M i c h a e l J. C r o w e
A HISTORY OF
VEC O R ANALYSIS
T h e Evolution of t h e I d e a of a Vectorial System
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M i c h a e l J. C r o w e
A HISTORY OF
VEC O R ANALYSIS
T h e Evolution of t h e I d e a of a Vectorial System
A
HISTORY
OF
VECTOR ANALYSIS T h e E v o l u t i o n of the Idea of a V e c t o r i a l System
M I C H A E L J. CROWE University
of Notre
Dame
D o v e r Publications, I n c . New York
To
Copyright ©
MARY
ELLEN
1967 b y U n i v e r s i t y o f N o t r e D a m e Press
N e w m a t e r i a l C o p y r i g h t © 1985 by M i c h a e l J. C r o w e A l l rights reserved u n d e r Pan A m e r i c a n a n d International C o p y r i g h t Conventions. Published Lesmill Road,
in
Canada by
General
Publishing Company,
Ltd.,
30
D o n Mills, Toronto, Ontario.
Published in the United Kingdom by Constable and Company, Ltd., 10 Orange Street, This
London W C 2 H 7EG.
D o v e r edition, first published in
1985,
is an unabridged and
corrected republication of the work first published by the University of N o t r e D a m e Press i n 1967. A n e w Preface has b e e n a d d e d t o this e d i t i o n . M a n u f a c t u r e d i n t h e U n i t e d States o f A m e r i c a D o v e r Publications, Inc., 31 East 2 n d Street, Mineola, N.Y.
L i b r a r y of Congress Cataloging in Publication D a t a C r o w e , M i c h a e l J. A h i s t o r y of v e c t o r analysis. Originally published: Notre D a m e : University of N o t r e D a m e Press,
1967. W i t h c o r r e c t i o n s a n d n e w pref.
Includes bibliographies and index. 1.
Vector analysis—History.
QA433.C76 ISBN
1985
0-486-64955-5
515'.63
I.
Title. 85-13081
11501
Preface
Shortly before becoming President of Harvard in ematician the
Thomas
best k n o w n
Newton have dynasties
Hill
made
vectorial
done
the
system
following of his
1862, the math-
statement concerning
day:
"The
discoveries
of
m o r e for E n g l a n d a n d for the race than w h o l e
of British
monarchs;
and we
d o u b t not that in the great
mathematical birth of 1853, the Quaternions of H a m i l t o n , there is as much
real
promise
of benefit to
mankind as
in any event of Vic-
toria's r e i g n . " L o r d K e l v i n , w r i t i n g w h e n V i c t o r i a was v e r y o l d a n d the
modern
vector
"Quaternions been
done;
system
came
and,
from
very
new,
Hamilton
though
took
a very
different view.
really
good work had
after his
beautifully
ingenious, have been an
m i x e d evil to those w h o have t o u c h e d t h e m in any w a y .
.
un-
. vectors
. . . have n e v e r b e e n of the slightest use to any creature." T h o u g h Kelvin's barbs quaternion
in this attack of the 1890's w e r e d i r e c t e d against the
system,
methods since the
he
had
been
waging
w a r against all
vectorial
1860's.
If a scientist of the present day w e r e forced to take sides in this dispute
on the value of vectorial
methods, he might view Hill
as
overly enthusiastic, but he w o u l d not side w i t h Kelvin. T h e v i e w of vectorial m e t h o d s c h a m p i o n e d by this great physicist has b e e n refuted by the thousands
of uses
that have b e e n f o u n d for vectorial
m e t h o d s . N e a r l y all b r a n c h e s o f classical p h y s i c s a n d m a n y areas o f m o d e r n physics are n o w p r e s e n t e d i n the language o f vectors, a n d the benefits d e r i v e d t h e r e b y are m a n y . V e c t o r analysis has l i k e w i s e proved omy,
a valuable
Despite little
aid
for
many problems
in engineering, astron-
and geometry. the
studied.
importance Not a single
of vector book
analysis,
and
its
not more
history has than
been
a handful of
s c h o l a r l y p a p e r s h a v e u p t o n o w b e e n w r i t t e n o n its h i s t o r y . C o n s e quently m a n y historical errors m a y be f o u n d in the relevant literaiii
Preface
ture. T h e present study was not w r i t t e n in the expectation that all or even
most historical
swered;
questions a b o u t vector analysis w o u l d b e an-
rather it was
written
in the h o p e of presenting an essen-
t i a l l y c o r r e c t o u t l i n e o f t h e h i s t o r y o f t h i s i m p o r t a n t area. I n u n d e r t a k i n g this study I have f r e q u e n t l y b e e n h i n d e r e d by the scarcity of scholarly
studies
numbers,
linear algebra, tensors, theoretical
of the
history
teenth-century mechanics.
This
of such
r e l a t e d areas
as
complex
electricity, and nine-
is of course the c o m m o n plight of
historians of science, a n d I have b e e n consoled by the hope that the present
study
m a y s h e d l i g h t o n t h e h i s t o r y o f o t h e r areas
o f sci-
ence, such as those m e n t i o n e d above. In
this
pects
study I
h a v e c o n c e n t r a t e d o n t h e m o r e f u n d a m e n t a l as-
of vectorial
treated in detail:
analysis;
the
history of the
following topics
is
vector a d d i t i o n a n d subtraction, the forms of vec-
tor multiplication,
vector division
(in
those
systems
where
i t oc-
curs), a n d t h e s p e c i f i c a t i o n o f v e c t o r types. Less a t t e n t i o n has b e e n given to the history of vector differentiation and integration, and the operator V a n d the associated transformation theorems, since these were
for the
work.
No
most part developed originally in a Cartesian frame-
detailed
presentation
of the
complicated
history of the
l i n e a r vector f u n c t i o n has b e e n a t t e m p t e d . T h o u g h the above statement indicates the materials included, it does not sufficiently specify the approach taken in this study. For a n u m b e r o f r e a s o n s I h a v e c h o s e n t o f o c u s (as t h e s u b t i t l e i n d i c a t e s ) on t h e h i s t o r y of t h e i d e a of a v e c t o r i a l system. It s h o u l d not be forgotten that the m o d e r n
system
many
vectorial
created
these
systems e m b o d i e d an
systems
of vector analysis is but one of the in
the
course
of history.
Each of
idea or conception of the form that a
vectorial system can have and should have. A n d it is the history of these ideas that I have tried to describe. To do this I have discussed each
of the
tempted to led
to
these
vectorial
systems
created
before
1 9 0 0 a n d at-
creation,
development,
and acceptance
or rejection of
systems.
The the
the
major
d e t e r m i n e w h a t ideas (mathematical a n d motivational)
history of vectorial analysis m a y in one sense be v i e w e d as
history of systems of abbreviation, since any p r o b l e m that can
b e s o l v e d b y vectorial m e t h o d s can also b e s o l v e d ( t h o u g h usually less
conveniently) by the
vectorial
analysis
older Cartesian methods. T h e history of
may equally w e l l be v i e w e d as the history of a
w a y of looking at physical a n d geometrical entities. Consideration of these
two
aspects
chosen to focus
of the
history
will
help explain w h y I
have
on the evolution of the idea of a vectorial system,
rather than on the history of the major theorems in vectorial analy-
iv
Preface
sis, m a n y o f w h i c h w e r e i n a n y case d i s c o v e r e d b e f o r e a n d o u t s i d e of the vectorial traditions. Concerning
the
references.
The
reader
will
find
that a simple
and
not u n c o m m o n system o f reference has b e e n e m p l o y e d i n t h e text. T h e notes for each chapter are located at the e n d of that chapter; w i t h i n each chapter ordinary note numbers w i l l be f o u n d as w e l l as r e f e r e n c e s t o t h e s e n o t e s o f t h e f o r m (3,11,1; 2 7 ) . T h e l a t t e r a r e r e a d as follows: the first n u m b e r always refers to a note at the e n d of the chapter;
the
numbers to the right of the semicolon always refer to
the page n u m b e r s in the publication indicated in that note. In some c a s e s (as a b o v e ) o n e o r t w o o t h e r n u m b e r s a r e i n c l u d e d t o t h e l e f t of the semicolon; these numbers ( w h e n they occur) refer to the volume
number and
part n u m b e r of the
the reference above is read:
publication
indicated.
Thus
see v o l u m e I I , part I, of i t e m 3 in t h e
notes; consult page 27. T h r o u g h this m e t h o d it has b e e n p o s s i b l e to provide the reader w i t h
many references
that otherwise
could be
i n c l u d e d only t h r o u g h a substantial increase in the size of the book. Concerning sources
quotations
for this
and
translations.
study were books
Since
many
and journals
of
the
of limited circula-
tion I have used quotations rather liberally. All quotations from documents written in foreign languages (French, German, Italian, Russian,
and
cases
Danish)
where
have
previously
been
translated
published
into
English.
translations
In
were
the
few
available,
I
have used these after c h e c k i n g t h e m against the original a n d n o t i n g deviations. T h e sole e x c e p t i o n to this statement occurs in t h e case of Wessel's D a n i s h ; here I have c h e c k e d Nordgaard's E n g l i s h translation
against
translations Concerning
the
French
translation
of Zeuthen.
