, 
 London; De Morgan's college, but not De Morgan's chair. 
 Henceforth University College was the centre of his labors. 
 
 He was now urged by friends to seek admission into 
 the Royal Society of London. This is the ancient scientific 
 society of England, founded in the time of Charles II, and 
 numbering among its first presidents Sir Isaac Newton. About 
 the middle of the nineteenth century the admission of new 
 members was restricted to fifteen each year; and from appU- 
 cations the Council recommends fifteen names which are posted 
 up, and subsequently balloted for by the Fellows. Hamilton 
 and De Morgan never applied. Clifford did not apply imme- 
 diately, but he became a Fellow a few years later. He joined 
 the London Mathematical Society — for it met in University 
 College — and he became one of its leading spirits. Another 
 metropolitan Society in which he took much interest was the 
 Metaphysical Society; Hke Hamilton, De Morgan, and Boole, 
 CUfford was a scientific philosopher. 
 
 In 1875 Clifford married; the lady was Lucy, daughter of 
 Mr. John Lane, formerly of Barbadoes. His home in London 
 became the meeting-point of a numerous body of friends, in 
 which almost every possible variety of taste and opinion was 
 represented, and many of whom had nothing else in common. 
 He took a special delight in amusing children, and for their 
 entertainment wrote a collection of fairy tales called The Little 
 People. In this respect he was like a contemporary mathe- 
 matician, Mr. Dodgson — " Lewis Carroll " — the author of 
 Alice in Wonderland. A children's party was one of Clifford's 
 greatest pleasures. At one such party he kept a waxwork 
 show, children doing duty for the figures; but I daresay he 
 drew the line at walking on all fours, as Mr. Dodgson was ac- 
 customed to do. A children's party was to be held in a house 
 in London and it happened that there was a party of adults 
 held simultaneously in the neighboring house; to give the 
 children a surprise Dodgson resolved to walk in on all fours; 
 unfortunately he crawled into the parlor of the wrong house ! 
 
 Clifford possessed unsurpassed power as a .teacher. Mr. 
 
WILLIAM KINGDON CLIFFORD 81 
 
 Pollock, a fellow student, gives an instance of Clifford's theory 
 of what teaching ought to be, and his constant way of carrying 
 it out in his discourses and conversations on mathematical 
 and scientific subjects. " In the analytical treatment of statics 
 there occurs a proposition called Ivory's Theorem concerning 
 the attractions of an ellipsoid. The textbooks demonstrate 
 it by a formidable apparatus of coordinates and integrals, 
 such as we were wont to call a grind. On a certain day in the 
 Long Vacation of 1866, which Clifford and I spent at Cambridge, 
 I was not a little exercised by the theorem in question, as I 
 suppose many students have been before and since. The chain 
 of symbolic proof seemed artificial and dead; it compelled the 
 understanding, but failed to satisfy the reason. After reading 
 and learning the proposition one still failed to see what it was 
 all about. Being out for a walk with Clifford, I opened my 
 perplexities to him; I think that I can recall the very spot. 
 What he said I do not remember in detail, which is not sur- 
 prising, as I have had no occasion to remember anything about 
 Ivory's Theorem these twelve years. But I know that as he 
 spoke he appeared not to be working out a question, but 
 simply telling what he saw. Without any diagram or symbolic 
 aid he described the geometrical conditions on which the 
 solution depended, and they seemed to stand out visibly in 
 space. There were no longer consequences to be deduced, 
 but real and evident facts which only required to be seen." 
 
 Clifford inherited a constitution in which nervous energy 
 and physical strength were unequally balanced. It was in 
 his case specially necessary to take good care of his health, 
 but he did the opposite; he would frequently sit up most of 
 the night working or talking. Like Hamilton he would work 
 twelve hours on a stretch; but, unlike Hamilton, he had 
 laborious professional duties demanding his personal attention 
 at the same time. The consequence was that five years after 
 his appointment to the chair in University College, his health 
 broke down; indications of pulmonary disease appeared. To 
 recruit his health he spent six months in Algeria and Spain, 
 and came back to his professional duties again. A year and 
 
82 TEN BRITISH MATHEMAIICIANS 
 
 a half later his health broke down a second time, and he was 
 obliged to leave again for the shores of the Mediterranean. 
 In the fall of 1878 he returned to England for the last time, 
 when the winter came he left for the Island of Madeira; all 
 hope of recovery was gone; he died March 3, 1879 in the 34th 
 year of his age. 
 
 On the title page of the volume containing his collected 
 mathematical papers I find a quotation, "If he had Hved we 
 might have known something." Such is the feeling one has 
 when one looks at his published works and thinks of the short- 
 ness of his life. In his lifetime there appeared Elements of Dy- 
 namic, Part I. Posthumously there have appeared Elements of 
 Dynamic, Part II; Collected Mathematical Papers; Lectures and 
 Essays; Seeing and Thinking; Common Sense of the Exact 
 Sciences. The manuscript of the last book was left in a very 
 incomplete state, but the design was filled up and completed 
 by two other mathematicians. 
 
 In a former lecture I had occasion to remark on the relation 
 of Mathematics to Poetry — on the fact that in mathematical 
 investigation there is needed a higher power of imagination 
 akin to the creative instinct of the poet. The matter is dis- 
 cussed by Clifford in a discourse on " Some of the conditions 
 of mental development," which he delivered at the Royal 
 Institution in 1868 when he was 23 years of age. This insti- 
 tution was founded by Count Rumford, an American, and is 
 located in London. There are Professorships of Chemistry, 
 Physics, and Physiology; its professors have included Davey, 
 Faraday, Young, Tyndall, Rayleigh, Dewar. Their duties are 
 not to teach the elements of their science to regular students, 
 but to make investigations, and to lecture to the members 
 of the institution, who are in general wealthy and titled people. 
 
 In this discourse Clifford said " Men of science have to 
 deal with extremely abstract and general conceptions. By 
 constant use and familiarity, these, and the relations between 
 them, become Just as real and external ai the ordinary objects 
 of experience, and the perception of new relations among them 
 is so rapid, the correspondence of the mind to external circum- 
 
WILLIAM KINGDON CLIFFORD 83 
 
 Stances so great, that a real scientific sense is developed, by 
 which things are perceived as immediately and truly as I see 
 you now. Poets and painters and musicians also are so accus- 
 tomed to put outside of them the idea of beauty, that it becomes 
 a real external existence, a thing which they see with spiritual 
 eyes and then describe to you, but by no means create, any 
 more than we seem to create the ideas of table and forms and 
 light, which we put together long ago. There is no scientific 
 discoverer, no poet, no painter, no musician, who will not tell 
 you that he found ready made his discovery or poem or picture — 
 that it came to him from outside, and that he did not con- 
 sciously create it from within. And there is reason to think 
 that these senses or insights are things which actually increase 
 among mankind. It is certain, at least, that the scientific sense 
 is immensely more developed now than it was three hundred 
 years ago ; and though it may be impossible to find any absolute 
 standard of art, yet it is acknowledged that a number of minds 
 which are subject to artistic training will tend to arrange 
 themselves under certain great groups and that the members 
 of each group will give an independent and yet consentient 
 testimony about artistic questions. And this arrangement 
 into schools, and the definiteness of the conclusions reached in 
 each, are on the increase, so that here, it would seem, are actually 
 two new senses, the scientific and the artistic, which the mind 
 is now in the process of forming for itself." 
 
 Clifford himself wrote a good many poems, but only a few 
 have been published. The following verses were sent to George 
 Eliot, the novelist, with a presentation copy of The Little People: 
 
 Baby drew a little house, 
 
 Drew it all askew; 
 Mother saw the crooked door 
 
 And the window too. 
 
 Mother heart, whose wide embrace 
 
 Holds the hearts of men, 
 Grows with all our growing hopes, 
 
 Gives them birth again, 
 
84 TEN BRITISH MATHEMATICIANS 
 
 Listen to this baby-talk: 
 'Tisn't wise or clear; 
 But what baby-sense it has 
 Is for you to hear. 
 
 An amusement in which Clifford took pleasure even in his 
 maturer years- was the flying of kites. He made some mathe- 
 matical investigations in the subject, anticipating, as it were, the 
 interest which has been taken in more recent years in the subject 
 of motion through the atmosphere. Clifford formed a project 
 of writing a series of textbooks on Mathematics beginning at 
 the very commencement of each subject and carrying it on 
 rapidly to the most advanced stages. He began with the 
 Elements of Dynamic, of which three books were printed in his 
 lifetime, and a fourth book, in a supplementary volume, after 
 his death. The work is unique for the clear ideas given of the 
 science; ideas and principles are more prominent than sjonbols 
 and formulae. He takes such familiar words as spin, twist, 
 squirt, whirl, and gives them an exact meaning. The book is 
 an example of what he meant by scientific insight, and from its 
 excellence we can imagine what the complete series of text- 
 books would have been. 
 
 In Clifford's lifetime it was said in England that he was the 
 only mathematician who could discourse on mathematics to 
 an audience composed of people of general culture and make 
 them think that they understood the subject. In 1872 he was 
 invited to deliver an evening lecture before the members of the 
 British Association, at Brighton; he chose for his subject " The 
 aims and instruments of scientific thought." The main theses 
 of the lecture are First, that scientific thought is the application 
 of past experience to new circumstances by means of an observed 
 order of events. Second, this order of events is not th oreti ally 
 or absolutely exact, but only exa.ct enough to correct experi- 
 ments by. As an instance of what is, and what is not scientific 
 thought, he takes the phenomenon of double ref act'on. " A 
 mineralogist, by measuring the angles of a crystal, can tell you 
 whether or no it possesses the property of double refraction 
 without looking through it. He requires no scientific thought 
 
WILLIAM KINGDON CLIFFORD 85 
 
 to do that. But Sir William Rowan Hamilton, knowing these 
 facts and also the explanation of them which Fresnel had given, 
 thought about the subject, and he predicted that by looking 
 through certain crystals in a particular direction we should see 
 not two dots but a continuous circle. Mr. Lloyd made the 
 experiment, and saw the circle, a result which had never been 
 even suspected. This has always been considered one of the 
 most signal instances of scientific thought in the domain of 
 physics. It is most distinctly an application of experience 
 gained under certain circumstances to entirely different cir- 
 circumstances." 
 
 In physical science there are two kinds of law — distinguished 
 as "empirical " and "rational." The former expresses a relation 
 which is sufficiently true for practical purposes and within 
 certain limits ; for example, many of the formulas used by engi- 
 neers. But a rational law states a connection which is accu- 
 rately true, without any modification of limit. In the theorems 
 of geometry we have examples of scientific exactness; for 
 example, in the theorem that the sum of the three interior 
 angles of a plane triangle is equal to two right angles. The 
 equality is one not of approximation, but of exactness. Now 
 the philosopher Kant pointed to such a truth and said : We know 
 that it is true not merely here and now, but ever}rwhere and for 
 all time; such knowledge cannot be gained by experience; there 
 must be some other source of such knowledge. His solution 
 was that space and time are forms of the sensibility; that truths 
 about them are not obtained by empirical induction, but by 
 means of intuition; and that the characters of necessity and 
 universaUty distinguished these truths from other truths. This 
 philosophy was accepted by Sir William Rowan Hamilton, and 
 to him it was not a barren philosophy, for it served as the 
 starting point of his discoveries in algebra which culminated in 
 the discovery of quaternions. 
 
 This philosophy was admired but not accepted by Clifford; 
 he was, so long as he lived, too strongly influenced by the 
 philosophy which has been built upon the theory of evolution. 
 He admits that the only way of escape from Kant's conclusions 
 
86 TEN BRITISH MATHEMATICIANS 
 
 is by denying the theoretical exactness of the proposition referred 
 to. He says, "About the beginning of the present century the 
 foundations of geometry were criticised independently by two 
 mathematicians, Lobatchewsky and Gauss, whose results have 
 been extended and generalized more recently by Riemaim and 
 Helmholtz. And the conclusion to which these investigations 
 lead is that, although the assumptions which were very properly 
 made by the ancient geometers are practically exact — that is 
 to say, more exact than experiment can be — for such finite things 
 as we have to deal with, and such portions of space as we can 
 reach; yet the truth of them for very much larger things, or 
 very much smaller things, or parts of space which are at present 
 beyond our reach, is a matter to be decided by experiment, 
 when its powers are considerably increased. I want to make 
 as clear as possible the real state of this question at present, 
 because it is often supposed to be a question of words or meta- 
 physics, whereas it is a very distinct and simple question of 
 fact. I am supposed to know that the three angles of a recti- 
 linear triangle are exactly equal to two right angles. Now 
 suppose that three points are taken in space, distant from one 
 another as far as the Sun is from a Centauri, and that the 
 shortest distances between these points are drawn so as to form 
 a triangle. And suppose the angles of this triangle to be very 
 accurately measured and added together; this can at present 
 be done so accurately that the error shall certainly be less than 
 one minute, less therefore than the five-thousandth part of a 
 right angle. Then I do not know that this sum would differ 
 at all from two right angles; but also I do not know that the 
 difference would be less than ten degrees or the ninth part of 
 a right angle." 
 
 You will observe that Clifford's philosophy depends on the 
 validity of Lobatchewsky's ideas. Now it has been shown by 
 an Italian mathematician, named Beltrami, that the plane 
 geometry of Lobatchewsky corresponds to trigonometry on a 
 surface called the pseudosphere. Clifford and other followers of 
 Lobatchewsky admit Beltrami's interpretation, an interpretation 
 which does not involve any paradox about geometrical space. 
 
WILLIAM KINGDON CLIFFORD 87 
 
 and which leaves the trigonometry of the plane alone as a dif- 
 ferent thing. If that interpretation is true, the Lobatchewskian 
 plane triangle is after all a triangle on a special surface, and the 
 straight Imes joining the points are not the shortest absolutely, 
 but only the shortest with respect to the surface, whatever that 
 may mean. If so, then Clifford's argument for the empirical 
 nature of the proposition referred to fails; and nothing pre- 
 vents us from falUng back on Kant's position, namely, that 
 there is a body of knowledge characterized by absolute exact- 
 ness and possessing universal application in time and space; 
 and as a particular case thereof we believe that the sum of the 
 three angles of Clifford's gigantic triangle is precisely two right 
 angles. 
 
 Trigonometry on a spherical surface is a generalized form of 
 plane trigonometry, from the theorems of the former we can 
 deduce the theorems of the latter by supposing the radius of 
 the sphere to be infinite. The sum of the three angles of a 
 spherical triangle is greater than two right angles; the sum of 
 the angles of a plain triangle is equal to two right angles; we 
 infer that there is another surface, complementary to the 
 sphere, such that the angles of any triangle on it are less than 
 two right angles. The complementary surface to which I refer 
 is not the pseudosphere, but the equilateral hyperboloid. As 
 the plane is the transition surface between the sphere and 
 the equilateral hyperboloid, and a triangle on it is the transi- 
 tion triangle between the spherical triangle and the equilateral 
 hyperboloidal triangle, the sum of the angles of the plane tri- 
 angle must be exactly equal to two right angles. 
 
 In 1873, the British Association met at Bradford; on this 
 occasion the evening discourse was delivered by Maxwell, 
 the celebrated physicist. He chose for his subject " Mole- 
 cules." The application of the method of spectrum-ana ysis 
 assures the physicist that he can find out in his laboratory 
 truths of universal vahdity in space and t me. In fact, the 
 chief maxim of physical science, according to MaxweU is, 
 that physical changes are independent of the conditions of 
 space and time, and depend only on conditions of configuration 
 
88 TEN BEITISH MATHEMATICIANS 
 
 of bodies, temperature, pressure, etc. The address closed 
 with a celebrated passage in striking contrast to Clifford's 
 address: " In the heavens we discover by their light, and 
 by their light alone, stars so distant from each other that no 
 material thing can ever have passed from one to another; and 
 yet this light, which is to us the sole evidence of the exis ence 
 of these distant worlds, tells us also that each of th m is bui-t 
 up of molecules of the same kinds as those which are found on 
 earth. A mol cule of hydrogen, for example, whether in S rius 
 or in Arcturus, executes its vibrations in precisely the same 
 time. No theory of evolution can be formed to account for 
 the similarity of molecules, for evolution necessarily implies 
 continuous change, and the molecule is incapable of growth 
 or decay, of generation or destruction. None of the processes 
 of Nature since the time when Nature began, have produced 
 the slightest difference in the properties of any molecule. We 
 are therefore unable to ascribe either the existence of the mole- 
 cules or the identity of their properties to any of the causes 
 which we call natural. On the other hand, the exact equality 
 of each molecule to all others of the same kind gives it, as 
 Sir John Herschel has well said, the essential character of a 
 manufactured article, and precludes the idea of its being eternal 
 and self -existent." 
 