The
remaining
(the majority) are my o w n . bibliography.
No
formal
bibliographical
been i n c l u d e d in this book. T h e reader w i l l
find
section
has
h o w e v e r that the
sections of notes at the e n d of each chapter w i l l serve rather w e l l as a bibliography raphy
is
for that
greatly
chapter.
Moreover the
d i m i n i s h e d by the
existence
n e e d for a bibliogof a book
that
lists
nearly all relevant p r i m a r y d o c u m e n t s p u b l i s h e d to about 1912; this is
Alexander
Systems
of
Macfarlane's
Mathematics
(Dublin,
Bibliography 1904).
of
Quaternions
Supplements
to
and
Allied
this
un-
c o m m o n l y accurate bibliography w e r e p u b l i s h e d up to 1913 in the Bulletin
of
Quaternions The
the
International
and
Allied
author
wishes
Society Systems
to
express
for of
his
Promoting
the
Study
of
Mathematics.
gratitude
to those
who
have
aided h i m in preparing this study. P u b l i s h e d and u n p u b l i s h e d materials have b e e n o b t a i n e d f r o m libraries too n u m e r o u s to m e n t i o n , a n d this through the kindness of the librarians of the universities of v
Preface
Notre D a m e , Wisconsin, C a m b r i d g e , a n d Yale. Assistance at important
points
has
come
from
Professor Stephen J.
Rogers
of Notre
D a m e University and from Professor D e r e k J. Price of Yale University. Sincere thanks are e x t e n d e d to Professors C. H. B l a n c h a r d a n d William
D.
sor James
Stahlman of the W.
U n i v e r s i t y of W i s c o n s i n a n d to Profes-
B o n d o f P e n n s y l v a n i a State U n i v e r s i t y . T h e s e three
scholars (a physicist, an historian of science, a n d a mathematician) gave generously of their time (in reading the entire manuscript) and of t h e i r w i s d o m (in s a v i n g t h e m a n u s c r i p t f r o m a n u m b e r of errors). To
Professor E r w i n N.
most
sincere
thanks
Hiebert, of the University of Wisconsin, my
for
his
numerous,
detailed,
and
perceptive
c o m m e n t s on the entire manuscript. Portions of the research for this book
w e r e carried out w i t h f i n a n c i a l assistance p r o v i d e d b y funds
administered by C o m m i t t e e on Grants for the Arts and Humanities of the
University of Notre
Notre
Dame,
Dame. Michael J. Crowe
March,
vi
1967
Indiana
Acknowledgments
Grateful lishers
acknowledgment is hereby made to the following pub-
and
libraries
published B.
G.
for permission
to
quote
from
books
and un-
materials:
Teubner Verlag,
Friedrich
Engel,
Hermann
Grassmanns
kalische
Stuttgart,
Grassmanns
for
Leben,
permission
contained
Gesammelte
in
to
quote
Vol.
mathematische
from
Ill
und
of physi-
Werke.
Cambridge
University
published material
in
Library
for permission to quote from
un-
the correspondence of James Clerk M a x w e l l
and Peter Guthrie Tait. C a m b r i d g e U n i v e r s i t y Press for p e r m i s s i o n to quote f r o m Cargill Gilston
Knott,
Life
and
Scientific
Work
of
Peter
Guthrie
Tait.
Ernst B e n n L i m i t e d , L o n d o n , for permission to quote f r o m O l i v e r Heaviside,
Electromagnetic
Macmillan Oliver
&
Co.,
Theory,
Ltd.,
Heaviside,
Vols.
London,
Electrical
I
for
and
III.
permission
to
quote
from
Papers.
T h o m a s N e l s o n a n d Sons, Ltd., L o n d o n , for p e r m i s s i o n to quote from and
Sir
Edmund
Electricity,
Vol.
Yale
Whittaker,
A
History
of
the
Theories
o f Aether
I.
University Library for permission to quote from the u n p u b -
lished material
in the correspondence of Josiah W i l l a r d Gibbs.
Yale U n i v e r s i t y Press for p e r m i s s i o n to q u o t e f r o m L y n d e P h e l p s Wheeler,
Josiah
Willard
Gibbs:
The
History
of
a
Great
Mind.
vii
List
Graph I
Graphs
and
Tables
Q u a t e r n i o n P u b l i c a t i o n s f r o m 1841 to 1900
Graph I I Graph
of
III
Q u a t e r n i o n Books from 1841 to 1900 Annual
N u m b e r of Titles
of Mathematical
Articles and Books, 1868-1909 Graph I V
Grassmannian
Analysis
Publications
113 from
1841 to 1900 Graph V Graph V I Graph VII Graph
VIII
113
G r a s s m a n n i a n A n a l y s i s B o o k s f r o m 1841 to 1900 Q u a t e r n i o n P u b l i c a t i o n s by C o u n t r y
Analysis
Publications
115 by
Country Graph I X Chronology
viii
114 114
Q u a t e r n i o n B o o k s by C o u n t r y Grassmannian
111 112
G r a s s m a n n i a n Analysis Books by C o u n t r y
115 116 256
Contents
Chapter
One
THE
EARLIEST
TRADITIONS
I. I n t r o d u c t i o n II.
1
The Concept of the
Parallelogram
of Velocities
and
Forces
2
III.
L e i b n i z ' C o n c e p t of a G e o m e t r y of Situation
IV.
The
Concept of the
Geometrical
3
Representation
of
Complex Numbers V.
Chapter
5
Summary and Conclusion
11
Notes
13
Two
SIR
WILLIAM
ROWAN
HAMILTON
AND
QUATERNIONS I.
Introduction: Hamiltonian Historiography
17
Hamilton's Life and Fame
19
III.
Hamilton and Complex Numbers
23
IV.
Hamilton's Discovery of Quaternions
27
Quaternions until H a m i l t o n ' s D e a t h (1865)
33
II.
V. VI.
Chapter
Summary and Conclusion
41
Notes
43
Three
OTHER
EARLY
ESPECIALLY
VECTORIAL
GRASSMANN'S
SYSTEMS, THEORY OF
EXTENSION I. Introduction II.
III. IV.
47
August Ferdinand Mobius and His
Barycentric
Calculus
48
Giusto Bellavitis and His Calculus of Equipollences
52
Hermann
Grassmann
and His
Calculus
Introduction
of Extension: 54
V.
G r a s s m a n n ' s Theorie der Ebbe und Flut
60
VI.
G r a s s m a n n ' s Ausdehnungslehre o f 1 8 4 4
63 ix
Contents
VII. VIII.
IX.
T h e Period from 1844 to 1862 Grassmann's
77
Ausdehnungslehre
of
1862
and
the
Gradual, Limited Acceptance of His Work
89
Matthew O'Brien
96
Notes
Chapter
102
Four
TRADITIONS THE
I. II.
IN
MIDDLE
VECTORIAL PERIOD OF
ANALYSIS ITS
FROM
HISTORY
Introduction
109
Interest in Vectorial Analysis
in Various
Countries
from 1841 to 1900 III.
110
Peter Guthrie Tait:
Advocate
and
Developer of
Quaternions IV.
V. VI.
Chapter
Benjamin
117
Peirce:
Advocate
of Quaternions
in
America
125
James Clerk Maxwell: Critic of Quaternions
127
William Kingdon Clifford: Transition Figure
139
Notes
144
Five
GIBBS
AND
HEAVISIDE
DEVELOPMENT
OF
AND
THE
THE
MODERN
SYSTEM OF VECTOR ANALYSIS I.
Introduction
150
II. Josiah W i l l a r d Gibbs III.
Gibbs' Early W o r k in Vector Analysis
152
IV.
G i b b s ' Elements o f Vector Analysis
155
Gibbs' Other W o r k Pertaining to Vector Analysis
158
V. VI. VII. VIII. IX. X.
Chapter I. II. III.
x
150
Oliver Heaviside
162
Heaviside's Electrical Papers
163
H e a v i s i d e ' s Electromagnetic Theory
169
T h e Reception Given to Heaviside's Writings
174
Conclusion
177
Notes
178
Six
A
STRUGGLE
FOR
EXISTENCE
Introduction
IN
THE
1890'S 182
T h e "Struggle for Existence"
183
Conclusions
215
Notes
221
Contents
Chapter
Seven
THE
EMERGENCE
OF
THE
OF VECTOR ANALYSIS: I. II.
III.
SYSTEM
Introduction Twelve
Major Publications
225 in Vector Analysis
from
1894 to 1910
226
Summary and Conclusion
239
Notes
243
Chapter Eight Notes
Index
MODERN
1894-1910
SUMMARY AND CONCLUSIONS
247 255
260
xi
Preface
to
the
Dover
Edition
It is v e r y gratifying that interest in the materials presented in this v o l u m e i s s u f f i c i e n t t o j u s t i f y a s e c o n d e d i t i o n . T h i s has p e r m i t t e d t h e c o r r e c t i o n o f a n u m b e r of small errors and, more importantly, provides an opportunity to b r i n g t o r e a d e r s ' a t t e n t i o n s o m e o f t h e r e l e v a n t s t u d i e s o f s p e c i f i c areas w h i c h h a v e a p p e a r e d s i n c e t h e b o o k ' s first p u b l i c a t i o n i n 1967. Recent researches have shed light particularly on the history of algebra d u r i n g the nineteenth century. T h e most broadly conceived of such works is
Lubos
Novy's
Origins
o f Modern
Algebra.l
British
developments
in
algebra have received most attention, i m p o r t a n t studies having b e e n p u b lished by Harvey W.
Becher,
J.
M.
Dubbey,
Philip C.
Enros,
Elaine
K o p p e l m a n , L u i s M . Laita, a n d Joan L . Richards.2 Interest i n Sir W i l l i a m R o w a n H a m i l t o n ' s a c h i e v e m e n t s i n a l g e b r a has b e e n especially intense. R e s e a r c h i n t h i s a r e a has b e e n a i d e d b y t h e a p p e a r a n c e i n 1967 u n d e r t h e editorship of H. Hamilton's
Halberstam and R.
Mathematical Papers,
tions in algebra.3 T h o m a s L.
E.
Ingram of the third volume of
that volume
being devoted
H a n k i n s has e n r i c h e d
to his publica-
H a m i l t o n i a n schol-
arship by various publications, most notably his e n g a g i n g b i o g r a p h y of the great Irish m a t h e m a t i c i a n a n d scientist.4 T h e scholar most actively engaged in assessing H a m i l t o n ' s place in t h e history of B r i t i s h algebra is H e l e n a M. Pycior,
w h o s e d o c t o r a l d i s s e r t a t i o n i n t h i s a r e a has b e e n f o l l o w e d b y a
number
of studies
of the
contemporaries.5 Jerold algebraic/analytic
researches
W a e r d e n has p r o v i d e d quaternions.7
algebraic
David
ideas
of Hamilton
and
M a t h e w s has p u b l i s h e d a p a p e r o n during
the
a n e w analysis
1830's,6 w h i l e
of Hamilton's
B l o o r has b r o a d l y c o n s i d e r e d
B.
his
British
Hamilton's L.
van
der
1843 d i s c o v e r y o f
Hamilton's algebraic
a p p r o a c h in r e l a t i o n to t h e social, political, a n d p h i l o s o p h i c a l context o f his times,8 whereas T. the genesis and
L.
H a n k i n s a n d John H e n d r y have focused studies on
importance of Hamilton's conception of algebra as the
"Science of Pure Time."9 Arnold R.
N a i m a n i n his d o c t o r a l dissertation
surveyed the role of quaternions
the overall development of mathe-
matics.10 xii
in
Preface to the D o v e r Edition
The fascination
I felt for
Hamilton while
researching this b o o k was
rivaled, if not surpassed, as I l e a r n e d m o r e of his r e m a r k a b l e c o n t e m p o r a r y Hermann Grassmann.
M a n y issues I e n c o u n t e r e d i n s t u d y i n g his m a t h e -
matical creations have b e e n treated in d e p t h by A l b e r t C. doctoral dissertation
is
Lewis whose
a c a r e f u l a n a l y s i s o f G r a s s m a n n ' s Ausdehnungslehre
o f 1844 a n d its sources. D r . L e w i s has n o w p u b l i s h e d s o m e o f his r e s u l t s i n papers on the influence of Grassmann's father and of Schleiermacher on his mathematical system.11 M o r e o v e r , Jean D i e u d o n n e a n d D e s m o n d Fearnl e y - S a n d e r h a v e e a c h p u b l i s h e d essays o n G r a s s m a n n ' s p l a c e i n t h e h i s t o r y of linear algebra.12 R e c e n t r e s e a r c h e s h a v e also d e v e l o p e d n e w p e r s p e c t i v e s o n f i g u r e s less c e n t r a l t h a n H a m i l t o n a n d G r a s s m a n n i n t h i s h i s t o r y . H e l e n a M . P y c i o r has presented ciative
a fresh
Algebra,13
analysis
and
of B e n j a m i n
Hubert
Kennedy
Peirce's has
p i o n e e r i n g Linear Asso-
investigated
James
Mills
Peirce's place in t h e " c u l t of q u a t e r n i o n s " that arose in late n i n e t e e t h century America.14 G.
C . S m i t h i n a r e c e n t p a p e r has u r g e d t h a t M a t t h e w
O ' B r i e n deserves significantly m o r e credit as a pioneer of the
modern
v e c t o r i a l s y s t e m t h a n has t r a d i t i o n a l l y b e e n a c c o r d e d h i m , 1 5 a n d t h e late B. R.
Gossick has
provided
n e w insights on
the contrasting views
of
vectorial methods espoused by O l i v e r Heaviside and L o r d Kelvin.16 T h e first systematic study of the history of Stokes' T h e o r e m a n d of the associated theorems n a m e d after Gauss and G r e e n is d u e to V i c t o r J.
Katz.17 T h e
i n v o l v e m e n t o f R u s s i a n m a t h e m a t i c i a n s w i t h v e c t o r i a l m e t h o d s has b e e n treated b y W . D o b r o v o l s k i j , 1 8 a n d studies o f t h e history o f v e c t o r analysis i n general have b e e n u n d e r t a k e n by A d a l b e r t A p o l i n a n d James W. Joiner, b o t h of w h o m seem to have w r i t t e n w i t h o u t k n o w l e d g e of my book.19 F o r t h e sake o f c o m p l e t e n e s s , m e n t i o n s h o u l d b e m a d e o f t h r e e p u b l i c a tions w h i c h a p p e a r e d before m y book, b u t w h i c h escaped m y b i b l i o g r a p h i c searches. T w o o f these, b o t h f r o m t h e 1930 s , t r e a t t h e h i s t o r y o f c o m p l e x n u m b e r s ; the earlier was w r i t t e n by J. B u d o n whereas the second is E r n e s t Nagel's " I m p o s s i b l e N u m b e r s . " 2 0 T h e latter omission is especially regrettab l e b e c a u s e t h a t essay p r o v i d e s a h i s t o r i o g r a p h i c p e r s p e c t i v e w h i c h w o u l d h a v e e n r i c h e d m y p r e s e n t a t i o n . T h i s i s e v e n m o r e t r u e o f t h e t h i r d essay, that p u b l i s h e d in 1 9 6 3 - 6 4 by the late I m r e Lakatos.21 A l t h o u g h c o n t a i n i n g essentially n o t h i n g r e l e v a n t to the h i s t o r y of vector analysis, Lakatos' n o w f a m o u s essay i s r i c h i n p h i l o s o p h i c a n d h i s t o r i o g r a p h i c i n s i g h t s w h i c h , w e r e I to rewrite this book, w o u l d certainly be included. Some hints as to the d i r e c t i o n I w o u l d t a k e a r e p r o v i d e d i n a h i s t o r i o g r a p h i c essay I p u b l i s h e d i n 1975.22 Persons w h o m a y acquire f r o m this book an interest in f u r t h e r readings in the history of mathematics
may wish
to consult
the
excellent
general
histories of mathematics w r i t t e n by Carl B. Boyer and M o r r i s Kline,23 or for articles on i n d i v i d u a l mathematicians, o f Scientific
Biography,24
Bibliographic
t h e m a n y v o l u m e s o f t h e Dictionary
searches
which
required
days
in xiii
Preface to the D o v e r Edition
t h e e a r l y 1960's c a n n o w b e a c c o m p l i s h e d b y s p e n d i n g a f e w h o u r s w i t h t h e late
Kenneth
Mathematics
O.
Mays
and
with
Bibliography
the
ISIS
and
Research
Manual
of the
History
of
Bibliography.25
Cumulative
In c o n c l u d i n g this u p d a t e d preface, I extend w a r m e s t thanks to the two persons
w h o have
made
this
new edition
possible:
John
W.
Grafton,
Assistant to t h e P r e s i d e n t of D o v e r Publications, a n d James R. L a n g f o r d , D i r e c t o r o f t h e U n i v e r s i t y o f N o t r e D a m e Press. T h e e n c o u r a g e m e n t o f t h e f o r m e r a n d t h e cooperation of the latter are chiefly responsible for this book b e i n g once again available to readers. M i c h a e l J. C r o w e University of Notre
Dame
January, 1985
Notes 1
LuboS
2
Harvey
Novy,
Mathematica, Historia
W.