 What reply could Clifford make to this? In a discourse 
 on the " First and last catastrophe " delivered soon afterwards, 
 he said " If anyone not possessing the great authority of 
 Maxwell, had put forward an argument, founded upon a sci- 
 entific basis, in which there occurred assumptions about what 
 things can and what things cannot have existed from eternity, 
 and about the exact similarity of two or more things established 
 by experiment, we would say: ' Past eternity; absolute exact- 
 ness; won't do '; and we should pass on to another book. 
 The experience of all scientific culture for all ages during which 
 it has been a light to men has shown us that we never do get 
 at any conclusions of that sort. We do not get at conclusions 
 about infinite time, or .'nfinite exactness. We get at conclu- 
 sions which are as nearly true as experment can show, and 
 
WILLIAM KINGDON CLIFFORD 89 
 
 sometimes which are a great deal more correct than direct 
 experiment can be, so that we are able actually to correct 
 one experiment by deductions from another, but we never 
 get at conclusions which we have a right to say are absolutely 
 exact." 
 
 Clifford had not faith in the exactness of mathematical science 
 nor faith in that maxim of physical science which has built 
 up the new astronomy, and extended all the bounds of physical 
 science. Faith in an exact order of Nature was the charac- 
 teristic of Faraday, and he was by unanimous consent the 
 greatest electrician of the nineteenth century. What is the 
 general direction of progress in science? Physics is becoming 
 more and more mathematical; chemistry is becoming more 
 and more physical, and I daresay the biological sciences are 
 moving in the same direction. They are all moving towards 
 exactness; consequently a true philosophy of science will de- 
 pend on the principles of mathematics much more than 
 upon the phenomena of biology. Clifford, I believe, had he 
 lived longer, would have changed his philosophy for a more 
 mathematical one. In 1874 there appeared in Nature among 
 the letters from correspondents one to the following effect: 
 
 An anagram: The practice of enclosing discoveries in sealed 
 packets and sending them to Academies seems so inferior to 
 the old one of Huyghens, that the following is sent you for 
 publication in the old conservated form : 
 
 This anagram was explained in a book entitled The Unseen 
 Universe, which was pubhshed anonymously in 1875; and is 
 there translated, " Thought conceived to affect the matter of 
 another universe simultaneously with this may explain a future 
 state." The book was evidently a work of a physicist or 
 physicists, and as phys'cists were not so numerous then as 
 they are now, it was not diiificult to determine the authorship 
 from internal evidence. It was attributed to Tait, the professor 
 of physics at Edinburgh University, and Balfour Stewart, the 
 professor of physics at Owens College, Manchester. When 
 
90 TEN BRITISH MATHEMATICIANS 
 
 the fourth edition appeared, their names were given on the 
 title page. 
 
 The kernel of the book is the above so-called discovery, 
 first published in the form of an anagram. Preliminary chap- 
 ters are devoted to a survey of the beliefs of ancient peoples 
 on the subject of the immortality of the soul; to physical 
 axioms; to the physical doctrine of energy, matter, and ether; 
 and to the biological doctrine of development; in the last 
 chapter we come to the unseen universe. What is meant by 
 the unseen universe? Matter is made up of molecules, which 
 are supposed to be vortex-rings of an imperfect fluid, namely, 
 the luminiferous ether; the luminous ether is made up of much 
 smaller molecules, which are vortex-rings in a second ether. 
 These smaller molecules with the ether in which they float 
 are the unseen universe. The authors see reason to believe 
 that the unseen universe absorbs energy from the visible uni- 
 verse and vice versa. The soul is a frame which is made of 
 the refined molecules and exists in the unseen universe. In 
 life it is attached to the body. Every thought we think is 
 accompam'ed by certain motions of the coarse molecules of 
 the brain, these motions are propagated through the visible 
 universe, but a part of each motion is absorbed by the fine 
 molecules of the soul. Consequently the soul has an organ 
 of memory as well as the body; at death the soul with its 
 organ of memory is simply set free from associat'on with the 
 coarse molecules of the body. In this way the authors con- 
 sider that they have shown the physical possibility of the 
 immortality of the soul. 
 
 The curious part of the book follows: the authors change 
 their possibility into a theory and apply it to explain the main 
 doctrines of Christianity; and it is certainly remarkable to find 
 in the same book a discussion of Camot's heat-engine and ex- 
 tensive quotations from the apostles and prophets. Clifford 
 wrote an elaborate review which he finished in one sitting occu- 
 pying twelve hours. He pointed out the difficulties to which 
 the main speculation, which he admitted to be ingenious, is 
 liable; but his wrath knew no bounds when he proceeded to con- 
 
WILLIAM KINGDON CLIFFORD 91 
 
 sider the application to the doctrines of Christianity; for from 
 being a High Churchman in youth he became an agnostic in 
 later years ; and he could not write on any religious question 
 without using language which was offensive even to his friends. 
 The Phaedo of Plato is more satisfying to the mind than the 
 Unseen Universe of Tait and Stewart. In it, Socrates discusses 
 with his friends the immortahty of the soul, just before taking 
 the draught of poison. One argument he advances is, How can 
 the works of an artist be more enduring than the artist himself? 
 This is a question which comes home in force when we peruse 
 the works of Peacock, De Morgan, Hamilton, Boole, Cayley 
 and Clifford. 
 
HENRY JOHN STEPHEN SMITH* 
 
 (1826-1883) 
 
 Henry John Stephen Smith was born in Dublin, Ireland, 
 on November 2, 1826. His father, John Smith, was an Irish 
 barrister, who had graduated at Trinity College, Dublin, and 
 had afterwards studied at the Temple, London, as a pupil of 
 Henry John Stephen, the editor of Blackstone's Commentaries; 
 hence the given name of the future mathematician. His mother 
 was Ma-y Murphy, an accomplished and clever Irishwoman, 
 tall and beautiful. Henry was the youngest of four children, 
 and was but two years old when his father died. His mother 
 would have been left in straitened circumstances had she not 
 been successful in claiming a bequest of £10,000 which had been 
 left to her husband but had been disputed. On receiving this 
 money, she migrated to England, and finally settled in the Isle 
 of Wight. 
 
 Henry as a child was sickly and very near-sighted. When 
 four years of age he displayed a genius for mastering languages. 
 His first instructor was his mother, who had an accurate knowl- 
 edge of the class'cs. When eleven years of age, he, along with 
 his brother and sisters, was placed in the charge of a private 
 tutor, who was strong in the classics; in one year he read a 
 large portion of the Greek and Latin authors commonly studied. 
 His tutor was mpressed with his power of memory, quickness 
 of perception, indefatigable diHgence, and intuitive grasp of 
 whatever he studied. In their leisure hours the children would 
 improvise plays from Homer, or Robinson Crusoe; and they 
 also became diligent students of animal and insect life. Next 
 year a new tutor was strong in the mathematics, and with his 
 aid Henry became acquainted with advanced arithmetic, and 
 
 * This Lecture was delivered March 15, 1902. — Editors. 
 92 
 
HENRY JOHN STEPHEN SMITH 93 
 
 the elements of algebra and geometry. The year following, 
 Mrs. Smith moved to Oxford, and placed Henry under the 
 care of Rev. Mr. Highton, who was not only a sound scholar, 
 but an exceptionally good mathematician. The year following 
 Mr. Highton received a mastership at Rugby with a boarding- 
 house attached to it (which is important from a financial point 
 of view) and he took Henry Smith with him. as his first boarder. 
 Thus at the age of fifteen Henry Smith was launched into the 
 life of the English public school, and Rugby was then under the 
 most famous headmaster of the day. Dr. Arnold. Schoolboy life 
 as it was then at Rugby has been depicted by Hughes in " Tom 
 Brown's Schooldays." 
 
 Here he showed great and all-around ability. It became 
 his ambition to crown his school career by carrying off an 
 entrance scholarship at BalHol College, Oxford. But as a sister 
 and brother had already died of consumption, his mother did 
 not allow him to complete his third and final year at Rugby, but 
 took him to Italy, where he continued his reading privately. 
 Notwithstanding this manifest disadvantage, he was able to 
 carry off the coveted scholarship; and at the age of nineteen 
 he began residence as a student of Balliol College. The next 
 long vacation was spent in Italy, and there his health broke 
 down. By the following winter he had not recovered enough 
 to warrant his return to Oxford; instead, he went to Paris, 
 and took several of the courses at the Sorbonne and the College 
 de France. These studies abroad had much influence on his 
 future career as a mathematician. Thereafter he resumed his 
 undergraduate studies at Oxford, carried off what is considered 
 the highest classical honor, and in 1849, when 23 years old, 
 finished his undergraduate career with a double-first; that is, 
 in the honors examination for bache or of arts he took first-class 
 rank in the classics, and also first-class rank in he math matics. 
 
 It is not very pleasant to be a double fi st, for the outwardly 
 envied and distinguished recipient is apt to find himself in the 
 position of the ass between two equally inviting bundles of hay, 
 unless indeed there is some external attraction superior to both. 
 In the case of Smith, the external attraction was the bar, for 
 
94 TEN BRITISH MATHEMATICIANS 
 
 which he was in many respects well suited; but the feebleness 
 of his constitution led him to abandon that course. So he had 
 a difficulty in deciding between classics and mathematics, and 
 there is a story to the effect that he finally solved the difficulty 
 by tossing up a penny. He certainly used the expression: but 
 the reasons which determined his choice in favor of mathematics 
 were first, his weak sight, which made thinking preferable to 
 reading, and secondly, the opportunity which presented itself. 
 
 At that time Oxford was recovering from the excitement 
 which had been produced by the Tractarian movement, and 
 which had ended in Newman going over to the Church of Rome. 
 But a Parliamentary Commission had been appointed to inquire 
 into the working of the University. The old system of close 
 scholarships and fellowships was doomed, and the close pre- 
 serves of the Colleges were being either extinguished or thrown 
 open to public competition. Resident professors, married tutors 
 or fellows were almost or quite unknown; the heads of the 
 several colleges, then the governing body of the University, 
 formed a little society by themselves. Balliol College (founded 
 by John Balliol, the unfortunate King of Scotland who was 
 willing to sell its independence) was then the most distinguished 
 for intellectual eminence; the master was singular among his 
 compeers for keeping steadily in view the true aim of a col- 
 lege, and he reformed the abuses of privilege and close endow- 
 ment as far as he legally could. Smith was elected a fellow 
 with the hope that he would consent to reside, and take the 
 further office of tutor in mathematics, which he did. Soon 
 after he became one of the mathematical tutors of Balliol he 
 was asked by his college to deliver a course of lectures on 
 chemistry. For this purpose he took up the study of chemical 
 analysis, and exhibited skill in manipulation and accuracy in 
 work. He had an idea of seeking numerical relations connecting 
 the atomic weights of the elements, and some mathematical 
 basis for their properties which might enable experiments to 
 be predicted by the operation of the mind. 
 
 About this time Whewell, the master of Trinity College, 
 Cambridge, wrote The Plurality of Worlds, which was at first 
 
HENRY JOHN STEPHEN SMITH 95 
 
 published anonymously. Whewell pointed out what he called 
 law of waste traceable in the Divine economy; and his argu- 
 ment was that the other planets were waste effects, the Earth 
 the only oasis in the desert of our system, the only world 
 inhabited by intelligent beings; Sir David Brewster, a Scottish 
 physicist, inventor of the kaleidoscope, wrote a fiery answer 
 entitled " More worlds than one, the creed of the philosopher 
 and the hope of the Christian." In 1855 Smith wrote an essay 
 on this subject for a volume of Oxford and Cambridge Essays 
 in which the fallibility both of men of science and of theologians 
 was impartially exposed. It was his first and only effort at 
 popular writing. 
 
 His two earliest mathematical papers were on geometrical 
 subjects, but the third concerned that branch of mathematics 
 in which he won fame — the theory of numbers. How he was 
 led to take up this branch of mathematics is not stated on 
 authority, but it was probably as follows: There was then no 
 school of mathematics at Oxford; the symbolical school was 
 flourishing at Cambridge; and Hamilton was lecturing on 
 Quaternions at Dublin. Smith did not estimate either of these 
 very highly; he had studied at Paris under some of the great 
 French analysts; he had lived much on the Continent, and was 
 familiar with the French, German and Italian languages. As 
 a scholar he was drawn to the masterly disquisitions of Gauss, 
 who had made the theory of numbers a principal subject of 
 research. I may quote here his estimate of Gauss and of his 
 work: " If we except the great name of Newton (and the excep- 
 tion is one which Gauss himself would have been delighted to 
 make) it is probable that no mathematician of any age or country 
 has ever surpassed Gauss in the combination of an abundant 
 fertility of invention with an absolute vigorousness in demonstra- 
 tion, which the ancient Greeks themselves might have envied. 
 It may be admitted, without any disparagement to the eminence 
 of such great mathematicians as Euler and Cauchy that they 
 were so overwhelmed with the exuberant wealth of their own 
 creations, and so fascinated iby the interest attaching to the 
 results at which they arrived, that they did not greatly care 
 
96 TEN BRITISH MATHEMATICIANS 
 
 to expend their time in arranging their ideas in a strictly logical 
 order, or even in establishing by irrefragable proof propositions 
 which they instinctively felt, and could almost see to be true. 
 With Gauss the case was otherwise. It may seem paradoxical, 
 but it is probably nevertheless true that it is precisely the effort 
 after a logical perfection of form which has rendered the writings 
 of Gauss open to the charge of obscurity and unnecessary diffi- 
 culty. The fact is that there is neither obscurity nor difficulty 
 in his writings, as long as we read them in the submissive spirit 
 in which an intelligent schoolboy is made to read his Euclid. 
 Every assertion that is made is fully proved, and the assertions 
 succeed one another in a perfectly just analogical order; there 
 nothing so far of which we can complain. But when we have 
 finished the perusal, we soon begin to feel that our work is but 
 begun, that we are still standing on the threshold of the temple, 
 and that there is a secret which lies behind the veil and is as 
 yet concealed from us. No vestige appears of the process by 
 which the result itself was obtained, perhaps not even a trace 
 of the considerations which suggested the successive steps of 
 the demonstration. Gauss says more than once that for brevity, 
 he gives only the synthesis, and suppresses the analysis of his 
 propositions. Pauca sed matura — few but well-matured — were 
 the words with which he delighted to describe the character which 
 he endeavored to impress upon his mathematical writings. 
 If, on the other hand, we turn to a memoir of Euler's, there 
 is a sort of free and luxuriant gracefulness about the whole 
 performance, which tells of the quiet pleasure which Euler must 
 have taken in each step of his work; but we are conscious never- 
 theless that we are at an immense distance from the severe 
 grandeur of design which is characteristic of all Gauss's greater 
 efforts." 
 
 Following the example of Gauss, he wrote his first paper 
 on the theory of numbers in Latin: " De compositione nume- 
 rorum primorum formse 4w-|-i ex duobus quadratis." In it 
 he proves in an original manner the theorem of Fermat— " That 
 every prime number of the form 411 4- 1 {n being an integer 
 number) is the sum of two square numbers." In his second 
 
HENRY JOHN STEPHEN SMITH 97 
 
 paper he gives an introduction to the theory of numbers. " It 
 is probable that the Pythagorean school v/as acquainted with 
 the definition and nature of prime numbers; nevertheless the 
 arithmetical books of the elements of Euclid contain the oldest 
 extant investigations respecting them; and, in particular the 
 celebrated yet simple demonstration that the number of the 
 primes is infinite. To Eratosthenes of Alexandria, who is for 
 so many other reasons entitled to a place in the history of the 
 sciences, is attributed the invention of the method by which the 
 primes may successively be determined in order of magnitude. 
 It is termed, after him, ' the sieve of Eratosthenes '; and is es- 
 sentially a method of exclusion, by which all composite numbers 
 are successively erased from the series of natural numbers, and 
 the primes alone are left remaining. It requires only one kind 
 of arithmetical operation; that is to say, the formation of the 
 successive multiples of given numbers, or in other words, 
 addition only. Indeed it may be said to require no arithmetical 
 operation whatever, for if the natural series of numbers be 
 represented by points set off at equal distances along a line, 
 by using a geometrical compass we can determine without cal- 
 culation the multiples of any given number. And in fact, it 
 was by a mechanical contrivance of this nature that M. Burck- 
 hardt calculated his table of the least divisors of the first three 
 millions of numbers. 
 