Origins
7 (1980),
Mathematica,
(1812-1813): (1983),
"Woodhouse,
3 8 9 - 4 0 0 ; J. 4
(1977),
Elaine
Archive for
M.
by Jaroslav T a u e r
Dubbey,
Renewal
Koppelman,
History
trans, Babbage,
295-302;
Precursor of t h e
24-47;
Algebra,"
o f Modern Algebra,
Becher,
Peacock,
and
"Babbage,
Philip
C.
1973).
A l g e b r a , " Historia
Peacock a n d M o d e r n A l g e b r a , "
Enros,
of C a m b r i d g e
(Leyden,
Modern
"The
Analytical
M a t h e m a t i c s , " Historia
Society
Mathematica,
10
" T h e C a l c u l u s o f O p e r a t i o n s a n d t h e Rise o f Abstract
o f Exact
Sciences,
8
(1971),
155-242;
Luis
M.
Laita,
"The
Influence of Boole's Search for a Universal M e t h o d in Analysis on the Creation of His Logic," Annals
o f Science,
Controversy
34
(1977),
between
163-176;
William
Luis
Hamilton
M.
Laita,
and
"Influences
Augustus
De
on
Boole's
Logic:
The
M o r g a n , " Annals o f Science,
36
(1979), 4 5 - 6 5 ; L u i s M . L a i t a , " B o o l e a n A l g e b r a a n d Its E x t r a - l o g i c a l Sources: T h e T e s t i m o n y of M a r y
Everest
Boole,"
History and Philosophy o f Logic,
" T h e A r t and the Science of British Algebra: Truth," 3
H.
Hamilton, 4
Historia
Mathematica,
Halberstam vol.
Ill:
Thomas
L.
7
and
Algebra
(1980),
R.
E.
Hankins,
Sir
William
(1980),
3 7 - 6 0 ; Joan
L.
Richards,
343-365.
Ingram,
(Cambridge,
1
A Study in the Perception of Mathematical
The
Mathematical
England, Rowan
Papers
of
Sir
William
Rowan
1967).
Hamilton
(Baltimore,
1980).
For
a
shorter
b i o g r a p h y w h i c h discusses H a m i l t o n ' s m a t h e m a t i c s o n a m o r e e l e m e n t a r y l e v e l , see: Sean O'Donnell, 5
William
Helena
Algebra ( A
M.
Rowan
Hamilton:
Pycior,
1976 C o r n e l l
The
Portrait
Role
of Sir
of a
Prodigy
William
Hamilton
University doctoral dissertation);
(Dublin,
1983).
in
the
Development
H.
M.
Pycior,
and the
B r i t i s h O r i g i n s o f S y m b o l i c a l A l g e b r a , " Historia Mathematica, 8 ( 1 9 8 1 ) ,
Pycior,
"Early
Criticisms
(1982), 3 9 2 - 4 1 2 ; H . Isis, 6
74 ( 1 9 8 3 ) ,
7
L.
available
in
Approach
to
Algebra,"
23-45;
Historia
H.
M.
Mathematica,
9
211-226. "William Rowan
Archive for
B.
Symbolical
Modern
M . Pycior, " A u g u s t u s D e Morgan's Algebraic W o r k : T h e T h r e e Stages,"
Jerold Mathews,
Analysis, "
of t h e
of British
" G e o r g e Peacock
van
History der
English
of Exact
Waerden,
as
H a m i l t o n ' s P a p e r o f 1837 o n t h e A r i t h m e t i z a t i o n o f
Sciences,
19
Hamiltons
"Hamilton's
(1978),
Entdeckungder
Discovery
177-200. Quaternionen(Gottingen,
of Q u a t e r n i o n s , "
1974).
Mathematics
Now
Magazine,
49
(1976), 2 2 7 - 2 3 4 . 8
David
Nineteenth
Bloor,
Century
"Hamilton
Mathematics,
and
ed.
by
Peacock
on
Herbert
the
Essence of A l g e b r a "
Mehrtens,
Henk
Bos
in
and
Social History o f Ivo
Schneider
( B o s t o n , 1981), p p . 2 0 2 - 2 3 2 . 9
Thomas L. Hankins, "Algebra as Pure Time: William Rowan Hamilton and the Founda-
tions
xiv
of
Algebra"
in
Motion
and
Time,
Space
and
Matter:
Interrelations
in
the
History
of
Preface to the D o v e r Edition
Philosophy and Science,
ed.
by P.
J.
Machamer and
R.
G.
Turnbull (Columbus,
1976),
pp.
327-359. 10
Arnold
R.
Naiman,
The
Role
of Quaternions
in
the
History
of
Grassmanns
of Mathematics
(A
1974
New
York University doctoral dissertation). 11
Albert
C.
Lewis,
An
Historical
Analysis
1975 U n i v e r s i t y o f T e x a s a t A u s t i n d o c t o r a l dissertation); A . Ausdehnungslehre A.
and
Schleiermacher's
Dialektik ,"
Annals
Ausdehnungslehre
of 1844
(A
C . L e w i s , " H . G r a s s m a n n ' s 1844
of Science,
34
(1977),
103-162;
C. Lewis, "Justus Grassmann's School Programs as Mathematical Antecedents of H e r m a n n
Grassmann's in
the
Early
1844
Ausdehnungslehre"
Nineteenth
Century,
ed.
in
by
Epistemological
Hans
Niels
and
Jahnke
Social and
Problems
Michael
of the
Otte
Sciences
(Dordrecht,
1981), p p . 2 5 5 - 2 6 7 . 12
Jean
1-14;
Dieudonne,
Desmond
gebra,"
American
"Hermann Monthly, 13
"The
Mathematical
Grassmann
89
(1982),
Helena
Tragedy
Fearnley-Sander, Monthly,
and
of G r a s s m a n n , ' '
"Hermann 86
the
Linear and
Grassmann
(1979),
809-817;
Prehistory
of
Multilinear Algebra,
and
the Creation
see
also
Universal
D.
8
(1979),
of Linear Al-
Fearnley-Sander,
Algebra,"
American
Mathematical
161-166.
M.
Pycior,
"Benjamin
Peirce's
Linear
Associative
Algebra,"
I sis,
70
(1979),
537-551. 14
Hubert
Kennedy,
"James
Mills
Peirce and
t h e C u l t o f Q u a t e r n i o n s , " Historia
Mathemat-
ica, 6 ( 1 9 7 9 ) , 4 2 3 - 4 2 9 . 15
G.
C.
Smith,
Mathematica, 16
B.
9
R.
"Matthew
(1982),
O'Brien's
Anticipation
of Vectorial
Mathematics,"
Historia
172-190.
Gossick,
"Heaviside
and
Kelvin:
A
Study
in
C o n t r a s t s , " Annals
o f Science,
33
(1976), 2 7 5 - 2 8 7 . 17
Victor
J.
Katz,
"The
History
of Stokes'
Theorem,"
Mathematics
Magazine,
52
(1979),
146-156. 18
W . D o b r o v o l s k i j , " D e v e l o p p e m e n t d e l a t h e o r i e des v e c t e u r s e t des q u a t e r n i o n s dans les
travaux des
mathematiciens
russes
du X I X e
siecle,"
Revue d'histoire des sciences,
21
(1968),
345-349. 19
Adalbert
ralis,
12
Apolin,
(1970),
"Die
357-365;
geschichtliche James
Entwicklung der Vektorrechnung,"
W a l t e r Joiner,
A
History of Vector Analysis (A
Historia Natu-
1971
doctoral
dissertation at G e o r g e Peabody C o l l e g e for Teachers). 20
J.
Budon,
quelques (1933), Ideas, the
175-200; 3
(1935),
Philosophy 21
" S u r la r e p r e s e n t a t i o n g e o m e t r i q u e s des n o m b r e s imaginaires (Analyse de
memoires
Imre
parus
de
220-232; 427-474;
and
History
Lakatos,
1795
Ernest reprinted
of Science
"Proofs
a
1820),"
Nagel, in
(New
and
Bulletin
des sciences
"Impossible
Ernest York,
Nagel,
1979),
Refutations,"
mathematiques,
Numbers,"
ser. the
2,
57
History
of
Teleology Revisited and Other Essays
in
pp.
Studies i n
166-194.
British Journal for
the
Philosophy
of Science,
14
( 1 9 6 3 - 1 9 6 4 ) , 1 - 2 5 ; 1 2 0 - 1 3 9 ; 2 2 1 - 2 4 5 ; 2 9 6 - 3 4 2 . T h e s e e s s a y s h a v e n o w b e e n r e p u b l i s h e d as: Imre
Lakatos,
Proof and
Refutations:
The
Logic
of
Mathematical
Discovery,
ed.
by
John
W o r r a l l a n d E l i e Z a h a r ( C a m b r i d g e , E n g l a n d , 1976). 22
M.
Historia 23
ical 24
J. Crowe, " T e n ' L a w s ' C o n c e r n i n g Patterns ofChange in the History of Mathematics," Mathematica,
Carl
B.
2
Boyer,
Thought from
(1975), A
Ancient
161-166.
History o f Mathematics ( N e w Y o r k , to
Modern
Dictionary o f Scientific Biography,
14
Times
(New
vols.,
ed.
1968) a n d
York, by
Morris
Kline,
Mathemat-
1972).
Charles
Coulston
Gillispie
( N e w York,
Science
Formed from
1970-1980). 25
ISIS
ISIS
Cumulative
Critical
1 9 7 1 - 1 9 8 2 ) ; ISIS 1980);
and
Bibliography.
Bibliographies
1-90:
Cumulative
Kenneth
O.
A
Bibliography
1913-1965,
Bibliography May,
5
of
vols.,
1966-1975, Bibliography
vol. and
the
ed.
History by
I,
Research
of
Magda
ed.
by
Manual
Whitrow
John of the
Neu History
(London, (London, of Mathematics
( T o r o n t o , 1973). XV
CHAPTER
The
I.
Earliest
ONE
Traditions
Introduction The
early
history
of
vectorial
analysis
is
most
viewed within the context of two broad traditions
appropriately
in the history of
science. O n e of these traditions relates to mathematics, the other to physical
science.
T h e first tradition, that w i t h i n the history of mathematics, extends from the time of the Egyptians and Babylonians to the present and consists
in
the
progressive
Throughout time to include
the
broadening of the
concept of number.
c o n c e p t of n u m b e r has b e e n e x p a n d e d so as
not only positive
integers, but negative
numbers,
frac-
tions, and algebraic and transcendental irrationals. E v e n t u a l l y complex
and
higher complex
numbers
(including
vectors)
were intro-
duced. T h e activities of some of the figures in the history of vector analysis m a y be v i e w e d as b e l o n g i n g to this tradition. The also
second tradition, that w i t h i n the history of physical science,
extends
back
mathematical
to
ancient
entities
and
times
a n d consists
operations
that
in the
represent
search for aspects
of
physical reality. This tradition p l a y e d a part in the creation of G r e e k geometry, and the inherited problems.
from
natural philosophers of the seventeenth century
the
Greeks
However
in the
the
geometrical
course
of the
approach
seventeenth
to
physical
century the
physical entities to be represented passed t h r o u g h a transformation. This
transformation
consisted
in
the
shift
in
emphasis
from
such
scalar q u a n t i t i e s as p o s i t i o n a n d w e i g h t to s u c h v e c t o r i a l q u a n t i t i e s as velocity, force, m o m e n t u m , and acceleration. T h e transition was neither abrupt nor was it confined to the seventeenth century. Later developments to
transform
with
in
the
electricity, space
magnetism,
of mathematical
and
optics
physics
into
acted
further
a space filled
vectors.
These two broad traditions converged at a n u m b e r of periods history;
one
such
period
was
in the
in
nineteenth century, and this
1
A H i s t o r y of V e c t o r Analysis
convergence
is
marked
by
the
creation
and
d e v e l o p m e n t of vec-
torial methods. T h e first major three-dimensional vectorial systems were
created in
portant ideas
1840,s.
the
Before
were put forth w h i c h
this
time, however, three im-
l e d t o t h e m a j o r v e c t o r i a l sys-
tems. T h e s e t h r e e ideas are the subject of the present chapter; t h e y are the c o n c e p t of a p a r a l l e l o g r a m of forces, L e i b n i z ' c o n c e p t of a geometry of situation, and the concept of the geometrical representation
of imaginary
II.
The and
Concept
numbers.
of
the
Parallelogram
of
Velocities
Forces
O n e of the most f u n d a m e n t a l m a t h e m a t i c a l ideas in vector analysis
is
the
idea of the addition of vectors.
T h e sum of t w o vectors
w h i c h have a c o m m o n point of origin is defined as the vector originating at the same point and extending to the opposite corner of the parallelogram d e f i n e d by the t w o original vectors. Certain physical entities,
such
as
velocities
a n d forces,
m a y be c o m p o u n d e d
in
a
similar w a y , a n d f r o m this c o r r e s p o n d e n c e stems m u c h of the usefulness
of vector analysis.
T h e idea of a parallelogram of velocities may be found in various ancient forces
authors,8 *
Greek was
not
uncommon
and in
the the
concept
of a
parallelogram
of
sixteenth and seventeenth cen-
turies.9 By the early n i n e t e e n t h century parallelograms of physical entities
frequently
appeared
in
treatises,
and
this
usage
indirectly
led to vector analysis, for this idea p r o v i d e d a striking example of how
vectorial
entities
could
be
used
for physical
applications.
It
s h o u l d not be inferred, h o w e v e r , that all of those w h o used the concept of a parallelogram of physical entities were aware of the idea of a vector or of vector addition.
T h e essential
idea in the parallelo-
gram of physical entities is the construction of a diagram in terms of w h i c h the operations involved in determining the resultant become evident.
The
i d e a o f adding t h e l i n e s n e e d n o t b e i n t r o d u c e d o r w a s
i t (to m y k n o w l e d g e ) e v e r i n t r o d u c e d b e f o r e t h e c r e a t i o n o f vectors. T h u s this
i d e a a l o n e c o u l d n o t a n d a l m o s t c e r t a i n l y d i d n o t directly
s t i m u l a t e a n y o n e to t h e c r e a t i o n of a vectorial system. Its i n f l u e n c e was
indirect b u t i m p o r t a n t , f o r i t w a s t h e f i r s t a n d m o s t o b v i o u s c a s e
in w h i c h vectorial methods could be brought to the aid of physical science. ° T h e system used for n u m b e r i n g notes is described in the preface.
2
The
III.
Leibniz'
Concept
of
a
Geometry
of
Earliest
Traditions
Situation
Gottfried W i l h e l m Leibniz (1646-1716) made many contributions to
mathematics;
among
geometry of situation.
the
In
less
this
well
regard
known
is
Leibniz
his
concept
discussed
of a
the possi-
bility of creating a system w h i c h w o u l d serve as a direct m e t h o d of space
analysis.
Although
the
details
of this
idea were
never fully
w o r k e d out by L e i b n i z , he a d v a n c e d far e n o u g h to be r a n k e d as a conceptual
forerunner of the
essay, w h i c h w a s
history of vectorial Leibniz' main 8,
first
vectorial
first p u b l i s h e d in
analysts.
M o r e o v e r his
1833, p l a y e d a part in the later
analysis.
ideas w e r e contained in a letter dated S e p t e m b e r Huygens.1
1679, a n d w r i t t e n to Christian
In this
letter L e i b n i z
wrote: I am still not satisfied w i t h algebra, because it does not give the shortest methods or the most beautiful constructions in geometry. This is w h y I believe that,
so far as
geometry is
concerned, we
need still
another
analysis w h i c h is distinctly geometrical or linear a n d w h i c h w i l l express situation
[situs]
directly
as
algebra
expresses
magnitude
directly.
And
I
believe that I have f o u n d the w a y a n d that we can represent figures a n d even
machines
and
movements
by
characters,
as
algebra represents
n u m b e r s or m a g n i t u d e s . I am s e n d i n g y o u an essay w h i c h seems to me t o b e i m p o r t a n t . (1; 3 8 2 ) I n his essay, w h i c h was c o n t a i n e d i n the letter, L e i b n i z d e s c r i b e d his
system further: I
have discovered certain e l e m e n t s of a n e w characteristic w h i c h is
entirely different f r o m algebra a n d w h i c h w i l l have great advantages i n r e p r e s e n t i n g t o t h e m i n d , e x a c t l y a n d i n a w a y f a i t h f u l t o its n a t u r e , e v e n w i t h o u t f i g u r e s , e v e r y t h i n g w h i c h d e p e n d s o n sense p e r c e p t i o n . A l g e b r a is the characteristic for u n d e t e r m i n e d n u m b e r s or m a g n i t u d e s o n l y , b u t it does not express situation, angles, a n d m o t i o n directly. H e n c e it is often difficult to analyze the properties of a figure by calculation, and still more difficult to find very convenient geometrical demonstrations and constructions,
even
w h e n the algebraic calculation
is completed.
But
this n e w characteristic, w h i c h follows the visual figures, cannot fail to give the solution, the construction, and the geometric demonstration all at the
same time,
and
in
a natural
w a y and in
one
analysis,
t h a t is,
through determined procedure.
B u t its c h i e f v a l u e l i e s i n t h e r e a s o n i n g w h i c h c a n b e d o n e a n d t h e c o n clusions could
which
not
be
c a n b e d r a w n b y o p e r a t i o n s w i t h its c h a r a c t e r s , w h i c h expressed
in
figures,
and
still
less
in
models,
without
m u l t i p l y i n g these too greatly o r w i t h o u t c o n f u s i n g t h e m w i t h too m a n y points and lines in the course of the m a n y futile attempts one is forced to
make.