 In 1857 Mrs. Smith died; as the result of her cares and 
 exertions she had seen her son enter Balliol College as a 
 scholar, graduate a double-first, elected a fellow of his college, 
 appointed tutor in mathematics, and enter on his career as an 
 independent mathematician. The brother and sister that were 
 left arranged to keep house in Oxford, the two spending the 
 terms together, and each being allowed complete liberty of move- 
 ment during the vacations. Thereafter this was the domestic 
 arrangement in which Smith lived and worked; he never married. 
 As the owner of a house, instead of living in rooms in college 
 he was able to satisfy his fondness for pet animals, and also 
 to extend Irish hospitality to visiting friends under his own 
 roof. He had no household cares to destroy the needed serenity 
 
98 TEN BKITISH MATHEMATICIANS 
 
 for scientific work, excepting that he was careless in money 
 matters, and trusted more to speculation in mining shares than 
 to economic management of his income. Though addicted to 
 the theory of numbers, he was not in any sense a recluse; on 
 the contrary he entered with zest into every form of social 
 enjoyment in Oxford, from croquet parties and picnics to ban- 
 quets. He had the rare power of utilizing stray hours of leisure, 
 and it was in such odd times that he accomplished most of his 
 scientific work. After attending a picnic in the afternoon, he 
 could mount to those serene heights in the theory of numbers 
 
 " Where never creeps a cloud or moves a wind, 
 Nor ever falls the least white star of snow, 
 Nor ever lowest roll of thunder moans, 
 Nor sound of human sorrow mounts, to mar 
 Their sacred everlasting calm." 
 
 Then he could of a sudden come down from these heights 
 to attend a dinner, and could conduct himself there, not as a 
 mathematical genius lost in reverie and pointed out as a poor 
 and eccentric mortal, but on the contrary as a thorough man 
 of the world greatly liked by everybody. 
 
 In 1860, when Smith was 34 years old, the Savilian professor 
 of geometry at Oxford died. At that time the English uni- 
 versities were so constituted that the teaching was done by the 
 college tutors. The professors were officers of the University; 
 and before reform set in, they not only did not teach, they did 
 not even reside in Oxford. At the present day the lectures of 
 the University professors are in general attended by only a few 
 advanced students. Henry Smith was the only Oxford candi- 
 date; there were other candidates from the outside, among 
 them George Boole, then professor of mathematics at Queens 
 College, Cork. Smith's claims and talents were considered so 
 conspicuous by the electors, that they did not consider any 
 other candidates. He did not resign as tutor at Balliol, but 
 continued to discharge the arduous duties, in order that the 
 income of his Fellowship might be continued. With proper 
 financial sense he might have been spared from labors which 
 militated against the discharge of the higher duties of professor. 
 
, HENRY JOHN STEPHEN SMITH 99 
 
 His freedom during vacation gave him the opportunity of 
 attending the meetings of the British Association, where he 
 was not only a distinguished savant, but an accomplished 
 member of the social organization known as the Red Lions. In 
 1858 he was selected by that body to prepare a report upon the 
 Theory of Numbers. It was prepared in five parts, extending 
 over the years 1859-1865. It is neither a history nor a treatise, 
 but something intermediate. The author analyzes with remark- 
 able clearness and order the works of mathematicians for the 
 preceding century upon the theory of congruences, and upon 
 that of binary quadratic forms. He returns to the original 
 sources, indicates the principle and sketches the course of the 
 demonstrations, and states the result, often adding something 
 of his own. The work has been pronounced to be the most 
 complete and elegant monument ever erected to the theory of 
 numbers, and the model of what a scientific report ought to be. 
 
 During the preparation of the Report, and as a logical con- 
 sequence of the researches connected therewith. Smith pub- 
 lished several original contributions to the higher rithmetic. 
 Some were in complete form and appeared in the Philosophical 
 Transactions of the Royal Society of London; others were 
 incomplete, giving only the results without the extended demon- 
 strations, and appeared in the Proceedings of that Society. One 
 of the latter, entitled " On the orders and genera of quadratic 
 forms containing more than three indeterminates," enunciates 
 certain general principles by means of which he solves a problem 
 proposed by Eisenstein, namely, the decomposition of integer 
 numbers into the sum of five squares; and further, the analogous 
 problem for seven squares. It was also indicated that the four, 
 six, and eight-square theorems of Jacobi, Eisenstein and Lion- 
 ville were deducible from the principles set forth. 
 
 In 1868 he returned to the geometrical researches which had 
 first occupied his attention. For a memoir on " Certain cubic 
 and biquadratic problems " the Royal Academy of Sciences of 
 Berlin awarded him the Steiner prize. On account of his ability 
 as a man of affairs, Smith was in great demand for University 
 and scientific work of the day. He was made Keeper of the 
 
100 TEN BRITISH MATHEMATICIANS 
 
 University Museum; he accepted the office of Mathematical 
 Examiner to the University of London; he was a member of a 
 Royal Commission appointed to report on Scientific Education; 
 a member of the Commission appointed to reform the University 
 of Oxford; chairman of the committee of scientists who were 
 given charge of the Meteorological Office, etc. It was not till 
 1873, when offered a Fellowship by Corpus Christi College, 
 that he gave up his tutorial duties at Balliol. The demands 
 of these offices and of social functions upon his time and energy 
 necessarily reduced the total output of mathematical work of 
 the highest order; the results of long research lay buried in 
 note-books, and the necessary time was not found for elabora- 
 ting them into a form suitable for publication. Like his master, 
 Gauss, he had a high ideal of what a scientific memoir ought 
 to be in logical order, vigor of demonstration and literary execu- 
 tion; and it was to his mathematical friends matter of regret 
 that he did not reserve more of his energy for the work for 
 which he was exceptionally fitted. 
 
 He was a brilliant talker and wit. Working in the purely 
 speculative region of the theory of numbers, it was perhaps 
 natural that he should take an anti-utihtarian view of mathe- 
 matical science, and that he should express it in exaggerated 
 terms as a defiance to the grossly utilitarian views then pop- 
 ular. It is reported that once in a lecture after explaining 
 a new solution of an old problem he said, "It is the peculiar 
 beauty of this method, gentlemen, and one which endears it 
 to the really scientific mind, that under no circumstances can it 
 be of the smallest possible utility." I believe that it was at 
 a banquet of the Red Lions that he proposed the toast " Pure 
 mathematics; may it never be of any use to any one." 
 
 I may mention some other specimens of his wit. " You 
 take tea in the morning," was the remark with which he once 
 greeted a friend; " if I did that I should be awake all day." 
 Some one mentioned to him the enigmatical motto of Marischal 
 College, Aberdeen: " They say; what say they; let them say." 
 "Ah," said he, " it expresses the three stages of an undergradu- 
 ate's career. ' They say '—in his first year he accepts every- 
 
HENRY JOHN STEPHEN SMITH 101 
 
 thing he is told as if it were inspired. ' What say they ' — in 
 his second year he is skeptical and asks that question. ' Let 
 them say ' expresses the attitude of contempt characteristic of 
 his third year." Of a brilliant writer but illogical thinker he 
 said " He is never right and never wrong; he is never to the 
 point." Of Lockyer, the astronomer, who has been for many 
 years the editor of the scientific journal Nature, he said, 
 " Lockyer sometimes forgets that he is only the editor, not 
 the author, of Nature." Speaking to a newly elected fellow 
 of his college he advised him in a low whisper to write a little 
 and to save a little, adding " I have done neither." 
 
 At the jubilee meeting of the British Association held at 
 York in 1881, Prof. Huxley and Sir John Lubbock (now Lord 
 Avebury) strolled down one afternoon to the Minster, which 
 is considered the finest cathedral in England. At the main 
 door they met Prof. Smith coming out, who made a mock 
 movement of surprise. Huxley said, " You seem surprised to 
 see me here." " Yes," said Smith, "going in, you know; I would 
 not have been surprised to see you on one of the pinnacles." 
 Once I was introduced to him at a garden party, given in the 
 grounds of York Minster. He was a tall man, with sandy hair 
 and beard, decidedly good-looking, with a certain intellectual 
 distinction in his features and expression. He was everywhere 
 and known to everyone, the life and soul of the gathering. He 
 retained to the day of his death the simplicity and high spirits 
 of a boy. Socially he was an embodiment of Irish blarney 
 modified by Oxford dignity. 
 
 In 1873 the British Association met at Bradford; at which 
 meeting Maxwell delivered his famous " Discourse on Mole- 
 cules." At the same meeting Smith was the president of the 
 section of mathematics and physics. He did not take up any 
 technical subject in his address; but confined himself to matters 
 of interest in the exact sciences. He spoke of the connection 
 between mathematics and physics, as evidenced by the dual 
 province of the section. " So intimate is the union between 
 mathematics and physics that probably by far the larger part 
 of the accessions to our mathematical knowledge have been 
 
102 TEN BRITISH MATHEMATICIANS 
 
 obtained by the efforts of mathematicians to solve the problems 
 set to them by experiment, and to create for each successive 
 class of phenomena a new calculus or a new geometry, as the 
 case might be, which might prove not wholly inadequate to the 
 subtlety of nature. Sometimes indeed the mathematician has 
 been before the physicist, and it has happened that when some 
 great and new question has occurred to the experimenter or the 
 observer, he has found in the armory of the mathematician 
 the weapons which he has needed ready made to his hand. But 
 much oftener the questions proposed by the physicist have 
 transcended the utmost powers of the mathematics of the time, 
 and a fresh mathematical creation has been needed to supply 
 the logical instrument required to interpret the new enigma." 
 As an example of the rule he points out that the experiments 
 of Faraday called forth the mathematical theory of Maxwell; 
 as an example of the exception that the work of ApoUonius 
 on the conic sections was ready for Kepler in investigating the 
 orbits of the planets. 
 
 At the time of the Bradford meeting, education in the public 
 schools and universities of England was practically confined 
 to the classics and pure mathematics. In his address Smith 
 took up the importance of science as an educational discipline 
 in schools; and the following sentences, falling as they did from 
 a profound scholar, produced a powerful effect : " All knowledge 
 of natural science that is imparted to a boy, is, or may be, useful 
 to him in the business of his after-life; but the claim of natural 
 science to a place in education cannot be rested upon its useful- 
 ness only. The great object of education is to expand and to 
 train the mental faculties, and it is because we believe that the 
 study of natural science is eminently fitted to further these two 
 objects that we urge its introduction into school studies. Science 
 expands the minds of the young, because it puts before them 
 great and ennobling objects of contemplation; many of its 
 truths'are such as a child can understand, and yet such that while 
 in a measure he understands them, he is made to feel something 
 of the greatness, something of the sublime regularity and some- 
 thing of the impenetrable mystery, of the world in which he 
 
HENRY JOHN STEPHEN SMITH 103 
 
 is placed. But science also trains the growing faculties, for 
 science proposes to itself truth as its only object, and it presents 
 the most varied, and at the same time the most splendid 
 examples of the different mental processes which lead to the 
 attainment of truth, and which make up what we call reasoning. 
 In science error is always possible, often close at hand; and the 
 constant necessity for being on our guard against it is one im- 
 portant part of the education which science supplies. But in 
 science sophistry is impossible; science knows no love of para- 
 dox; science has no skill to make the worse appear the better 
 reason; science visits with a not long deferred exposure all our 
 fondness for preconceived opinions, all our partiality for views 
 which we have ourselves maintained; and thus teaches the two 
 best lessons that can well be taught — on the one hand, the love 
 of truth; and on the other, sobriety and watchfulness in the use 
 of the understanding." 
 
 The London Mathematical Society was founded in 1865. 
 By going to the meetings Prof. Smith was induced to prepare 
 for publication a number of papers from the materials of his 
 notebooks. He was for two years president, and at the end 
 of his term delivered an address " On the present state and 
 prospects of some branches of pure mathematics." He began 
 by referring to a charge which had been brought against the 
 Society, that its Proceedings showed a partiahty in favor of 
 one or two great branches of mathematical science to the com- 
 parative neglect and possible disparagement of others. He 
 replies in the language of a miner. " It may be re j pined with 
 great plausibility that ours is not a blamable partiality, but a 
 well-grounded preference. So great (we might contend) have 
 been the triumphs achieved in recent times by that combination 
 of the newer algebra with the direct contemplation of space 
 which constitutes the modern geometry— so large has been the 
 portion of these triumphs, which is due to the genius of a few 
 great English mathematicians; so vast and so inviting has been 
 the field thus thrown open to research, that we do well to press 
 along towards a country which has, we might say, been ' pros- 
 pected ' for us, and in which we know beforehand we cannot 
 
104 TEN BRITISH MATHEMATICIANS 
 
 fail to find something that will repay our trouble, rather than 
 adventure ourselves into regions where, soon after the first step, 
 we should have no beaten tracks to guide us to the lucky spots, 
 and in which (at the best) the daily earnings of the treasure- 
 seeker are small, and do not always make a great show, even 
 after long years of work. Such regions, however, there are in 
 the realm of pure mathematics, and it cannot be for the interest 
 of science that they should be altogether neglected by the rising 
 generation of English mathematicians. I propose, therefore, 
 in the first instance to direct your attention to some few of these 
 comparatively neglected spots." Since then quite a number of 
 the neglected spots pointed out have been worked. 
 
 In 1878 Oxford friends urged him to come forward as a candi- 
 date for the representation in Parliament of the University of 
 Oxford, on the principle that a University constituency ought 
 to have for its representative not a mere party politician, but 
 an academic man well acquainted with the special needs of the 
 University. The main question before the electors was the 
 approval or disapproval of the Jingo war policy of the Con- 
 servative Government. Henry Smith had always been a Liberal 
 in politics, university administration, and religion. The voting 
 was influenced mainly by party considerations — Beaconsfield 
 or Gladstone — with the result that Smith was defeated by more 
 than 2 to i; but he had the satisfaction of knowing that his 
 support came mainly from the resident and working members of 
 the University. He did not expect success and he hardly desired 
 it, but he did not shrink when asked to stand forward as the 
 representative of a principle in which he believed. The election 
 over, he devoted himself with renewed energy to the publication 
 of his mathematical researches. His report on the theory of 
 numbers had ended in elliptic functions; and it was this subject 
 which now engaged his attention. 
 
 In February, 1882, he was surprised to see in the Comptes 
 rendus that the subject proposed by the Paris Academy of 
 Science for the Grand prix des sciences mathematiques was the 
 theory of the decomposition of integer numbers into a sum of 
 five squares; and that the attention of competitors was directed 
 
HENRY JOHN STEPHEN SMITH lOS 
 
 to the results announced without demonstration by Eisenstein, 
 whereas nothing was said about his papers dealing with 
 the same subject in the Proceedings of the Royal Society. He 
 wrote to M. Hermite calling his attention to what he had pub- 
 lished; in reply he was assured that the members of the com- 
 mission did not know of the existence of his papers, and he 
 was advised to complete his demonstrations and submit the 
 memoir according to the rules of the competition. According 
 to the rules each manuscript bears a motto, and the correspond- 
 ing envelope containing the name of the successful author is 
 opened. There were still three months before the closing of the 
 concours (i June, 1882) and Smith set to work, prepared the 
 memoir and despatched it in time. 
 
 Meanwhile a political agitation had grown up in favor of 
 extending the franchise in the county constituencies. In the 
 towns the mechanic had received a vote; but in the counties 
 that power remained with the squire and the farmer; poor 
 Hodge, as he is called, was left out. Henry Smith was not merely 
 a Liberal; he felt a genuine sympathy for the poor of his own 
 land. At a meeting in the Oxford Town Hall he made a speech 
 in favor of the movement, urging justice to all classes. From 
 that platform he went home to die. When he spoke he was 
 suffering from a cold. The exposure and excitement were 
 followed by congestion of the liver, to which he succumbed on 
 February 9, 1883, in the S7th year of his age. 
 
 Two months after his death the Paris Academy made their 
 award. Two of the three memoirs sent in were judged worthy 
 of the prize. When the envelopes were opened, the authors 
 were found to be Prof. Smith and M. Minkowski, a young 
 mathematician of Koenigsberg, Prussia. No notice was taken 
 of Smith's previous publication on the subject, and M. Hermite 
 on being written to, said that he forgot to bring the matter to 
 the notice of the commission. It was admitted that there was 
 considerable similarity in the course of the investigation in the 
 two memoirs. The truth seems to be that M. Minkowski 
 availed himself of whatever had been published on the sub- 
 ject, including Smith's paper, but to work up the memoir 
 
106 TEN BRITISH MATHEMATICIANS 
 
 from that basis cost Smith iiimself much intellectual labor, 
 and must have cost Minkowski much more. Minkowski is 
 now the chief living authority in that high region of the theory 
 of numbers. Smith's work remains the monument of one of 
 the greatest British mathematicians of the nineteenth century. 
 