This
method,
by contrast, w i l l g u i d e us
surely and without
3
A
History
effort.
of V e c t o r Analysis
I b e l i e v e that by this m e t h o d one c o u l d treat mechanics almost
l i k e g e o m e t r y , a n d o n e c o u l d e v e n test the qualities of materials, because this o r d i n a r i l y d e p e n d s o n c e r t a i n f i g u r e s i n t h e i r s e n s i b l e parts. F i n a l l y , I have no h o p e that we can get v e r y far in physics u n t i l we have f o u n d s o m e s u c h m e t h o d o f a b r i d g m e n t t o l i g h t e n its b u r d e n o f i m a g i n a t i o n . (1; 3 8 4 - 3 8 5 )
His
system
as actually sketched by h i m shows that he by no means
discovered a primitive vector analysis, though the above quotations show
that
he
was
searching
for
s o m e t h i n g a k i n to vector analysis.
L e i b n i z ' s y s t e m c e n t e r e d o n t h e i d e a o f t h e c o n g r u e n c e o f sets o f points.
He used A, B, . . . to represent fixed points and X, Y , . . . to
represent u n k n o w n relation
points.
congruence;
The
thus
he
s y m b o l b was used to express the wrote
A B C b DEF
to
express
that
a
set of t h r e e p o i n t s A, B, C, e a c h of w h i c h w a s a fixed distance f r o m t h e o t h e r t w o p o i n t s , c o u l d b e m a d e t o c o i n c i d e w i t h a n o t h e r set o f similarly fixed points D, E, F. He then discussed locus relations and stated that the locus of points congruent to a
fixed
space
g i v e n t h a t AB
infinite
in
all
directions."
(1;
387)
If it is
point " w i l l be a b
AY,
the p o i n t values of Y w i l l be points on a sphere w i t h center at A and radius
of
whose
points
length
A B C b A B Y
(X)
AB.
The
are
equidistant
determines
relation
AX b BX
from
a circle.
locus
that the
of all
Y's
r e l a t i o n AY
will V
BY
be V
a
determines
and
B,
and
a
the
plane
relation
L e i b n i z then discussed the locus
of points Y satisfying the relation AY "the
A
b BY
straight
CY V
DY
line."
b
CY and c o n c l u d e d that (1;
389)
determines
applied his analysis to four simple problems.
After
showing
a point, Leibniz
O n e of these may be
discussed as typical. T h e p r o b l e m is to show that the intersection of two planes plane,
is a straight line.
and
the
combining before,
relation
these
we
determines
AY
have
T h e relation AY b BY determines one b CY
AY
determines
b BY b CY,
a
second
which,
as
plane.
it was
By
shown
a straight line.10
Proceeding from this s u m m a r y of Leibniz' best-known exposition system,11
of his sis.
First,
w e m a y d i s c u s s its r e l a t i o n t o m o d e r n v e c t o r a n a l y -
Leibniz
deserves
much
credit for suggesting that a n e w
algebra, w h e r e i n geometrical entities are symbolically represented and he
the
symbols
operated u p o n directly, was
desirable.
However,
failed to discover a system in w h i c h geometrical entities could
be a d d e d , subtracted, a n d m u l t i p l i e d . L i k e w i s e he failed to see that A B a n d B A (for e x a m p l e ) can b e v i e w e d a s distinct entities a n d that —AB
could have a significant meaning.
representing runner the
4
of
a
fixed
Mobius
concept
point
and
of a vector.
by
a
T h o u g h his idea of directly
symbol
Grassmann,
he
makes
certainly
him did
a partial forenot
introduce
D e s p i t e the fact that angle considerations
The
Earliest Traditions
d i d not enter into his system, he still m u s t be v i e w e d as h a v i n g constructed a system w h i c h a l l o w e d for the use of co-ordinai^s. L e i b n i z saw that a n e w algebra of the applications failed
to
in
mathematics
develop
Leibniz'
system
practical taken
form
and
sought
in
methods
by
w o u l d have
the physical for these
Couturat,
though
numerous
sciences, but he
tasks.
stated
The in
view
of
relation
to
Grassmann's system, is also a p p l i c a b l e in r e l a t i o n to m o d e r n vector analysis; Couturat wrote:
" I n summary, the calculus of Grassmann
seems to bring fully into reality the geometrical characteristic conceived by Leibniz, and shows that Leibniz' idea was not simply a dream. But there is such a disproportion b e t w e e n Leibniz' conception
of a
system
and
the
very
defective
p r o d u c e d that Grassmann felt a sharp
essay
which
he
actually
distinction should be made
between the ideal conceived and the sketch actually written." Shortly after Jablonowski
1833,
12
w h e n L e i b n i z ' essay was first p u b l i s h e d , the
Gesellschaft expressed their interest in
and enthusi-
asm for the essay by offering a prize for the f u r t h e r d e v e l o p m e n t of Leibniz'
system.
One
mathematician entered the competition and
w o n the prize, e v e n t h o u g h he had created his system before hearing of L e i b n i z ' ideas; this mathematician was Grassmann a n d this incident w i l l be more fully discussed in the third chapter.
IV.
The of
Concept
Complex
Though ence
to
the
term
systems
dimensional
of
the
Geometrical
Representation
Numbers vector
of
space,
analysis
is
mathematics it
should
now
that
not
be
used
may
primarily
be
applied
forgotten
that
in
refer-
in
the
three-
complex
n u m b e r s y s t e m m a y l e g i t i m a t e l y be c o n s i d e r e d as a v e c t o r i a l system.
The
metrical useful
as
two-dimensional representation the
of
vectorial complex
three-dimensional
primary subject of this history. cuss
briefly
system
based
numbers
vectorial
is
on
the
certainly
systems
which
geo-
not are
as the
Nevertheless it is i m p o r t a n t to dis-
the early history of the
geometrical representation
of
complex numbers, not only because the complex n u m b e r system is (broadly
speaking)
a vectorial
system
b u t also
because
Hamilton
discovered quaternions in the course of a search for a t h r e e - d i m e n sional analogue to the complex n u m b e r system. A t least six m e n are c o m m o n l y c r e d i t e d w i t h t h e d i s c o v e r y o f t h e geometrical
representation
of complex
numbers;
t h e y are Wessel,
Gauss, Argand, Buee, M o u r e y , a n d Warren.13 Since the systems crea t e d b y these six m e n are v e r y s i m i l a r a n d are o f l i m i t e d r e l e v a n c e to
the
present
study, they need not all be discussed in
detail.
In
5
A H i s t o r y of V e c t o r Analysis
w h a t follows, the system p u b l i s h e d by Wessel, w h i c h was the earliest a n d a m o n g t h e m o s t i m p r e s s i v e , w i l l b e a n a l y z e d i n s o m e d e p t h ; t h e ideas o f t h e o t h e r f i v e m e n w i l l b e t r e a t e d less f u l l y t h o u g h w i t h special will
be
attention
to
certain
shown
that
some
three-dimensional
aspects of their d e v e l o p m e n t . T h u s it of
vectorial
these
mathematicians
systems
and
that
one
searched
of them
for
influ-
enced Hamilton in an important manner. Although
Hero
of Alexandria
and
Diophantus
in ancient times
h a d encountered the question of the m e a n i n g of the square root of a negative
number,
and although
Cardan
had in his
1 5 4 5 Ars Magna
used complex numbers in computation, nevertheless complex numbers were not accepted by most mathematicians as legitimate mathematical
entities
until
well
into
hardly surprising since numbers
the
nineteenth
such as
century.
This is
V ^ T seem to be neither
less t h a n , greater t h a n , n o r e q u a l to zero. In
modern
mathematics
complex
numbers
are
usually justified
either by representing t h e m in terms of couplets of real numbers or by representing them geometrically. T h e origin of the first method w i l l be discussed in the next chapter. T h e first attempt (which was unsuccessful)
to
represent
complex
numbers
geometrically
was
m a d e in the seventeenth century by John Wallis.14 W h e r e Wallis failed, a Norwegian Caspar Wessel geometrical
(1745-1818)
representation
surveyor succeeded;
in
1799
published the first explanation of the of complex
numbers.15
His
ideas w e r e
p r e s e n t e d before the Royal A c a d e m y o f D e n m a r k i n 1797 a n d publ i s h e d t w o years later in the m e m o i r s of that society.2 Unfortunately, however, Wessel's ematicians until
publication went unnoticed by European math-
1897, w h e n it was r e p u b l i s h e d in a F r e n c h transla-
tion.3 In the first paragraph of his m e m o i r W e s s e l stated: attempt
deals
with
the
question,
"This present
h o w may we represent direction
a n a l y t i c a l l y ; t h a t is, h o w s h a l l w e e x p r e s s r i g h t l i n e s s o t h a t i n a single the
equation length
i n v o l v i n g one u n k n o w n line and others k n o w n , both and
the
direction
of the
unknown
line
may
be
ex-
p r e s s e d . " (2; 55) A s t h i s q u o t a t i o n suggests a n d later passages confirm, Wessel's chief interest was the creation of geometrical methods; his representation of c o m p l e x n u m b e r s was subservient to this aim.