JAMES JOSEPH SYLVESTER* 
 (1814-1897) 
 
 James Joseph Sylvester was born in London, on the 3d 
 of September, 1814. He was by descent a Jew. His father 
 was Abraham Joseph Sylvester, and the future mathematician 
 was the youngest but one of seven children. He received his 
 elementary education at two private schools in London, and his 
 secondary education at the Royal Institution in Liverpool. At 
 the age of twenty he entered St. John's College, Cambridge; 
 and in the tripos examination he came out second wrangler. 
 The senior wrangler of the }'ear did not rise to any eminence; 
 the fourth wrangler was George Green, celebrated for his con- 
 tributions to mathematical physics; the fifth wrangler was 
 Duncan F. Gregory, who subsequently wrote on the foundations 
 of algebra. On account of his religion Sylvester could not sign 
 the thirty-nine articles of the Church of England; and as a con- 
 sequence he could neither receive the degree of Bachelor of 
 Arts nor compete for the Smith's prizes, and as a further conse- 
 quence he was not eligible for a fellowship. To obtain a degree 
 he turned to the University of Dublin. After the theological 
 tests for degrees had been abolished at the Universities of 
 Oxford and Cambridge in 1872, the University of Cambridge 
 granted him his well-earned degree of Bachelor of Arts and also 
 that of Master of Arts. 
 
 On leaving Cambridge he at once commenced to write papers, 
 and these were at first on applied mathematics. His first paper 
 was entitled " An analytical development of Fresnel's optical 
 theory of crystals," which was published in the Philosophical 
 Magazine. Ere long he was appointed Professor of Physics in 
 University College, London, thus becoming a colleague of De 
 
 * A Lecture delivered March 21, 1902. — Editors. 
 107 
 
108 TEN BRITISH MATHEMATICIANS 
 
 Morgan. At that time University College was almost the only 
 institution of higher education in England in which theological 
 distinctions were ignored. There was then no physical laboratory 
 at University College, or indeed at the University of Cambridge; 
 which was fortunate in the case of Sylvester, for he would have 
 made a sorry experimenter. His was a sanguine and fiery 
 temperament, lacking the patience necessary in physical manipu- 
 lation. As it was, even in these pre-laboratory days he felt 
 out of place, and was not long in accepting a chair of pure 
 mathematics. 
 
 In 1 84 1 he became professor of mathematics at the Uni- 
 versity of Virginia. In almost all notices of his life nothing 
 is said about his career there; the truth is that after the short 
 space of four years it came to a sudden and rather tragic ter- 
 mination. Among his students were two brothers, fully imbued 
 with the Southern ideas about honor. One day Sylvester 
 criticised the recitation of the younger brother in a wealth of 
 diction which offended the young man's sense of honor; he 
 sent word to the professor that he must apologize or be chastised. 
 Sylvester did not apologize, but provided himself with a sword- 
 cane; the young man provided himself with a heavy walking- 
 stick. The brothers lay in wait for the professor; and when he 
 came along the younger brother demanded an apology, almost 
 immediately knocked off Sylvester's hat, and struck him a blow 
 on the bare head with hi . heavy stick. Sylvester drew his sword- 
 cane, and pierced the young man just over the heart; who fell 
 back into his brother's arms, calling out " I am killed." A 
 spectator, coming up, urged Sylvester away from the spot. 
 Without waiting to pack his books the professor left for New 
 York, and took the earliest possible passage for England. The 
 student was not seriously hurt; fortunately the point of the 
 sword had struck fair against a rib. 
 
 Sylvester, on his return to London, connected himself with 
 a firm of actuaries, his ultimate aim being to qualify himself 
 to practice conveyancing. He became a student of the Inner 
 Temple in 1846, and was called to the bar in 1850. He chose 
 the same profession as did Cayley; and in fact Cayley and 
 
JAMES JOSEPH SYLVESTER 109 
 
 Sylvester, while walking the law-courts, discoursed more on 
 mathematics than on conveyancing. Cayley was full of the 
 theory of invariants; and it was by his discourse that Sylvester 
 was induced to take up the subject. These two men were life- 
 long fri nds; but it is safe to say that the permanence of the 
 friendship was due to Cayley's kind and patient disposition. 
 Recognized as the leading mathematicians of their day in Eng- 
 land, they were yet very different both in nature and talents. 
 
 Cayley was patient and equable ; Sylvester, fiery and passion- 
 ate. Cayley finished off a mathematical memoir with the same 
 care as a legal instrument; Sylvester never wrote a paper with- 
 out foot-notes, appendices, supplements; and the alterations 
 and corrections in his proofs were such that the printers found 
 their task weli-nigh impossible. Cayley was well-read in con- 
 temporary mathematics, and did much useful work as referee 
 for scientific societies; Sylvester read only what had an immedi- 
 ate bearing on his own researches, and did little, if any, work 
 as a referee. Cayley was a man of sound sense, and of great 
 service in University administration; Sylvester satisfied the 
 popular idea of a mathematician as one lost in reflection, and 
 high above mundane affairs. Cayley was modest and retiring; 
 Sylvester, courageous and full of his own importance. But 
 while Cayley's papers, almost all, have the stamp of pure logical 
 mathematics, Sylvester's are full of human interest. Cayley 
 was no orator and no poet; Sylvester was an orator, and if 
 not a poet, he at least prided himself on his poetry. It was 
 not long before Cayley was provided with a chair at Cam- 
 bridge, where he immediately married, and settled down to 
 work as a mathematician in the midst of the most favorable 
 environment. Sylvester was obliged to continue what he called 
 " fighting the world " alone and unmarried. 
 
 There is an ancient foundation in London, named after its 
 founder, Gresham College. In 1854 the lectureship of geometry 
 fell vacant and Sylvester applied. The trustees requested him 
 and I suppose also the other candidates, to deliver a probation- 
 ary lecture; with the result that he was not appointed. The 
 professorship of mathematics in the Royal Military Academy 
 
110 TEN BRITISH MATHEMATICIANS 
 
 at Woolwich fell vacant; Sylvester was again unsuccessful; but 
 
 the appointee died in the course of a year, and then Sylvester 
 
 succeeded on a second application. This was in 1855, when he 
 
 was 41 years old. 
 
 He was a professor at the Military Academy for fifteen years; 
 
 and these years constitute the period of his greatest scientific 
 
 activity. In addition to continuing his work on the theory of 
 
 invariants, he was guided by it to take up one of the most 
 
 difficult questions in the theory of numbers. Cayley had 
 
 reduced the problem of the enumeration of invariants to that 
 
 of the partition of numbers; Sylvester may be said to have 
 
 revolutionized this part of mathematics by giving a complete 
 
 analytical solution of the problem, which was in effect to 
 
 enumerate the solutions in positive integers of the indeterminate 
 
 equation : 
 
 ax+by+cz+ .... -\-ld = m. 
 
 Thereafter he attacked the similar problem connected with two 
 such simultaneous equations (known to Euler as the problem 
 of the Virgins) and was partially and considerably successful. In 
 June, 1859, he delivered a series of seven lectures on compound 
 partition in general at King's College, London. The outlines 
 of these lectures have been published by the Mathematical 
 Society of London. 
 
 Five years later (1864) he contributed to the Royal Society 
 of London what is considered his greatest mathematical achieve- 
 mant. Newton, in his lectures on algebra, which he called 
 " Universal Arithmetic " gave a rule for calculating an inferior 
 limit to the number of imaginary roots in an equation of any 
 degree, but he did not give any demonstration or indication 
 of the process by which he reached it. Many succeeding 
 mathematicians such as Euler, Waring, Maclaurin, took up the 
 problem of investigating the rule, but they were unable to estab- 
 lish either its truth or inadequacy. Sylvester in the paper 
 quoted established the validity of the rule for algebraic equa- 
 tions as far as the fifth degree inclusive. Next year in a com- 
 munication to the Mathematical Society of London, he fully 
 established and generalized the rule. " I owed my success," he 
 
JAMES JOSEPH SYLVESTER 111 
 
 said, " chiefly to merging the theorem to be proved in one of 
 greater scope and generality. In mathematical research, revers- 
 ing the axiom of Euclid and controverting the proposition of 
 Hesiod, it is a continual matter of experience, as I have found 
 myself over and over again, that the whole is less than its part." 
 
 Two years later he succeeded De Morgan as president of 
 the London Mathematical Society. He was the first mathe- 
 matician to whom that Society awarded the Gold medal founded 
 in honor of De Morgan. In 1869, when the British Association 
 met in Exeter, Prof. Sylvester was president of the section of 
 mathematics and physics. Most of the mathematicians who 
 have occupied that position have experienced difficulty in find- 
 ing a subject which should satisfy the two conditions of being 
 first, cognate to their branch of science; secondly, interesting 
 to an audience of general culture. Not so Sylvester. He took 
 up certain views of the nature of mathematical science which 
 Huxley the great biologist had just published in Macmillan's 
 Magazine and the Fortnightly Review. He introduced his subject 
 by saying that he was himself like a great party leader and 
 orator in the House of Lords, who, when requested to make a 
 speech at some religious or charitable, at-all-events non-political 
 meeting declined the honor on the ground that he could not 
 speak unless he saw an adversary before him. I shall now 
 quote from the address, so that you may hear Sylvester's own 
 words. 
 
 " In obedience," he said, " to a somewhat similar combative 
 instinct, I set to myself the task of considering certain utter- 
 ances of a most distinguished member of the Association, one 
 whom I no less respect for his honesty and public spirit, than 
 I admire for his genius and eloquence, but from whose opinions 
 on a subject he has not studied I feel constrained to differ. I 
 have no doubt that had my distinguished friend, the probable 
 president-elect of the next meeting of the Association, applied 
 his uncommon powers of reasoning, induction, comparison, 
 observation and invention to the study of mathematical science, 
 he would have become as great a mathematician as he is now 
 a biologist; indeed he has given public evidence of his ability 
 
112 TEN BRITISH MATHEMATICIANS 
 
 to grapple with the practical side of certain mathematical ques- 
 tions; but he has not made a study of mathematical science 
 as such, and the eminence of his position, and the weight justly 
 attaching to his name, render it only the more imperative that 
 any assertion proceeding from such a quarter, which may appear 
 to be erroneous, or so expressed as to be conducive to error^ 
 should not remain unchallenged or be passed over in silence. 
 
 " Huxley says ' mathematical training is almost purely 
 deductive. The mathematician starts with a few simple prop- 
 ositions, the proof of which is so obvious that they are called 
 self-evident, and the rest of his work consists of subtle deduc- 
 tions from them. The teaching of languages at any rate as 
 ordinarily practised, is of the same general nature — authority 
 and tradition furnish the data, and the mental operations are 
 deductive.' It would seem from the above somewhat singularly 
 juxtaposed paragraphs, that according to Prof. Huxley, the 
 business of the mathematical student is, from a limited number 
 of propositions (bottled up and labelled ready for use) to deduce 
 any required result by a process of the same general nature 
 as a student of languages employs in declining and conjugating 
 his nouns and verbs — that to make out a mathematical propo- 
 sition and to construe or parse a sentence are equivalent or 
 identical mental operations. Such an opinion scarcely seems 
 to need serious refutation. The passage is taken from an article 
 in Macmillan's Magazine for June last, entitled, ' Scientific 
 Education — Notes of an after-dinner speech'; and I cannot 
 but think would have been couched in more guarded terms by 
 my distinguished friend, had his speech been made before dinner 
 instead of after. 
 
 " The notion that mathematical truth rests on the narrow 
 basis of a limited number of elementary propositions from 
 which all others are to be derived by a process of logical inference 
 and verbal deduction has been stated still more strongly and 
 explicitly by the same eminent writer in an article of even date 
 with the preceeding in the Fortnightly Review; where we are 
 told that ' Mathematics is that study which knows nothing of 
 observation, nothing of experiment, nothing of induction, nothing 
 
JAMES JOSEPH SYLVESTER 113 
 
 of causation.' I think no statement could have been made 
 more opposite to the undoubted facts of the case, which are 
 that mathematical analysis is constantly invoking the aid of 
 new principles, new ideas and new methods not capable of 
 being defined by any form of words, but springing direct from 
 the inherent powers and activity of the human mind, and from 
 continually renewed introspection of that inner world of thought 
 of which the phenomena are as varied and require as close 
 attention to discern as those of the outer physical world; that 
 it is unceasingly calling forth the faculties of observation and 
 comparison; that one of its principal weapons is induction; 
 that is has frequent recourse to experimental trial and veri- 
 fication; and that it affords a boundless scope for the exercise 
 of the highest efforts of imagination and invention." 
 
 Huxley never replied; convinced or not, he had sufScient 
 sagacity to see that he had ventured far beyond his depth. 
 In the portion of the address quoted, Sylvester adds paren- 
 thetically a clause which expresses his theory of mathematical 
 knowledge. He says that the inner world of thought in each 
 individual man (which is the world of observation to the mathe- 
 matician) may be conceived to stand in somewhat the same 
 general relation of correspondence to the outer physical world 
 as an object to the shadow projected from it. To him the 
 mental order was more real than the world of sense, and the 
 foundation of mathematical science was ideal, not experimental. 
 
 By this time Sylvester had received most of the high dis- 
 tinctions, both domestic and foreign, which are usually awarded 
 to a mathematician of the first rank in his day. But a dis- 
 continuity was at hand. The War Office issued a regulation 
 whereby officers of the army were obliged to retire on half pay 
 on reaching the age of 55 years. Sylvester was a professor in 
 a Military College; in a few. months, on his reaching the pre- 
 scribed age, he was retired on half pay. He felt that though 
 no longer fit for the field he was still fit for the classroom. And 
 he felt keenly the diminution in his income. It was about this 
 time that he issued a small volume — the only book he ever 
 published; not on mathematics, as you may suppose, but 
 
114 TEN BRITISH MATHEMATICIANS 
 
 entitled The Laws of Verse. He must have prided himself a 
 good deal on this composition, for one of his last letters in Nature 
 is signed "J. J. Sylvester, author of The Laws of Verse." He 
 made some excellent translations from Horace and from German 
 poets; and like Sir W. R. Hamilton he was accustomed to express 
 his feelings in sonnets. 
 
 The break in his life appears to have discouraged Sylvester 
 for the time being from engaging in any original research. But 
 after three years a Russian mathematician named Tschebicheff, 
 a professor in the University of Saint Petersburg, visiting 
 Sylvester in London, drew his attention to the discovery by a 
 Russian student named Lipkin, of a mechanism for drawing 
 a perfect straight line. Mr. Lipkin received from the Russian 
 Government a substantial award. It was found that the same 
 discovery had been made several years before by M. Peaucellier, 
 an officer in the French army, but failing to be recognized at 
 its true value had dropped into oblivion. Sylvester introduced 
 the subject into England in the form of an evening lecture before 
 the Royal Institution, entitled " On recent discoveries in mechan- 
 ical conversion of motion." The Royal Institution of London 
 was founded to promote scientific research; its professors have 
 been such men as Davy, Faraday, Tyndall, Dewar. It is not 
 a teaching institution, but it provides for special courses of 
 lectures in the afternoons and for Friday evening lectures by 
 investigators of something new in science. The evening lec- 
 tures are attended by fashionable audiences of ladies and gentle- 
 men in full dress. 
 
 Euclid bases his Elements on two postulates; first, that a 
 straight line can be drawn, second, that a circle can be described. 
 It is sometimes expressed in this way; he postulates a ruler and 
 compass. The latter contrivance is not difficult to construct, 
 because it does not involve the use of a ruler or a compass in 
 its own construction. But how is a ruler to be made straight, 
 unless you already have a ruler by which to test it? The 
 problem is to devise a mechanism which shall assume the second 
 postulate only, and be able to satisfy the first. ■ It is the mechan- 
 ical problem of converting motion in a circle into motion in 
 
JAMES JOSEPH SYLVESTER 115 
 
 a Straight line, without the use of any guide. James Watt, 
 the inventor of the steam-engine, tackled the problem with all 
 his might, but gave it up as impossible. However, he succeeded 
 in finding a contrivance which solves the problem very approxi- 
 mately. Watt's parallelogram, employed in nearly every beam- 
 engine, consists of three links; of which AC and BD are 
 equal, and have fixed pivots at A and B respectively. The 
 link CD is of such a length that AC and BD are parallel 
 when horizontal. The tracing 
 
 AO <?c 
 
 point is attached to the middle 
 
 point of CD. When C and D 
 
 '■ ^ , Q^) OB 
 
 move round their pivots, the 
 
 tracing point describes a straight line very approximately, so 
 long as the arc of displacement is small. The complete figure 
 which would be described is the figure of 8, and the part utilized 
 is near the point of contrary flexure. 
 
 A linkage giving a closer approximation to a straight line 
 was also invented by the Russian mathematician before men- 
 tioned— Tschebicheff; it likewise made use of three links. But 
 the linkage invented by Peaucellier and later by Lipkin had 
 seven pieces. The arms AB and AC are of equal length, and 
 
 have a fixed pivot at A. The links 
 DB, BE, EC, CD are of equal length. 
 EF is an arm connecting E with the 
 fixed pivot F and is equal in length to 
 the distance between A and F. It is 
 readily shown by geometry that, as 
 --ifj- the point E describes a circle around 
 the center F, the point D describes 
 an exact straight line perpendicular to the line joining it and F. 
 The exhibition of this contrivance at work was the climax of 
 Sylvester's lecture. 
 