Nonetheless
the
latter p l a y e d a f u n d a m e n t a l role as is indi-
cated by the following statement: treatise]
was
my
" T h e o c c a s i o n for its b e i n g [his
seeking a method whereby I could avoid the im-
possible operations. . .
(2; 57)
After stating that previously only oppositely directed lines could be r e p r e s e n t e d analytically, W e s s e l suggested that it s h o u l d be pos-
6
The
sible to a
find
definition
added
Traditions
methods to represent inclined lines. Wessel then gave of the
if we
Earliest
addition
of straight
lines:
" T w o
unite t h e m in such a w a y that the
right
lines
are
second line begins
w h e r e t h e first o n e e n d s , a n d t h e n pass a r i g h t l i n e f r o m t h e first to t h e last p o i n t o f t h e u n i t e d lines. T h i s l i n e i s t h e s u m o f t h e u n i t e d lines."
(2;
58)
In
the
subsequent
discussion
of addition
Wessel
stated that the same definition can be used in a d d i n g m o r e than t w o (not necessarily coplanar) lines a n d that the order of addition is immaterial.
(2;
59)
Hence Wessel
had
introduced three-dimensional
vector addition and realized the importance of the commutative law for
addition.
Though
Wessel
had
up
to
called the positive unit (our 1
this of x
point •
only
discussed
what
he
1 + yV—I) a n d h a d n o t y e t i n d i -
cated h o w lines in general were to be represented in terms of complex numbers, nevertheless he proceeded to introduce the multiplication of lines.
The
product of two lines
(coplanar with each other
and w i t h the positive unit) was to have a length equal to the product of the lengths of the t w o factors. T h e p r o d u c t l i n e was to be coplanar w i t h t h e t w o factor l i n e s a n d w a s t o h a v e its i n c l i n a t i o n o r d i r e c t i o n angle (defined by reference to the inclination of the positive unit as 0°) e q u a l Wessel
to the
then
L e t 4-1
sum
of the
inclinations
of the
factor lines.
(2; 60)
added:
designate the positive rectilinear unit and +e a certain other
unit perpendicular to the positive unit and having the same origin; then t h e d i r e c t i o n a n g l e o f + 1 w i l l b e e q u a l t o 0°, t h a t o f - 1 t o 180°, t h a t o f + e t o 90°, a n d that o f - e t o - 9 0 ° o r 270°. B y t h e r u l e that t h e d i r e c t i o n a n g l e of the p r o d u c t shall e q u a l the s u m of the angles of the factors, we have: (+1)(+1) = + 1 ;
( + 1 ) ( — 1 ) = —1; ( - 1 ) ( - 1 ) = + 1 ; ( + l ) ( + e ) = +
(-l)(+e) = - e ; ( - l ) ( - € ) = +6;
(+e)(+e) = - 1 ;
e ;
(+e)(-e) = + 1 ;
(+l)(-6) = -
€ ;
(-e)(-e) = - 1 .
F r o m this it is seen that e is equal to V ^ I ; a n d the divergence of the product is d e t e r m i n e d such that not any of the c o m m o n rules of operation are c o n t r a v e n e d . (2; 60) Wessel
stated that any straight line in a plane m a y be represented
analytically showed
how
by
the
expressions
such
expressions
a +
eb
and
are to be
r(cos
v + €
multiplied,
v)
and
divided,
sin
and
raised to powers.
After giving t w o examples of the application of his
methods, Wessel
developed an elementary three-dimensional vec-
tor analysis.
(3; 2 3 - 2 8 )
Wessel began by constructing three mutually perpendicular lines w h i c h passed t h r o u g h the center of a sphere of radius r. W e s s e l specified three
that three radii
of the sphere w h i c h were collinear with the
m u t u a l l y p e r p e n d i c u l a r axes
s h o u l d be
designated by r,
171%
and er and that any point in space c o u l d be designated by a vector of
7
A H i s t o r y of V e c t o r Analysis
t h e f o r m x + r)y + ez.
(3;
23-24)
By a n a l o g y w i t h o r d i n a r y c o m p l e x
n u m b e r s W e s s e l d e f i n e d 1717 a n d e e a s e q u a l t o — 1 . T h e m u l t i p l i c a tion
of vectors corresponded to the rotation and extension of one
v e c t o r by a n o t h e r . T h u s (x
f 171/ + ez)
,,
( c o s u + € s i n u) r e p r e s e n t e d
t h e r o t a t i o n o f t h e v e c t o r x + iqy + e z t h r o u g h t h e a n g l e u a r o u n d t h e 17 or y axis. W e s s e l stated that t h e c o m p o n e n t of t h e v e c t o r that lies on
the
axis
product
of
of t h e
rotation above
is
should 17y +
remain x
cos
unchanged,
u — z
sin
and
thus
u + ex s i n
the
u + ez
cos u . ( 3 ; 2 5 - 2 6 ) T h e s y m b o l , , w a s u s e d t o i n d i c a t e m u l t i p l i c a t i o n . A r o t a t i o n of v d e g r e e s a r o u n d t h e € or z axis w a s e x p r e s s e d in t h e f o l l o w i n g w a y : (x + 1 7 y + ez)
,, ( c o s v + 1 7 s i n v) = ez + x c o s v — y s i n v
+ rjx s i n v + 7)y c o s v . ( 3 ; 2 6 ) R o t a t i o n s a r o u n d t h e 1 7 a x i s c o u l d b e compounded with
rotations
a r o u n d t h e € axis a n d v i c e versa, b u t
r o t a t i o n s a r o u n d t h e axis of t h e p o s i t i v e u n i t (the x axis) w e r e n e v e r discussed by Wessel. T h e reason for this is that serious mathematical
difficulties
were
involved
in
determining how
such
rotations
s h o u l d b e r e p r e s e n t e d , f o r e x a m p l e , t h e p r o d u c t s 17c a n d erj w o u l d h a v e h a d to be defined. W e s s e l p r e s u m a b l y e n c o u n t e r e d these difficulties b u t c o u l d not solve them.16 But even w i t h this limitation on his m e t h o d s Wessel was able to use t h e m to derive a n u m b e r of important results in spherical trigonometry. Wessel's
t h r e e - d i m e n s i o n a l v e c t o r i a l s y s t e m e x h i b i t e d a n a d hoc
character that makes
it appear seriously deficient w h e n compared
to m o d e r n systems; nevertheless, if it is v i e w e d as a creation of the late
eighteenth century, it can only be v i e w e d w i t h awe. Wessel's
treatment of ordinary complex numbers is equally impressive, and it was unfortunate for Wessel a n d for mathematics that his m e m o i r lay b u r i e d for nearly a century. In the early history of complex numbers a striking p h e n o m e n o n occurred:
on three separate occasions t w o m e n i n d e p e n d e n t l y and
simultaneously
discovered
the geometrical representation of com-
plex numbers. In 1806 A r g a n d a n d Buee both p u b l i s h e d independent
treatments
of imaginary
numbers,
and the
same
coincidence
o c c u r r e d i n 1828 w i t h M o u r e y a n d W a r r e n . W h a t i s e v e n m o r e surprising
is
that
Gauss
probably
discovered the
geometrical repre-
sentation of complex numbers at the same time as Wessel. Gauss' tion
first
published
treatment
of the geometrical representa-
of complex numbers appeared in
1831;
17
herein Gauss com-
m e n t e d that h e h a d h a d this i d e a for m a n y years a n d that traces o f i t could Lowell
easily be f o u n d in his Coolidge
investigated
1799 this
"Demonstratio Nova." point
and
showed
18
that
Julian Gauss'
c l a i m was a m p l y s u p p o r t e d b y the fact that s o m e m e t h o d s u s e d i n the
8
1799
paper
seem
"blind
and meaningless"
unless the author
The
Earliest Traditions
already possessed this idea.19 It was t h r o u g h Gauss'
1831 publica-
tion that most mathematicians came into contact w i t h the geometrical
representation of complex numbers, although
of Gauss'
paper
only
in
1852
However Hamilton heard in
(4;
312)
and
Hamilton
Grassmann
1845 that Gauss
heard 1844.20
in
had been
searching
for a "triple algebra" corresponding to the d o u b l e algebra of complex numbers. tion
(4; 3 1 1 - 3 1 2 ) F e l i x K l e i n a r g u e d i n a n 1 8 9 8 p u b l i c a -
that Gauss
Knott
had in
vigorously
accept
the
fact d i s c o v e r e d this.21
denied
geometrical
quaternions,
Ironically
representation
Gauss
but Tait and
himself did
of c o m p l e x
numbers
not
as
a
sufficient justification for them.22 In conclusion it m a y be n o t e d that Gauss' p u b l i c a t i o n w a s t h e shortest, t h e m o s t precise, t h e last, a n d the most influential
o f t h e six i n d e p e n d e n t p r e s e n t a t i o n s .