 In S}-lvester's audience were two mathematicians, Hart and 
 Kempe, who took up the subject for further investigation. Hart 
 perceived that the contrivances of Watt and of Tschebicheff 
 consisted of three links, whereas Peaucellier's consisted of seven. 
 Accordingly he searched for a contrivance of five links which 
 
116 TEN BRITISH MATHEMATICIANS 
 
 would enable a tracing point to describe a perfect straight line; 
 and he succeeded in inventing it. Kempe was a London barrister 
 whose specialty was ecclesiastical law. He and Sylvester worked 
 up the theory of linkages together, and discovered among other 
 things the skew pantograph. Kempe became so imbued with 
 linkage that he contributed to the Royal Society of London 
 a paper on the " Theory of Mathematical Form," in which he 
 explains all reasoning by means of linkages. 
 
 About this time (1877) the Johns Hopkins University was 
 organized at Baltimore, and Sylvester, at the age of 63, was 
 appointed the first professor of mathematics. Of his work 
 there as a teacher, one of his pupils. Dr. Fabian Franklin, thus 
 spoke in an address delivered at a memorial meeting in that 
 University: " The one thing which constantly marked Syl- 
 vester's lectures was enthusiastic love of the thing he was doing. 
 He had in the fullest possible degree, to use the French phrase, 
 the defect of this quality, for as he almost always spoke with 
 enthusiastic ardor, so it was almost never possible for him to 
 speak on matters incapable of evoking this ardor. In other 
 words, the substance of his lectures had to consist largely of his 
 own work, and, as a rule, of work hot from the forge. The 
 consequence was that a continuous and systematic presentation 
 of any extensive body of doctrine already completed was not to 
 be expected from him. Any unsolved difficulty, any suggested 
 extension, such as would have been passed by with a mention 
 by other lecturers, became inevitably with him the occasion of 
 a digression which was sure to consume many weeks, if indeed 
 it did not take him away from the original object permanently. 
 Nearly all of the important memoirs which he published, while 
 in Baltimore, arose in this way. We who attended his lectures 
 may be said to have seen these memoirs in the making. He 
 would give us on the Friday the outcome of his grapplings with 
 the enemy since the Tuesday lecture. Rarely can it have 
 fallen to the lot of any class to follow so completely the workings 
 of the mind of the master. Not only were all thus privileged to 
 see ' the very pulse of the machine,' to learn the spring and 
 motive of the successive steps that led to his results, but we 
 
JAMES JOSEPH SYLVESTER 117 
 
 were set aglow by the delight and admiration which, with perfect 
 naivete and with that luxuriance of language peculiar to him, 
 Sylvester lavished upon these results. That in this enthusiastic 
 admiration he sometimes lacked the sense of proportion caimot 
 be denied. A result announced at one lecture and hailed with 
 loud acclaim as a marvel of beauty was by no means sure of 
 not being found before the next lecture to have been erroneous; 
 but the Esther that supplanted this Vashti was quite certain 
 to be found still more supremely beautiful. The fundamental 
 thing, however, was not this occasional extravagance, but the 
 deep and abiding feeling for truth and beauty which underlay 
 it. No young man of generous mind could stand before that 
 superb grey head and hear those expositions of high and dear- 
 bought truths, testifying to a passionate devotion undimmed 
 by years or by arduous labors, without carrying away that 
 which ever after must give to the pursuit of truth a new and 
 deeper significance in his mind." 
 
 One of Sylvester's principal achievements at Baltimore was 
 the founding of the American Journal of Mathematics, which, 
 at his suggestion, took the quarto form. He aimed at estab- 
 lishing a mathematical journal in the English language, which 
 should equal Liouville's Journal in France, or Crelle's Journal 
 in Germany. Probably his best contribution to the American 
 Journal consisted in his "Lectures on Universal Algebra"; 
 which, however, were left unfinished, like a great many other 
 projects of his. 
 
 Sylvester had that quality of absent-mindedness which is 
 popularly supposed to be, if not the essence, at least an invariable 
 accompaniment, of a distinguished mathematician. Many 
 stories are related on this point, which, if not aU true, are at 
 least characteristic. Dr. Franklin describes an instance which 
 actually happened in Baltimore. To illustrate a theory of 
 versification contained in his book The Laws of Verse, Sylvester 
 prepared a poem of 400 lines, all rhyming with the name Rosa- 
 lind or Rosalind; and it was announced that the professor would 
 read the poem on a specified evening at a specified hour at the 
 Peabody Institute. At the time appointed there was a large 
 
118 TEN BRITISH MATHEMATICIANS 
 
 turn-out of ladies and gentlemen. Prof. Sylvester, as usual, 
 had a number of footnotes appended to his production; and he 
 announced that in order to save interruption in reading the 
 poem itself, he would first read the footnotes. The reading of 
 the footnotes suggested various digressions to his imagination; 
 an hour had passed, still no poem; an hour and a half passed 
 and the striking of the clock or the unrest of his audience 
 reminded him of the promised poem. He was astonished to 
 find how time had passed, excused all who had engagements, 
 and proceeded to read the RosaHnd poem. 
 
 In the summer of 1881 I visited London to see the Electrical 
 Exhibition in the Crystal Palace^one of the earliest exhibitions 
 devoted to electricity exclusively. I had made some investi- 
 gations on the electric discharge, using a Holtz machine where 
 De LaRue used a large battery of cells. Mr. De LaRue was 
 Secretary of the Royal Institution; he gave me a ticket to a 
 Friday evening discourse to be delivered by Mr. Spottiswoode, 
 then president of the Royal Society, on the phenomena of the 
 intensive discharge of electricity through gases; also an invi- 
 tation to a dinner at his own house to be given prior to the 
 lecture. Mr. Spottiswoode, the lecturer for the evening, was 
 there; also Prof. Sylvester. He was a man rather under the 
 average height, with long gray beard and a profusion of gray 
 locks round his head surmounted by a great dome of forehead. 
 He struck me as having the appearance of an artist or a poet 
 rather than of an exact scientist. After dinner he conversed 
 very eloquently with an elderly lady of title, while I conversed 
 with her daughter. Then cabs were announced to take us to 
 the Institution. Prof. Sylvester and I, being both bachelors, 
 were put in a cab together. The professor, who had been so 
 eloquent with the lady, said nothing; so I asked him how he 
 liked his work at the Johns Hopkins University. " It is very 
 pleasant work indeed," said he, " and the young men who 
 study there are all so enthusiastic." We had not exhausted 
 that subject before we reached our destination. We went up 
 the stairway together, then Sylvester dived into the library to 
 see the last number of Comptes Rendus (in which he published 
 
JAMES JOSEPH SYLVESTER 
 
 119 
 
 many of his results at that time) and I saw him no more. I have 
 always thought it very doubtful whether he came out to hear 
 Spottiswoode's lecture. 
 
 We have seen that H. J. S. Smith, the Savilian professor of 
 Geometry at Oxford, died in 1883. Sylvester's friends urged 
 his appointment, with the result that he was elected. After two 
 years he delivered his inaugural lecture; of which the subject 
 was differential invariants, termed by him reciprocants. An 
 
 . dH 
 elementary reciprocant is -7^, for if -7-^ = o then -5-7; = o. 
 
 He 
 
 looked upon this as the 
 the " chrysalis " 
 
 grub " form, and developed from it 
 
 and the " imago 
 
 dH 
 
 d^4> 
 
 d<t> 
 
 dx" 
 
 dxdy 
 
 dx' 
 
 d^4> 
 
 d^4> 
 
 d4> 
 
 dxdy 
 
 dy^ 
 
 dy' 
 
 d4 
 
 i± 
 
 
 dx 
 
 dy 
 
 
 d^^ 
 
 ^2$ 
 
 £^2$ 
 
 dx^ 
 
 dxdy 
 
 dxdr 
 
 ^2$ 
 
 ^2$ 
 
 rf2# 
 
 dxdy 
 
 dy"" 
 
 dydr 
 
 ^2* 
 
 ^2$ 
 
 ^2$ 
 
 dxdr 
 
 dydr 
 
 dr^' 
 
 You will observe that the chrysaHs expression is unsymmetrical; 
 the place of a ninth term is vacant. It moved Sylvester's poetic 
 imagination, and into his inaugural lecture he interjected the 
 following sonnet: 
 
 To A Missing Member of a Family GROxn" of Teems in 
 AN Algebraical Formula: 
 
 Lone and discarded one! divorced by fate, 
 Far from thy wished-for fellows — whither art flown? 
 Where lingerest thou in thy bereaved estate, 
 Like some lost star, or buried meteor stone? 
 
120 TEN BRITISH MATHEMATICIANS 
 
 Thou minds't me much of that presumptuous one, 
 
 Who loth, aught less than greatest, to be great.. 
 
 From H.aven's immensity fell headlong down 
 
 To live forlorn, self-centred, desolate: 
 
 Or who, new Heraklid, hard exile bore. 
 
 Now buoyed by hope, now stretched on rack of fear, 
 
 Till throned Astrsea, wafting to his ear 
 
 Words of dim portent through the Atlantic roar, 
 
 Bade him " the sanctuary of the Muse revere 
 
 And strew with flame the dust of Isis' shore." 
 
 This inaugural lecture was the beginning of his last great 
 contribution to mathematics, and the subsequent lectures of 
 that year were devoted to his researches in that line. Smith 
 and Sylvester were akin in devoting attention to the theory of 
 numbers, and also in being eloquent speakers. But in other 
 respects the Oxonians found a great difference. Smith had 
 been a painstaking tutor; Sylvester could lecture only on his 
 own researches, which were not popular in a place so wholly 
 given over to examinations. Smith was an incessantly active 
 man of affairs; Sylvester became the subject of melancholy 
 and complained that he had no friends. 
 
 In 1872 a deputy professor was appointed. Sylvester re- 
 moved to London, and lived mostly at the Athenaeum Club. 
 He was now 78 years of age, and suffered from partial loss of 
 sight and memory. He was subject to melancholy, and his 
 condition was indeed " forlorn and desolate." His nearest rela- 
 tives were nieces, but he did not wish to ask their assistance. 
 One day, meeting a mathematical friend who had a home in Lon- 
 don, he complained of the fare at the Club, and asked his friend 
 to help him find suitable private apartments where he could have 
 better cooking. They drove about from place to place for a 
 whole afternoon, but none suited Sylvester. It grew late: Syl- 
 vester said, " You have a pleasant home: take me there," and 
 this was done. Arrived, he appointed one daughter his reader 
 and another daughter his amanuensis. " Now," said he, "I feel 
 comfortably installed; don't let my relatives know where I 
 am." The fire of his temper had not dimmed with age, and it 
 required all the Christian fortitude of the ladies to stand his 
 
JAMES JOSEPH SYLVESTER 121 
 
 exactions. Eventually, notice had to be sent to his nieces to 
 come and take charge of him. He died on the 15th of March, 
 1897, in the 83d year of his age, and was buried in the Jewish 
 cemetery at Dalston. 
 
 As a theist, Sylvester did not approve of the destructive 
 attitude of such men as CUfford, in matters of religion. In the 
 early days of his career he suffered much from the disabilities 
 attached to his faith, and they were the prime cause of so much 
 " fighting the world." He was, in all probability, a greater 
 mathematical genius than Cayley; but the environment in 
 which he lived for some years was so much less favorable that 
 he was not able to accomplish an equal amount of soKd work. 
 Sylvester's portrait adorns St. John's College, Cambridge. A 
 memorial fund of £1500 has been placed in the charge of the 
 Royal Society of London, from the proceeds of which a medal 
 and about £100 in money is awarded triennially for work 
 done in pure mathematics. The first award has been made to 
 M. Henri Poincare of Paris, a mathematician for whom Sylvester 
 had a high professional and personal regard. 
 
THOMAS PENYNGTON KIRKMAN* 
 (1806-1895) 
 
 Thomas Penyngton Kiekman was born on March 31, 1806, 
 at Bolton in Lancashire. He was the son of John Kirkman, 
 a dealer in cotton and cotton waste; he had several sisters but 
 no brother. He was educated at the Grammar School of Bolton, 
 where the tuition was free. There he received good instruction 
 in Latin and Greek, but no instruction in geometry or algebra; 
 even Arithmetic was not then taught in the headmaster's upper 
 room. He showed a decided taste for study and was by far 
 the best scholar in the school. His father, who had no taste 
 for learning and was succeeding in trade, was determined that 
 his only son should follow his own business, and that without 
 any loss of time. The schoolmaster tried to persuade the father 
 to let his son remain at school; and the vicar also urged the 
 father, saying that if he would send his son to Cambridge Uni- 
 versity, he would guarantee for sixpence that the boy would 
 win a fellowship. But the father was obdurate; young Kirk- 
 man was removed from school, when he was fourteen years of 
 age, and placed at a desk in his father's office. WhUe so engaged, 
 he continued of his own accord his study of Latin and Greek, 
 and added French and German. 
 
 After ten years spent in the counting room, he tore away 
 from his father, secured the tuition of a young Irish baronet, 
 Sir John Blunden, and entered the University of Dublin with 
 the view of passing the examinations for the degree of B.A. 
 There he never had instruction from any tutor. It was not 
 until he entered Trinity College, Dublin, that he opened any 
 mathematical book. He was not of course abreast with men 
 who had good preparation. What he knew of mathematics, 
 
 * This Lecture was delivered April 20, 1903. — ^Editors. 
 
 122 
 
THOMAS PENYNGTON KIRKMAN 123 
 
 he owed to his own study, having never had a single hour's 
 instruction from any person. To this self-education is due, it 
 appears to me, both the strength and the weakness to be found 
 in his career as a scientist. However, in his college course he 
 obtained honors, or premiums as they are called, and graduated 
 as a moderator, something like a wrangler. 
 
 Returning to England in 1835, when he was 29 years old, 
 he was ordained as a minister in the Church of England. He 
 was a curate for five years, first at Bury, afterwards at Lymm ; 
 then he became the vicar of a newly-formed parish — Croft with 
 Southworth in Lancashire. This parish was the scene of his 
 life's labors. The income of the benefice was not large, about 
 £200 per annum; for several years he supplemented this by 
 taking pupils. He married, and property which came to his 
 wife enabled them to dispense with the taking of pupils. His 
 father became poorer, but was able to leave some property to 
 his son and daughters. His parochial work, though smaU, was 
 discharged with enthusiasm; out of the roughest material he 
 formed a parish choir of boys and girls who could sing at sight 
 any four-part song put before them. After the private teach- 
 ing was over he had the leisure requisite for the great mathe- 
 matical researches in which he now engaged. 
 
 Soon after Kirkman was settled at Croft, Sir WiUiam Rowan 
 Hamilton began to publish his quaternion papers and, being a 
 graduate of Dublin University, Kirkman was naturally one of 
 the first to stud}' the new analysis. As the fruit of his medi- 
 tations he contributed a paper to the Philosophical Magazine 
 " On pluquaternions and homoid products of sums of n squares." 
 He proposed the appellation " pluquaternions " for a linear 
 expression involving more than three imaginaries (the i, j, k of 
 Hamilton), " not dreading " he says, " the pluperfect criticism 
 of grammarians, since the convenient barbarism is their own." 
 Hamilton, writing to De Morgan, remarked " Kirkman is a 
 very clever fellow," where the adjective has not the American 
 colloquial meaning but the English meaning. 
 
 For his own education and that of his pupils he devoted 
 much attention to mathematical mnemonics, studying the 
 
124 TEN BRITISH MATHEMATICIANS 
 
 Memoria Technica of Grey. In 1851 he contributed a paper on 
 the subject to the Literary and Philosophical Society of Man- 
 chester, and in 1852 he published a book, First Mnemonical Les- 
 sons in Geometry, Algebra, and Trigonometry, which is dedicated 
 to his former pupil. Sir John Blunden. De Morgan pronounced 
 it " the most curious crochet I ever saw," which was saying a 
 great deal, for De Morgan was familiar with many quaint books 
 in mathematics. In the preface he says that much of the dis- 
 taste for mathematical study springs largely from the difficulty 
 of retaining in the memory the previous results and reasoning. 
 " This difficulty is closely connected with the unpronounceable- 
 ness of the formulae; the memory of the tongue and the ear art 
 not easily turned to account; nearly everything depends on the 
 thinking faculty or on the practice of the eye alone. Hence 
 many, who see hardly anything formidable in the study of a 
 language, look upon mathematical acquirements as beyond 
 their power, when in truth they are very far from being so. 
 My object is to enable the learner to ' talk to himself,' in rapid, 
 vigorous and suggestive syllables, about the matters which he 
 must digest and remember. I have sought to bring the memory 
 of the vocal organs and the ear to the assistance of the reasoning 
 faculty and have never scrupled to sacrifice either good grammar 
 or good EngHsh in order to secure the requisites for a useful 
 mnemonic, which are smoothness, condensation, and jingle. 
 
 As a specimen of his mnemonics we may take the cotangent 
 formula in spherical trigonometry: 
 
 cot .4 sin C+cos b cos C = cot a sin b 
 
 To remember this formula most masters then required some aid 
 to the memory; for instance the following: If in any spherical 
 triangle four parts be taken in succession, such as AbCa, consist- 
 ing of two means bC and two extremes Aa, then the product of 
 the cosines of the two means is equal to the sine of the mean 
 side X cotangent of the extreme side minus sine of the mean 
 angle X cotangent of the extreme angle, that is 
 
 cos b cos C = smb cot a— sin C cot A . 
 
THOMAS PENYNGTON KIEKMAN 125 
 
 This is an appeal to the reason. Kirkman, however, proceeds 
 on the principle of appealing to the memory of the ear, of the 
 tongue, and of the lips altogether; a true memoria technica. 
 He distinguishes the large letter from the small by calling them 
 Ang, Bang, Cang {ang from angle in contrast to side). To 
 make the formula more euphoneous he drops the s from cos 
 and the n from sin. Hence the formula is 
 
 cot Ang si Cang and co h co Cang are cot a si 6 
 
 which is to be chanted till it becomes perfectly familiar to the 
 ear and the lips. The former rule is a hint offered to the judg- 
 ment; Kirkman's method is something to be taught by rote. 
 In his book Kirkman makes much use of verse, in the turning 
 of which he was very skillful. 
 
 In the early part of the nineteenth century a publication 
 named the Lady's and Gentlemen's Diary devoted several columns 
 to mathematical problems. In 1844 the editor offered a prize 
 for the solution of the following question: " Determine the num- 
 ber of combinations that can be made out of n symbols, each 
 combination having p symbols, with this limitation, that no 
 combination of q symbols which may appear in any one of 
 them, may be repeated in any other." This is a problem of 
 great difficulty; Kirkman solved it completely for the special 
 case of ^ = 3 and 5 = 2 and printed his results in the second 
 volume of the Cambridge and Dublin Mathematical Journal. 
 As a chip off this work he published in the Diary for 1850 the 
 famous problem of the fifteen schoolgirls as follows: " Fifteen 
 young ladies of a school walk out three abreast for seven days 
 in succession; it is required to arrange them daily so that no two 
 shall walk abreast more than once." To form the schedules 
 for seven days is not difficult; but to find all the possible 
 schedules is a different matter. Kirkman found all the possible 
 combinations of the fifteen young ladies in groups of three to 
 be 35, and the problem was also considered and solved by Cayley, 
 and has been discussed by many later writers; Sylvester gave 
 91 as the greatest number of days; and he also intimated that 
 the principle of the puzzle was known to him when an under- 
 
126 TEN BRITISH MATHEMATICIANS 
 
 graduate at Cambridge, and that he had given it to fellow 
 undergraduates. Kirkman replied that up to the time he pro- 
 posed the problem he had neither seen Cambridge nor met 
 Sylvester, and narrated how he had hit on the question. 
 
 The Institute of France offered several times in succession 
 a prize for a memoir on the theory of the polyedra; this fact 
 together with his work in combinations led Kirkman to take 
 up the subject. He always writes polyedron not polyhedron; 
 for he says we write periodic not perihodic. When Kirkman 
 began work nothing had been done beyond the very ancient 
 enumeration of the five regular solids and the simple combi- 
 nations of crystallography. His first paper, " On the represen- 
 tation and enumeration of the polyedra," was communicated 
 in 1850 to the Literary and Philosophical Society of Manchester. 
 He starts with the well-known theorem P-\-S = L+2, where P 
 is the number of points or summits, 5 the number of plane 
 bounding surfaces and L the number of Hnear edges in a geo- 
 metrical solid. " The question — how many w-edrons are 
 there? — has been asked, but it is not likely soon to receive a 
 definite answer. It is far from being a simple question, even 
 when reduced to the narrower compass — how many n-edrons 
 are there whose summits are all trihedral "? He enumerated 
 and constructed the fourteen 8-edra whose faces are all tri- 
 angles. 
 
 In 1858 the French Institute modified its prize question. 
 As the subject for the concours of 1861 was announced: "Per- 
 fectionner en quelque point important la theorie geometrique 
 des polyedres," where the indefiniteness of the question indi- 
 cates the very imperfect state of knowledge on the subject. 
 The prize offered was 3000 francs. Kirkman appears to have 
 worked at it with a view of competing, but he did not send in 
 his memoir. Cayley appears to have intended to compete. 
 The time was prolonged for a year, but there was no award and 
 the prize was taken down. Kirkman communicated his results 
 to the Royal Society through his friend Cayley, and was soon 
 elected a Fellow. Then he contributed directly an elaborate 
 paper entitled " Complete theory of the Polyedra." In the 
 
THOMAS PENYNGTON KIEKMAN 127 
 
 preface he says, " The following memoir contains a complete 
 solution of the classification and enumeration of the P-edra 
 Q-acra. The actual construction of the solids is a task imprac- 
 ticable from its magnitude, but it is here shown that we can 
 enumerate them with an accurate account of their symmetry 
 to any values of P and Q." The memoir consisted of 21 sec- 
 tions; only the two introductory sections, occupying 45 quarto 
 pages, were printed by the Society, while the others still remain 
 in manuscript. During following years he added many con- 
 tributions to this subject. 
 
 In 1858 the French Academy also proposed a problem in the 
 Theory of Groups as the subject for competition for the grand 
 mathematical prize in i860: " Quels peuvent etre les nombres 
 de valeurs des fonctions bien definies qui contiennent un nombre 
 donne de lettres, et comment peut on former les fonctions pour 
 lesquelles il existe un nombre donne de valeurs? " Three 
 memoirs were presented, of which Kirkman's was one, but no 
 prize was awarded. Not the shghtest summary was vouch- 
 safed of what the competitors had added to science, although 
 it was confessed that all had contributed results both new and 
 important; and the question, though proposed for the first 
 time for the year i860, was withdrawn from competition con- 
 trary to the usual custom of the Academy. Kirkman con- 
 tributed the results of his investigation to the Manchester 
 Society under the title " The complete theory of groups, being 
 the solution of the mathematical prize question of the French 
 Academy for i860." In more recent years the theory of groups 
 has engaged the attention of many mathematicians in Germany 
 and America; so far as British contributors are concerned 
 Kirkman was the first and still remains the greatest. 
 
 In 1861 the British Association met at Manchester; it was 
 the last of its meetings which Sir William Rowan Hamilton 
 attended. After the meeting Hamilton visited Kirkman at his 
 home in the Croft rectory, and that meeting was no doubt a 
 stimulus to both. As regards pure mathematics they were 
 probably the two greatest in Britain ; both felt the loneliness of 
 scientific work, both were metaphysicians of penetrating power, 
 
128 TEN BRITISH MATHEMATICIANS 
 
 both were good versifiers if not great poets. Of nearly the same 
 age, they were both endowed with splendid physique; but the 
 care which was taken of their health was very different; in 
 four years Hamilton died but Kirkman lived more than 30 years 
 longer. 
 
 About 1862 the Educational Times, a monthly periodical 
 published in London, began to devote several columns to the 
 proposing and solving of mathematical problems, taking up 
 the work after the demise of the Diary. This matter was after- 
 wards reprinted in separate volumes, two for each year. In 
 these reprints are to be found many questions proposed by 
 Kirkman; they are generally propounded in quaint verse, and 
 many of them were suggested by his study of combinations. A 
 good specimen is " The Revenge of Old King Cole " 
 
 " Full oft ye have had your fiddler's fling, 
 
 For your own fun over the wine; 
 
 And now " quoth Cole, the merry old king, 
 
 " Ye shall have it again for mine. 
 
 My realm prepares for a week of joy 
 
 At the coming of age of a princely boy — 
 
 Of the grand six days procession in square, 
 
 In all your splendour dressed. 
 
 Filling the city with music rare 
 
 From fiddlers five abreast," etc. 
 
 The problem set forth by this and other verses is that of 
 25 men arranged in five rows on Monday. Shifting the second 
 column one step upward, the third two steps, the fourth three 
 
 Monday Tuesday Wednesday Thursday 
 
 ABCDE AGMSY ALWIT AQHXO 
 
 FGHIJ FLRXE FQCNY FVMDT 
 
 KLMNO KQWDJ KVHSE KBRIY 
 
 PQRST PVCIO PBMXJ PGWNE 
 
 UVWXY UBHNT NGRDO ULCSJ 
 
 Steps, and the fifth four steps gives the arrangement for Tuesday. 
 Applying the same rule to Tuesday gives Wednesday's array, 
 and similarly are found those for Thursday and Friday. In 
 
THOMAS PENYNGTON KIEKMAN 129 
 
 none of these can the same two men be found in one row. But 
 the rule fails to work for Saturday, so that a special arrangement 
 must be brought in which I leave to my hearers to work out. 
 This problem resembles that of the fifteen schoolgirls. 
 
 The Rev. Kirkman became at an early period of his life a 
 broad churchman. About 1863 he came forward in defense of 
 the Bishop of Colenso, a mathematician, and later he contributed 
 to a series of pamphlets published in aid of the cause of "Free 
 Enquiry and Free Expression." In one of his letters to me 
 Kirkman writes as follows: " The Life of Colenso by my friend 
 Rev. Sir George Cox, Bart., is a most charming book; and 
 the battle of the Bishops against the lawyers in the matter of 
 the vacant see of Natal, to which Cox is the bishop-elect, is 
 exciting. Canterbury refuses to ask, as required, the Queen's 
 mandate to consecrate him. The Natal churchmen have just 
 petitioned the Queen to make the Primate do his duty accord- 
 ing to law. Natal was made a See with perpetual succession, 
 and is endowed. The endowment has been lying idle since 
 Colenso's death in 1883; and the bishops who have the law 
 courts dead against them here are determined that no successor 
 to Colenso shall be consecrated. There is a Bishop of South 
 African Church there, whom they thrust in while Colenso lived, 
 on pretense that Colenso was excommunicate. We shall soon 
 see whether the lawyers or the bishops are to win." It was 
 Kirkman's own belief that his course in this matter injured 
 his chance of preferment in the church; he never rose above 
 being rector of Croft. 
 
 While a broad churchman the Rev. Mr. Kirkman was very 
 vehement against the leaders of the materiaUstic philosophy. 
 Two years after Tyndall's Belfast address, in which he announced 
 that he could discern in matter the promise and potency of 
 every form of life, Kirkman published a volume entitled Philoso- 
 phy without Assumptions, in which he criticises in very vigorous 
 style the materialistic and evolutional philosophy advocated by 
 Mill, Spencer, Tyndall, and Huxley. In ascribing everything 
 to matter and its powers or potencies he considers that they 
 turn philosophy upside down. He has, he writes, first-hand 
 
130 TEN BRITISH MATHEMATICIANS 
 
 knowledge of himself as a continuous person, endowed with 
 will; and he infers that there are will forces around; but he 
 sees no evidence of the existence of matter. Matter is an 
 assumption and forms no part of his philosophy. He relies on 
 Boscovich's theory of an atom as simply the center of forces. 
 Force he understands from his knowledge of will, but any other 
 substance he does not understand. The obvious difficulty in 
 this philosophy is to explain the belief in the existence of other 
 conscious beings — other will forces. Is it not the great assump- 
 tion which everyone is obliged to make; verified by experience, 
 but still in its nature an assumption? Kirkman tries to get 
 over this difficulty by means of a syllogism, the major premise 
 of which he has to manufacture, and which he presents to his 
 reason for adoption or rejection. How can a universal propo- 
 sition be easier to grasp than the particular case included in it? 
 If the mind doubts about an individual case, how can it be sure 
 about an infinite number of such cases? It is a petitio principii. 
 As a critic of the materiahstic philosophy Kirkman is more 
 successful. He criticises Herbert Spencer on free will as follows: 
 " The short chapter of eight pages on Will cost more philosophi- 
 cal toil than all the two volumes on Psychology. The author 
 gets himself in a heat, he runs himself into a corner, and brings 
 himself dangerously to bay. Hear him: ' To reduce the general 
 question to its simplest form; psychical changes either conform 
 to law, or they do not. If they do not conform to law, this work, 
 in common with all other works on the subject, is sheer non- 
 sense; no science of Psychology is possible. If they do conform 
 to law, there cannot be any such thing as free will.' Here we 
 see the horrible alternative. If the assertors of free will refuse 
 to commit suicide, they must endure the infinitely greater pang 
 of seeing Mr. Spencer hurl himself and his books into that 
 yawning guK, a sacrifice long devoted, and now by pitiless Fate 
 consigned, to the abysmal gods of nonsense. Then pitch him 
 down say I. Shall I spare him who tells me that my movements 
 in this orbit of conscious thought and responsibility are made 
 under ' parallel conditions ' with those of yon driven moon? 
 Shall I spare him who has juggled me out of my Will, my noblest 
 
THOMAS PENYNGTON KIRKMAN 131 
 
 attribute; who has hocuspocused me out of my subsisting 
 personality; and then, as a refinement of cruelty, has frightened 
 me out of the rest of my wits by forcing me to this terrific alterna- 
 tive that either the testimony of this Being, this Reason and this 
 Conscience is one ever-thundering lie, or else he, even he, has 
 talked nonsense? He has talked nonsense, I say it because I 
 have proved it. And every man must of course talk nonsense 
 who begins his philosophy with abstracts in the clouds instead 
 of building on the witness of his own self-consciousness. ' If 
 they do conform to law,' says Spencer, ' there cannot be any such 
 thing as free will.' The force of this seems to depend on his 
 knowledge of ' law.' When I ask. What does this writer know 
 of law — definite working law in the Cosmos? — the only answer 
 I can get is — Nothing, except a very little which he has picked 
 up, often malappropriately, as we have seen, among the mathe- 
 maticians. When I ask — What does he know about law?-^there 
 is neither beginning nor end to the reply. I am advised to read 
 his books about law, and to master the differentiations and inte- 
 grations of the coherences, the correlations, the uniformities, 
 and universalities which he has established in the abstract over 
 all space and all time by his vast experience and miraculous 
 penetration. I have tried to do this, and have found all pretty 
 satisfactory, except the lack of one thing — something like proof 
 of his competence to decide all that scientifically. When I 
 persist in my demand for such proof, it turns out at last — that he 
 knows by heart the whole Hymn Book, the Litanies, the Missal, 
 and the Decretals of the Must-be-ite religion ! ' Conform to 
 law.' Shall I tell you what he means by that? Exactly ninety- 
 nine hundredths of his meaning under the word law is must be." 
 Kirkman points out that the kind of proof offered by these 
 philosophers is a bold assertion of must-be-so. For instance 
 he mentions Spencer's evolution of consciousness out of the 
 unconscious: " That an effectual adjustment may be made 
 they (the separate impressions or constituent changes of a com- 
 plex correspondence to be coordinated) must be brought into 
 relation with each other. But this implies some center of com- 
 munication common to them all, through v/hich they severally 
 
132 TEN BRITISH MATHEMATICIANS 
 
 pass; and as they cannot pass through it simultaneously, they 
 must pass through it in succession. So that as the external 
 phenomena responded to become greater in number and more 
 complicated in kind, the variety and rapidity of the changes 
 to which this common center of communication is subject must 
 increase, there must result an unbroken series of those changes, 
 there must arise a consciousness." 
 
 The paraphrase which Kirkman gave of Spencer's definition 
 of Evolution commended itself to such great minds as Tait and 
 Clerk-Maxwell. Spencer's definition is : " Evolution is a change 
 from an indefinite incoherent homogeneity to a definite coherent 
 heterogeneity, through continuous differentiations and integra- 
 tions." Kirkman's' paraphrase is " Evolution is a change from 
 a nohowish untalkaboutable all-likeness, to a somehowish and 
 in-general-talkaboutable not-all-likeness, by continuous some- 
 thingelseifications and sticktogetherations." The tone of Kirk- 
 man's book is distinctly polemical and full of sarcasm. He 
 unfortimately wrote as a theologian rather than as a mathe- 
 matician. The writers criticised did not reply, although they 
 felt the edge of his sarcasm; and they acted wisely, for they 
 could not successfully debate any subject involving exact science 
 against one of the most penetrating mathematicians of the 
 nineteenth century. 
 
 We have seen that Hamilton appreciated Kirkman's genius; 
 so did Cayley, De Morgan, Clerk-Maxwell, Tait. One of Tait's 
 most elaborate researches was the enumeration and construc- 
 tion of the knots which can be formed in an endless cord — a 
 subject which he was induced to take up on account of its bear- 
 ing on the vortex theory of atoms. If the atoms are vortex 
 filaments their differences in kind, giving rise to differences in 
 the spectra of the elements, must depend on a greater or less 
 complexity in the form of the closed filament, and this difference 
 would depend on the knottiness of the filament. Hence the 
 main question was " How many different forms of knots are 
 there with any given small number of crossings?" Tait made 
 the investigation for three, four, five, six, seven, eight cross- 
 ings. Kirkman's investigations on the polyedra were much 
 
THOMAS PENYNGTON KIRKMAN 133 
 
 allied. He took up the problem and, with some assistance 
 from Tait, solved it not only for nine but for ten crossings. An 
 investigation by C. N. Little, a graduate of Yale University, 
 has confirmed Kirkman's results. 
 
 Through Professor Tait I was introduced to Rev. Mr. Kirk- 
 man; and we discussed the mathematical analysis of relation- 
 ships, formal logic, and other subjects. After I had gone to the 
 University of Texas, Kirkman sent me through Tait the follow- 
 ing question which he said was current in society: " Two boys, 
 Smith and Jones, of the same age, are each the nephew of the 
 other; how many legal solutions? " I set the analysis to work, 
 wrote out the solutions, and the paper is printed in the Proceed- 
 ings of the Royal Society of Edinburgh. There are four solu- 
 tions, rovided Smith and Jones are taken to be mere arbitrary, 
 names; if the convention about surnames holds there are only 
 two legal solutions. On seeing my paper Kirkman sent the 
 question to the Educational Times in the following improved 
 
 form: 
 
 Baby Tom of baby Hugh 
 
 The nephew is and uncle too; 
 
 In how many ways can this be true? 
 
 Thomas Penyngton Kirkman died on February 3, 1895, 
 having very nearly reached the age of 89 years. I have found 
 only one printed notice of his career, but all his writings are 
 mentioned in the new German Encyclopedia of Mathematics. 
 He was an honorary member of the Literary and Philosophical 
 Societies of Manchester and of Liverpool, a Fellow of the Royal 
 Society, and a foreign member of the Dutch Society of Sciences 
 at Haarlem. I may close by a quotation from one of his letters: 
 " What I have done in helping busy Tait in knots is, like the 
 much more difficult and extensive things I have done in polyedra 
 or groups, not at likely to be talked about intelligently by people 
 so long as I Hve. But it is a faint pleasure to think it wiU one 
 day win a little praise." 
 
ISAAC TODHUNTER* 
 
 (i 820-1884) 
 
 Isaac Todhunter was born at Rye, Sussex, 23 Nov., 1820. 
 He was the second son of George Todhunter, Congregationalist 
 minister of the place, and of Mary his wife, whose maiden name 
 was Hume, a Scottish surname. The minister died of con- 
 sumption when Isaac was six years old, and left his family, 
 consisting of wife and four boys, in narrow circumstances. The 
 widow, who was a woman of strength, physically and mentally, 
 moved to the larger town of Hastings in the same county, and 
 opened a school for girls. After some years Isaac was sent to 
 a boys' school in the same town kept by Robert Carr, and sub- 
 sequently to one newly opened by a Mr. Austin from London; 
 for some years he had been unusually backward in his studies, 
 but under this new teacher he made rapid progress, and his 
 career was then largely determined. 
 
 After his school days were over, he became an usher or 
 assistant master with Mr. Austin in a school at Peckham; and 
 contrived to attend at the same time the evening classes at 
 University College, London. There he came under the great 
 educating influence of De Morgan, for whom in after years he 
 always expressed an unbounded admiration; to De Morgan 
 " he owed that interest in the history and bibliography of 
 science, in moral philosophy and logic which determined the 
 course of his riper studies." In 1839 he passed the matriculation 
 examination of the University of London, then a merely examin- 
 ing body, winning the exhibition for mathematics (£30 for two 
 years); in 1842 he passed the B.A. examination carrying off 
 a mathematical scholarship (of £50 for three years) ; and in 1844 
 obtained the degree of Master of Arts with the gold medal 
 
 * This Lecture was delivered April 13, 1904. — Editors. 
 134 
 
ISAAC TODHUNTER 135 
 
 awarded to the candidate who gained the greatest distinction 
 in that examination. 
 
 Sylvester was then professor of natural philosophy in Uni- 
 versity College, and Todhunter studied under him. The 
 writings of Sir John Herschel also had an influence; for Tod- 
 hunter wrote as follows {Conflict of Studies, p. 66): "Lei me 
 at the outset record my opinion of mathematics; I cannot do 
 this better than by adopting the words of Sir J. Herschel, 
 to the influence of which I gratefully attribute the direction of 
 my own early studies. He says of Astronomy, ' Admission to 
 its sanctuary can only be gained by one means, — sound and 
 sufficient knowledge of mathematics, the great instrument of 
 all exact inquiry, without which no man can ever make such 
 advances in this or any other of the higher departments of 
 science as can entitle him to form an independent opinion on 
 any subject of discussion within their range.' " 
 
 When Todhunter graduated as M.A. he was 24 years of age. 
 Sylvester had gone to Virginia, but De Morgan remained. The 
 latter advised him to go through the regular course at Cambridge; 
 his name was now entered at St. John's College. Being some- 
 what older, and much more brilliant than the honor men of 
 his year, he was able to devote a great part of his attention to 
 studies beyond those prescribed. Among other subjects he 
 took up Mathematical Electricity. In 1848 he took his B.A. 
 degree as senior wrangler, and also won the first Smith's prize. 
 
 While an undergraduate Todhunter lived a very secluded 
 life. He contributed along with his brothers to the support 
 of their mother, and he had neither money nor time to spend 
 on entertainments. The following legend was applied to him, 
 if not recorded of him: " Once on a time, a senior wrangler 
 gave a wine party to celebrate his triumph. Six guests took 
 their seats round the table. Turning the key in the door, he 
 placed one bottle of wine on the table asseverating with unction, 
 ' None of you will leave this room while a single drop remains.' " 
 
 At the University of Cambridge there is a foundation which 
 provides for what is called the Burney prize. According to the 
 regulations the prize is to be awarded to a graduate of the 
 
136 TEN BRITISH MATHEMATICIANS 
 
 University who is not of more than three years' standing from 
 admission to his degree and who shall produce the best English 
 essay " On some moral or metaphysical subject, or on the 
 existence, nature and attributes of God, or on the truth and 
 evidence of the Christian religion." Todhunter in the course 
 of his first postgraduate year submitted an essay on the thesis 
 that " The doctrine of a divine providence is inseparable from 
 the belief in the existence of an absolutely perfect Creator." 
 This essay received the prize, and was printed in 1849. 
 
 Todhunter now proceeded to the degree of M.A., and unhke 
 his mathematical instructors in University College, De Morgan 
 and Sylvester, he did not parade his non-conformist principles, 
 but submitted to the regulations with as good grace as possible. 
 He was elected a fellow of his college, but not immediately, 
 probably on account of his being a non-conformist, and appointed 
 lecturer on mathematics therein ; he also engaged for some time 
 in work as a private tutor, having for one of his pupils P. G. 
 Tait, and I beheve E. J. Routh also. 
 
 For a space of 15 years he remained a fellow of St. John's 
 College, residing in it, and taking part in the instruction. He 
 was very successful as a lecturer, and it was not long before he 
 began to publish textbooks on the subjects of his lectures. In 
 1853 ^^ published a textbook on Analytical Statics; in 1855 
 one on Plane Coordinate Geometry; and in 1858 Examples of 
 Analytical Geometry of Three Dimensions. His success in these 
 subjects induced him to prepare manuals on elementary mathe- 
 matics; his Algebra appeared in 1858, his Trigonometry in 1859, 
 his Theory of Equations in 1861, and his Euclid in 1862. Some 
 of his textbooks passed through many editions and have beeli 
 widely used in Great Britain and North America. Latterly 
 he was appointed principal mathematical lecturer in his college, 
 and he chose to drill the freshmen in Euclid and other elemen- 
 tary mathematics. 
 
 Within these years he also labored at some works of a more 
 strictly scientific character. Professor Woodhouse (who was 
 the forerunner of the Analytical Society) had written a history 
 of the calculus of variations, ending with the eighteenth century; 
 
ISAAC TODHUNTER 137 
 
 this work was much admired for its usefulness by Todhunter, 
 and as he felt a decided taste for the history of mathematics, 
 he formed and carried out the project of continuing the history 
 of that calculus during the nineteenth century. It was the 
 first of the great historical works which has given Todhunter 
 his high place among the mathematicians of the nineteenth 
 century. This history was published in 1861; in 1862 he was 
 elected a Fellow of the Royal Society of London. In 1863 he 
 was a candidate for the Sadlerian professorship of Mathe- 
 matics, to which Ca}ley was appointed. Todhunter was not 
 a mere mathematical specialist. He was an excellent linguist; 
 besides being a sound Latin and Greek scholar, he was famiUar 
 with French, German, Spanish, Italian and also Russian, Hebrew 
 and Sanskrit. He was likewise well versed in philosophy, and 
 for the two years 1863-5 ^ctcd as an Examiner for the Moral 
 Science Tripos, of which the chief founders were himself and 
 Whewell. 
 
 By 1864 the financial success of his books was such that he 
 was able to marry, a step which involved the resigning of his 
 fellowship. His wife was a daughter of Captain George Davics 
 of the Royal Navy, afterwards Admiral Davies. 
 
 As a fellow and tutor of St. John's College he had lived a 
 very secluded life. His relatives and friends thought he was a 
 confirmed baclielor. He had sometimes hinted that the grapes 
 were sour. For art he had little eye; for music no ear. " He 
 used to say he knew two tunes; one was ' God save the Queen,' 
 the other wasn't. The former he recognized by the people 
 standing up." As owls shun the broad da},-light he had shunned 
 the glare of parlors. It was therefore a surprise to his friends 
 and relatives when they were invited to his marriage in 1864. 
 Prof. Mayor records that Todhunter wrote to his fiancee, " You 
 will not forget, I am sure, tliat I have always been a student, 
 and alwa^■s shall be; but books shall not come into even distant 
 rivalry with you," and Prof. Mayor insinuated that thus fore- 
 armed, he calmly introduced to the inner circle of their honey- 
 moon Hamilton on Quaternions. 
 
 It was now (1805) that the London Mathematical Society 
 
138 TEN BRITISH MATHEMATICIANS 
 
 was organized under the guidance of De Morgan, and Todhunter 
 became a member in the first year of its existence. The same 
 year he discharged the very onerous duties of examiner for the 
 mathematical tripos — a task requiring so much labor and 
 involving so much interference with his work as an author 
 that he never accepted it again. Now (1865) appeared his 
 History of the Mathematical Theory of Probability, and the same 
 year he was able to edit a new edition of Boole's Treatise on 
 Differential Equations, the author having succumbed to an 
 untimely death. Todhunter certainly had a high appreciation 
 of Boole, which he shared in common with De Morgan. The 
 work involved in editing the successive editions of his elementary 
 books was great; he did not proceed to stereotype until many 
 independent editions gave ample opportunity to correct all 
 errors and misprints. He now added two more textbooks; 
 Mechanics in 1867 and Mensuration in 1869. 
 
 About 1847 the members of St. John's College founded a 
 prize in honor of their distinguished fellow, J. C. Adams. It 
 is awarded every two years, and is in value about £225. In 
 1869 the subject proposed was " A determination of the circum- 
 stances under which Discontinuity of any kind presents itself 
 in the solution of a problem of maximum or minimum in the 
 Calculus of Variations." There had been a controversy a few 
 years previous on this subject in the pages of Philosophical 
 Magazine and Todhunter had there advocated his view of the 
 matter. " This view is found in the opening sentences of his 
 essay: 'We shall find that, generally speaking, discontinuity is 
 introduced, by virtue of some restriction which we impose, either 
 explicitly or implicitly in the statement of the problems which 
 we propose to solve.' This thesis he supported by considering 
 in turn the usual applications of the calculus, and pointing out 
 where he considers the discontinuities which occur have been 
 introduced into the conditions of the problem. This he success- 
 fully proves in many instances. In some cases, the want of a 
 distinct test of what discontinuity is somewhat obscures the 
 argument." To his essay the prize was awarded ; it is published 
 under the title " Researches in the Calculus of Variations "— 
 
ISAAC TODHUNTEE 139 
 
 an entirely different work from his History of the Calculus of 
 Varialions. 
 
 In 1873 he published his History of the Mathematical 
 Theories of Attraction. It consists of two volumes of nearly looo 
 pages altogether and is probably the most elaborate of his 
 histories. In the same year (1873) he published in book form 
 his views on some of the educational questions of the day, 
 under the title of The Conflict of Studies, and other essays on 
 subjects connected with education. The collection contains 
 six essays; they were originally written with the view of suc- 
 cessive publication in some magazine, but in fact they were 
 published only in book form. In the first essay, that on the 
 Conflict of Studies — Todhunter gave his opinion of the edu- 
 cative value in high schools and colleges of the different kinds 
 of study then commonly advocated in opposition to or in 
 addition to the old subjects of classics and mathematics. He 
 considered that the Experimental Sciences were little suitable, 
 and that for a very English reason, because they could not be 
 examined on adequately. He says: 
 
 " Experimental Science viewed in connection with educa- 
 tion, rejoices in a name which is unfairly expressive. A real 
 experiment is a very valuable product of the mind, requiring 
 great knowledge to invent it and great ingenuity to carry it 
 out. When Perrier ascended the Puy de D6me with a barom- 
 eter in order to test the influence of change of level on the 
 height of the column of mercury, he performed an experiment, 
 the suggestion of which was worthy of the genius of Pascal 
 and Descartes. But when a modern traveller ascends Mont 
 Blanc, and directs one of his guides to carry a barometer, he 
 cannot be said to perform an experiment in any very exact or 
 very meritorious sense of the word. It is a repetition of an 
 observation made thousands of times before, and we can never 
 recover any of the interest which belonged to the first trial, 
 unless indeed, without having ever heard of it, we succeeded 
 in reconstructing the process of ourselves. In fact, almost 
 always he who first plucks an experimental flower thus ap- 
 propriates and destroys its fragrance and its beauty." 
 
140 TEN BRITISH MATHEMATICIANS 
 
 At the time when Todhunter was writing the above, the 
 Cavendish Laboratory for Experimental Physics was just being 
 built at Cambridge, and Clerk-Maxwell had just been appointed 
 the professor of the new study; from Todhunter's utterance 
 we can see the state of affairs then prevailing. Consider the 
 corresponding experiment of Torricelli, which can be performed 
 inside a classroom; to every fresh student the experiment 
 retains its fragrance; the sight of it, and more especially the 
 performance of it imparts a kind of knowledge which cannot be 
 got from description or testimony; it imparts accurate concep- 
 tions and is a necessary preparative for making a new and 
 original experiment. To Todhunter it may be replied that the 
 flowers of Euclid's Elements were plucked at least 2000 years 
 ago, yet, he must admit, they still possess, to the fresh student 
 of mathematics, even although he becomes acquainted with 
 them through a textbook, both fragrance and beauty." 
 
 Todhunter went on to write another passage which roused 
 the ire of Professor Tait. " To take another example. We 
 assert that if the resistance of the air be withdrawn a sovereing 
 and a feather will fall through equal spaces in equal times. 
 Very great credit is due to the person who first imagined the 
 well-known experiment to illustrate this; but it is not obvious 
 what is the special benefit now gained by seeing a lecturer repeat 
 the process. It may be said that a boy takes more interest in 
 the matter by seeing for himself, or by performing for himself, 
 that is, by working the handle of the air-pump; this we admit, 
 while we continue to doubt the educational value of the trans- 
 action. The boy would also probably take much more interest 
 in football than in Latin grammar; but the measure of his 
 interest is not identical with that of the importance of the 
 subjects. It may be said that the fact makes a stronger impres- 
 sion on the boy through the medium of his sight, that he believes 
 it the more confidently. I say that this ought not to be the case. 
 If he does not believe the statements of his tutor — probably 
 a clergyman of mature knowledge, recognized ability and blame- 
 less character — his suspicion is irrational, and manifests a want 
 of the power of appreciating evidence, a want fatal to his sue- 
 
ISAAC TODHUNTEli 141 
 
 cess in that branch of science which he is supposed to be cul- 
 tivating." 
 
 Clear physical conceptions cannot be got by tradition, even 
 from a clergyman of blameless charater; they are best got 
 directly from Nature, and this is recognized by the modern 
 laboratory instruction in physics. Todhunter would reduce 
 science to a matter of authority; and indeed his mathematical 
 manuals are not free from that fault. He deals with the charac- 
 teristic difficulties of algebra by authority rather than by sci- 
 entific explanation. Todhunter goes on to say: " Some con- 
 siderable drawback must be made from the educational value 
 of experiments, so called, on account of their failure. Many 
 persons must have been present at the exhibitions of skilled 
 performers, and have witnessed an uninterrupted series of 
 ignominious reverses, — they have probably longed to imitate the 
 cautious student who watched an eminent astronomer bafHed 
 by Foucault's experiment for proving the rotation of the Earth; 
 as the pendulum would move the wrong way the student retired, 
 saying that he wished to retain his faith in the elements of 
 astronomy." 
 
 It is not unlikely that the series of ignominious reverses 
 Todhunter had in his view were what he had seen in the physics 
 classroom of University College when the manipulation was 
 in the hands of a pure mathematician — Prof. Sylvester. At 
 the University of Texas there is a fine clear space about 60 
 feet high inside the building, very suitable for Foucault's experi- 
 ment. I fixed up a pendulum, using a very heavy ball, and 
 the turning of the Earth could be seen in two successive oscilla- 
 tions. The experiment, although only a repetition according to 
 Todhunter, was a live and inspiring lesson to all who saw it, 
 whether they came with previous knowledge about it or no. 
 The repetition of an}- such great experiment has an educative 
 value of which Todhunter had no conception. 
 
 Another subject which Todhunter discussed in these essays 
 is the suitability of EucHd's Elements for use as the elementary 
 textbook of Geometry. His experience as a college tutor for 
 25 years; his numerous engagements as an examiner in mathe- 
 
142 TEN BRITISH MATHEMATICIANS 
 
 matics; his correspondence with teachers in the large schools 
 gave weight to the opinion which he expressed. The question 
 was raised by the first report of the Association for the Improve- 
 ment of Geometrical Teaching; and the points which Todhunter 
 made were afterwards taken up and presented in his own unique 
 style by Lewis Carroll in " Euclid and his modern rivals." Up 
 to that time Euclid's manual was, and in a very large measure 
 still is, the authorized introduction to geometry; it is not as in 
 this country where there is perfect liberty as to the books and 
 methods to be employed. The great difficulty in the way of 
 liberty in geometrical teaching is the universal tyranny of com- 
 petitive examinations. Great Britain is an examination-ridden 
 country. Todhunter referred to one of the most distinguished 
 professors of Mathematics in England; one whose pupils had 
 likewise gained a high reputation as investigators and teachers; 
 his "venerated master and friend," Prof. De Morgan; and 
 pointed out that he recommended the study of Euclid with all 
 the authority of his great attainments and experience. 
 
 Another argument used by Todhunter was as follows: In 
 America there are the conditions which the Association desires; 
 there is, for example, a textbook which defines parallel lines as 
 those which have the same direction. Could the American mathe- 
 maticians of that day compare with those of England? He 
 answered no. 
 
 While Todhunter could point to one master^De Morgan — 
 as in his favor, he was obliged to quote another master — Syl- 
 vester — as opposed. In his presidential address before section A 
 of the British Association at Exeter in 1869, Sylvester had said: 
 " I should rejoice to see . . . Euclid honorably shelved or buried 
 ' deeper than did ever plummet sound ' out of the schoolboy's 
 reach; morphology introduced into the elements of algebra; 
 projection, correlation, and motion accepted as aids to geometry; 
 the mind of the student quickened and elevated and his faith 
 awakened by early initiation into the ruling ideas of polarity, 
 continuity, infinity, and familiarization with the doctrine of 
 the imaginary and inconceivable." Todhunter replied: " What- 
 ever may have produced the dislike to Euclid in the illustrious 
 
ISAAC TODHUXTER 143 
 
 mathematician whose words I have quoted, there is no ground 
 for supposing that he would have been better pleased with the 
 substitutes which are now offered and recommended in its place. 
 But the remark which is naturally suggested b}- the passage, 
 is that nothing prevents an enthusiastic teacher from carryiag 
 liis pupUs to any height he pleases in geometr)-, even if he starts 
 vdth. the use of Euclid." 
 
 Todhunter also repHed to the adverse opinion, deHvered by 
 some professor (doubtless Tait) in an address at Edinburgh 
 which was as follows: " From the majority of the papers in our 
 few mathematical journals, one would almost be led to fancy 
 that British mathematicians have too much pride to use a simple 
 method, while an unnecessarily complex one can be had. Xo 
 more telHng example of this could be mshed for than the insane 
 delusion under which they permit ' Euclid ' to be employed in 
 our elementar}- teaching. The}- seem voluntarily to weight 
 alike themsehes and their pupils for the race." To which 
 Todhunter replied: " The British mathematical journals with 
 the titles of which I am acquainted are the Quarter!}- Journal of 
 Mathematics, the ^Mathematical ^Messenger, and the Philosoph- 
 ical ^Magazine; to which may be added the Proceedings of the 
 Royal Societ}- and the Monthly Notices of the Astronomical 
 Societ}\ I should have thought it would have been an adequate 
 emplojTnent, for a person engaged in teaching, to read and master 
 these periodicals regularly; but that a single mathematician 
 should be able to improve more than halt the matter which is 
 thus presented to him fills me with amazement. I take down 
 some of these volumes, and turning over the pages I find article 
 after article by Profs. Ca}le}-, Salmon and Sylvester, not to 
 mention many other highly distinguished names. The idea of 
 amending the elaborate essa}-s of these eminent mathematicians 
 seems to me something like the audacity recorded in poetrj- 
 with which a superhuman hero climbs to the svimmit of 
 the Indian 01}inpus and overturns the thrones of Vishnu, 
 Brahma and Siva. WTiile we may regret that such abihty 
 shoiild be exerted on the revolutionai}- side of the question, 
 here is at least one mournful satislaction: the weapon with 
 
144 TEN BRITISH MATHEMATICIANS 
 
 which Euchd is assailed was forged by Euclid himself. The 
 justly celebrated professor, from whose address the quotation 
 is taken, was himself trained by those exercises which he now 
 considers worthless; twenty years ago his solutions of mathe- 
 matical problems were rich with the fragrance of the Greek 
 geometry. I venture to predict that we shall have to wait 
 some time before a pupil will issue from the reformed school, 
 who singlehanded will be able to challenge more than half the 
 mathematicians of England." Professor Tait, in what he said, 
 had, doubtless, reference to the avoidance of the use of the 
 Quaternion method by his contemporaries in mathematics. 
 
 More than haK of the Essays is taken up with questions 
 connected with competitive examinations. Todhunter explains 
 the influence of Cambridge in this matter: " Ours is an age 
 of examination; and the University of Cambridge may claim 
 the merit of originating this characteristic of the period. When 
 we hear, as we often do, that the Universities are effete bodies 
 which have lost their influence on the national character, we may 
 point with real or affected triumph to the spread of examinations 
 as a decisive proof that the humiliating assertion is not absolutely 
 true. Although there must have been in schools and elsewhere 
 processes resembling examinations before those of Cambridge 
 had become widely famous, yet there can be Httle chance of 
 error in regarding our mathematical tripos as the model for 
 rigor, justice and importance, of a long succession of insti- 
 tutions of a similar kind which have since been constructed." 
 Todhunter makes the damaging admission that " We cannot 
 by our examinations, create learning or genius; it is uncertain 
 whether we can infalKbly discover them; what we detect is simply 
 the examination-passing power." 
 
 In England education is for the most part directed to train- 
 ing pupils for examination. One direct consequence is that 
 the memory is cultivated at the expense of the understanding; 
 knowledge instead of being assimilated is crammed for the time 
 being, and lost as soon as the examination is over. Instead of 
 a rational study of the principles of mathematics, attention is 
 directed to problem-making, — to solving ten-minute conun- 
 
ISAAC TODHUNTER 145 
 
 drums. Textbooks are written with the \'iew not of teaching 
 the subject in the most scientific manner, but of passing certain 
 specified examinations. I have seen such a textbook on trigo- 
 nometry where all the important theorems which required the 
 genius of Gregory and others to discover, are put down as so 
 many definitions. Nominal knowledge, not real, is the kind 
 that suits examinations. 
 
 Todhunter possessed a considerable sense of humour. We 
 see this in his Essays; among other stories he tells the following: 
 A youth who was quite unable to satisfy his examiners as to a 
 problem, endeavored to mollify them, as he said, " by writing 
 out book work bordering on the problem." Another youth 
 who was rejected said " if there had been fairer examiners and 
 better papers I should have passed; I knew man}- things which 
 were not set." Again: "A visitor to Cambridge put himself 
 under the care of one of the self-constituted guides who obtrude 
 their services. Members of the various ranks of the academical 
 state were pointed out to the stranger — ^heads of colleges, pro- 
 fessors and ordinary fellows; and some attempt was made to 
 describe the nature of the functions discharged by the heads 
 and professors. But an inquiry as to the duties of fellows pro- 
 duced and reproduced only the answer, ' Them's fellows I say.' 
 The guide had not been able to attach the notion of even the 
 pretense of duty to a fellowship." 
 
 In 1874 Todhunter was elected an honorary fellow of his 
 college, an honor which he prized very highly. Later on he 
 was chosen as an elector to three of the University professor- 
 ships—Moral Philosophy, Astronom}-, Mental Philosophy and 
 Logic. " When the University of Cambridge established its 
 new degree of Doctor of Science, restricted to those who have 
 made original contributions to the advancement of science or 
 learning, Todhunter was one of those whose application was 
 granted within the first few months." Li 1875 he published 
 his manual Functions of Laplace, Besscl and Lcgendre. Next 
 year he finished an arduous literary task — the preparation 
 of two volumes, the one containing an account of the writings 
 of Whewell, the other containing selections from his literary 
 
146 TEN BRITISH MATHEMATICIANS 
 
 and scientific correspondence. Todhunter's task was marred 
 to a considerable extent by an unfortunate division of the 
 matter: the scientific and literary details were given to him, 
 while the writing of the life itself was given to another. 
 
 In the summer of 1880 Dr. Todhunter first began to suffer 
 from his eyesight, and from that date he gradually and 
 slowly became weaker. But it was not till September, 1883, 
 when he was at Hunstanton; that the worst symptoms came on. 
 He then partially lost by paralysis the use of the right arm; 
 and, though he afterwards recovered from this, he was left 
 much weaker. In January of the next year he had another 
 attack, and he died on March i, 1884, in the 64th year of his 
 age. 
 
 Todhunter left a History of Elasticity nearly finished. The 
 manuscript was submitted to Cay ley for report; it was in 1886 
 published under the editorship of Karl Pearson. I believe that 
 he had other histories in contemplation; I had the honor of 
 meeting him once, and in the course of conversation on mathe- 
 matical logic, he said that he had a project of taking up the 
 history of that subject; his interest in it dated from his study 
 under De Morgan. Todhunter had the same ruling passion as 
 Airy — love of order — and was thus able to achieve an immense 
 amount of mathematical work. Prof. Mayor wrote, " Tod- 
 hunter had no enemies, for he neither coined nor circulated 
 scandal; men of all sects and parties were at home with him, 
 for he was many-sided enough to see good in every thing. His 
 friendship extended even to the lower creatures. The canaries 
 always hung in his room, for he never forgot to see to their 
 wants." 
 
INDEX 
 
 Adams, J. C, 138 
 Airy, G. B., 38, 45. 146 
 Apollonius, 102 
 Argand, J. R., 13, 56, 138 
 Arnold, T., 93 
 
 Babbage, C, 10, 13 
 
 Ball, R., 14 
 
 Beltrami, E., 86 
 
 Boole, G., 50-63, 14, 29, 80, 98, 138 
 
 Boscovich, R. J., 130 
 
 Brewster, D., 95 
 
 Brinkley, N., 35, 36, 38 
 
 Burkhardt, J. C, 97 
 
 Cauchy, A. L., 95 
 
 Cayley, A., 64-77, 46, 78, 108, 109, no, 
 
 121, 126, 132, 137, 143, 146 
 Chrystal, G., 25, 35 
 Clairault, A. C, 10 
 Clifford, W. K., 78-91, 121 
 Colburn, Z., 35 
 Colenso, J. W., 129 
 
 Davy, H., 82, 114 
 
 Delambre, J. B. J., 10 
 
 De La Rue, W., 118 
 
 De Morgan, A., 19-33, 8, 14, 40, 41, 
 52,53,54, 58, 62,63,65, 70, 78, 79, 
 80, 108, III, 123, 124, 132, 134, 135, 
 138, 142, 146 
 
 De Morgan, G., 22 
 
 Dewar, J., 82, 114 
 
 Dodgson, C. L., 80, 142 
 
 Dodson, J., 19 
 
 Eisenstein, F. G., 99 
 Ellis, L., 64 
 
 Eratosthenes, 97 
 
 Euclid, 19, no, in, 114, 140, 142 
 
 Euler, L., 10, 96, no 
 
 Faraday, M., 82, 102, 114 
 Fermat, P. de, 96 
 Forsyth, A. R., 53, 70 
 Foucault, J. B. L., 141 
 Franfois, 13 
 Franklin, F., 116, 117 
 Frend, W., 12, 13, 21 
 
 Gauss, K. F., 86, 95, 96, 100 
 
 Graves, C., 54 
 
 Green, G., 107 
 
 Gregory, D., 52 
 
 Gregory, D. F., 14, 25, 27, 51, 52, 64, 
 
 65, 107 
 Gregory, J., 52 
 
 Hamilton, J., 34 
 
 Hamilton, W., 23, 29 
 
 Hamilton, W. E., 48 
 
 Hamilton, W. R., 34-49, 14, 18, 23, 28, 
 52,53,54, 62,69,71, 73, 74, 75, 80, 
 81, 8s, 95, 114, 123, 127, 128, 132 
 
 Harley, R., 54 
 
 Hart, H., 115 
 
 Helmholtz, H. L. F., 86 
 
 Hermite, C., 105 
 
 Herschel, J. F. W., 8, 10, 13, 88, 135 
 
 Highton, H., 93 
 
 Hipparchus, 48 
 
 Hobbes, T., 63 
 
 Huxley, T. H., 101, in, 112, 113, 129 
 
 Ivory, J., 10, 81 
 
 147 
 
148 
 
 INDEX 
 
 Jacoby, K. G. J., lo, 99 
 Joly, J-, 45, 49 
 
 Kant, E., 41, 42, 74, 85, 87 
 Kelvin, Lord, 79 
 Kempe, A. B., 115, 116 
 Kepler, J., 102 
 Kirkman, T. P., 122-133 
 
 Lacroix, S. F., 10 
 Lagrange, C. F. L., 10, 4c 
 Laplace, P. S., 10, 35, 65 
 Legendre, A. M., 10 
 Leibnitz, G. W., 9 
 Little, C. N., 133 
 Lipkin, 114 
 Lloyd, H., 41, 85 
 Lobatchewsky, N. I., 86 
 Lockyer, J. N., loi 
 Lubbock, J., loi 
 
 Macfarlane, A., 3, 4, 31, 45, 57, 67, 
 
 loi, 118, 133, 141, 146 
 Maclaurin, C, no 
 Martineau, J., 22 
 Maseres, F., 12, 14 
 Maxwell, J. C, 40, 67, 68, 79, 87, loi, 
 
 102, 132, 140 
 Mill, J. S., 74, 129 
 Minkowski, 105, 106 
 
 Newton, I., 9, 41, 46, 65, 67, 80, no 
 
 Peacock, G., 7-18, 20, 24, 25, 41, 52, 
 
 55,78 
 Peaucellier, C, N,, 114, 115 
 
 Plato, 74, 91 
 Poincar6, J. H., 121 
 Pollock, F., 81 
 
 Rankine, W. J. M., 40 
 Rayleigh, Lord, 82 
 Record, R., 16 
 Riemann, G. F. B., 86 
 Rosse, Lord, 45 
 Routh, E. J., 136 
 Rumford, Count, 82 
 
 Salmon, G., 46, 65, 143 
 Smith, H. J. S., 92-106, 119, 120 
 Smith, J., 32, 33 
 Socrates, 24, 91 
 
 Spencer, H., 129, 130, 131, 132 
 Spottiswoode, W., 119 
 Stewart, E., 89, 91 
 
 Sylvester, J. J., 107-121, 66, 69, 79, 135, 
 141, 143 
 
 Tait, P. G., 34, 42, 57, 71, 72, 73, 89, Qi 
 
 132, 133, 136, 140, 143, 144, 146 
 Todhunter, I., 134-146 
 Tschebicheff, 114, 115 
 Tyndall, J., 82, 114, 129 
 
 Waring, E., no 
 
 Warren, J., 13, 28 
 
 Watt, J., ns 
 
 Whewell, W., 14, 20, 24, 29, 79, 94 
 
 Woodhouse, R., 136 
 
 Wordsworth, W., 38, 39 
 
 Young, T., 83 
 
OORNOiUNIVERSITYLlBRARY 
 
 MAY Id 1993 
 
 MWHEMATICSUBRAo^' 
 
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