T h e next p u b l i c a t i o n to be c o n s i d e r e d was the longest, the least precise, the earliest (except for Wessel's), a n d the least influential. On J u n e 20, 1805, a l o n g essay e n t i t l e d " M e m o i r e sur les q u a n t i t e s imaginaires"
was
read before
the
Royal
Society
of London.
The
author was A b b e B u e e a n d his paper was p u b l i s h e d ( w i t h o u t translation)
in
the
1806
Transactions
of
the
Society.23
Royal
treatment of complex numbers was not of high quality; fact
has
expressed
surprise
that
it
was
Buee's
Coolidge in
published.24
The
well-
founded consensus a m o n g those w h o have studied Buee's paper is that
some
ingenuity
mixed
with
much
obscurity
is
to
be
found
there, as w e l l as a near approach to the concept of the m u l t i p l i c a t i o n of directed lines.
H a m i l t o n asserted that B u e e attempted to extend
his m e t h o d s t o space (5; [57]), b u t i f B u e e d i d d o t h i s , h e d i d i t i n a very
unorthodox
manner.
A far s u p e r i o r w o r k also a p p e a r e d in Argand's tites
small
book,
imaginaires
Essai
dans
sur
les
une
1806; this was Jean Robert maniere
constructions
de
representer
les
geometriques.6
quan-
Herein
Argand gave the m o d e r n geometrical representation of the addition and multiplication of complex numbers, and s h o w e d h o w this representation
could
trigonometry,
be
applied to deduce a n u m b e r of theorems
elementary
geometry, and algebra.
in
At this t i m e Ar-
gand d i d not attempt to e x p a n d his m e t h o d s for application to threed i m e n s i o n a l space. F o r seven years A r g a n d shared the fate of W e s sel;
however
unexpected In
in
1813 J.-F.
Gergonne's
1813
attention
was
called to his
book in
a very
way. Frangais published a short m e m o i r in v o l u m e IV of
Annates
de
mathematiques
(6;
63-74),
in
which
Fran-
gais p r e s e n t e d t h e g e o m e t r i c a l r e p r e s e n t a t i o n o f c o m p l e x n u m b e r s . At the conclusion of his paper Frangais stated that the f u n d a m e n t a l ideas in his paper w e r e not his o w n ; he h a d f o u n d t h e m in a letter
9
A
History
of V e c t o r Analysis
w r i t t e n by L e g e n d r e to his (Frangais') brother w h o had died. In this letter L e g e n d r e discussed the ideas of an u n n a m e d mathematician. Frangais
a d d e d that he h o p e d that this mathematician w o u l d make
himself k n o w n and publish his The
unnamed
ideas,
for
Legendre's
Frangais'
paper,
Gergonne
in
results.
mathematician friend
Argand
which
he
had
(6;
in
was Jean
already
p u b l i s h e d his
Robert Argand.
immediately
identified
74)
fact
sent
a
Hearing of
communication
to
himself as the mathematician of
L e g e n d r e ' s l e t t e r , c a l l e d a t t e n t i o n t o h i s b o o k , s u m m a r i z e d its c o n tents, a n d
finally
presented an (unsuccessful) attempt to extend his
system to three-dimensions. lications,
(6; 7 6 - 9 6 ) B e f o r e s e e i n g A r g a n d ' s p u b -
Frangais h a d w r i t t e n a letter to G e r g o n n e containing his
admittedly unsatisfactory attempts to extend the geometrical representation of c o m p l e x n u m b e r s to space.
(6;
96-101) A n d soon after
Argand's publication, Servois published a paper criticizing Argand's attempt and (6;
o u t l i n i n g his o w n ideas on a m e t h o d of space analysis.
101-109)
to
an
Hamilton
anticipation
triplets.
.
. ."
o f the
(5;
[57])
f o l l o w i n g passage
attributed
quaternions,
or
to at
In m a k i n g this
from
Servois least
to
"the an
nearest
approach
anticipation
statement Hamilton
of
had the
Servois' paper in mind.
Analogy w o u l d seem to
indicate that the tri-nominal should be of the
f o r m p cos a + q cos (3 + r cos y, a,
a n d y b e i n g t h e a n g l e s m a d e by a
r i g h t l i n e w i t h t h r e e r e c t a n g u l a r axes, a n d t h a t we s h o u l d h a v e (p cos a + q c o s (3 + r c o s y)(p' c o s a + q' c o s (3 + r' c o s y) = c o s 2 a + c o s 2 /3 + c o s 2 y — 1 . T h e v a l u e s o f p , q , r , p ' , q', r ' s a t i s f y i n g t h i s c o n d i t i o n w o u l d b e absurd;
but
A+
would
B V ^ I ? (7;
they
be
imaginaries,
reducible
to
the
general
form
114-115)
C o n c e r n i n g this
passage
Hamilton
wrote:
T h e s i x N O N - R E A L S w h i c h S e r v o i s t h u s w i t h r e m a r k a b l e s a g a c i t y foresaw,
without
b e i n g a b l e t o determine t h e m ,
the ther; u n k n o w n symbols +i, at
least,
these
latter
him, and furnish
may n o w be
identified with
+ / c , — i , — j , —/c, o f t h e q u a t e r n i o n t h e o r y :
symbols
fulfil
p r e c i s e l y t h e condition p r o p o s e d b y
a n answer t o h i s " s i n g u l a r q u e s t i o n . " I t m a y b e p r o p e r
t o state that m y o w n t h e o r y h a d b e e n c o n s t r u c t e d a n d p u b l i s h e d for a l o n g t i m e , b e f o r e t h e l a t e l y c i t e d passage h a p p e n e d t o m e e t m y eye. (5; [57]) The
series
of articles
in
Gergonne's
letter written by A r g a n d in w h i c h by
Lacroix
(6;
111)
Annales
was
concluded
calling attention to
Buee's
(1806)
this
very
point were
nions
10
is
in
1843.25
strong evidence unknown to The
ideas
that all
Hamilton of the
a
publication.
A r g a n d w r o t e t h a t h e h a d h a d n o k n o w l e d g e o f B u e e ' s w o r k . (6; There
by
he responded to a notice sent in
the
men
123)
discussed up to
w h e n he discovered quater-
next man
to be
discussed were
The
k n o w n to H a m i l t o n as early as thinking,
as
published cal
he
in
repeatedly
1828
Representation
a of
Earliest Traditions
1829 a n d m o r e o v e r i n f l u e n c e d his
acknowledged.
short
book
the
Square
(4;
entitled A Roots
190)
Treatise of
John Warren on
the
Negative
GeometriQuantities.
Warren's
presentation of the geometrical representation of complex
numbers
e x h i b i t e d great care a n d u n d e r s t a n d i n g ; he, u n l i k e B u e e
a n d A r g a n d , was a w a r e o f t h e i m p o r t a n c e o f t h e c o m m u t a t i v e , associative, and distributive laws, t h o u g h he d i d not use these terms.26 W a r r e n discovered his ideas in c o m p l e t e i n d e p e n d e n c e of the other mathematicians
who
wrote
on
the
geometrical
representation
of
complex numbers, b u t he, unlike the majority of t h e m , d i d not discuss t h e e x t e n s i o n o f h i s s y s t e m t o space.27 T h e final independent discoverer of the
geometrical representa-
tion of complex n u m b e r s was the F r e n c h m a n C. V. M o u r e y , w h o in 1828
published
quantites
an
negatives
excellent et
des
the conclusion of his book bra surpassing
treatise
entitled
quantites
La
pretendues
vrai
Theorie
imaginaires.28
des At
M o u r e y stated that there exists an alge-
not o n l y o r d i n a r y algebra b u t also the t w o - d i m e n -
sional algebra created by him.
This
algebra, he stated, extends to
three-dimensions.29 Presumably M o u r e y searched for such an algebra; if he f o u n d it, he d i d not p u b l i s h his discovery.
V.
Summary
and
Conclusion
T h u s w e can say that a t least f i v e m e n , w o r k i n g i n d e p e n d e n t l y o f each other, had by 1831 discovered and p u b l i s h e d the geometrical representation
of
complex
numbers.
These
men
were
Wessel,
Gauss, A r g a n d , W a r r e n , a n d M o u r e y . A t least t w o others, W a l l i s a n d Buee, had c o m e close to the same idea. Wessel, Gauss, Argand, a n d M o u r e y , a s w e l l a s S e r v o i s a n d F r a n g a i s , a n d p e r h a p s B u e e , h a d attempted to
find
higher c o m p l e x n u m b e r s for the analysis of space,
and all had failed. A number of conclusions cussed.
The
first is
m a y be d r a w n f r o m w h a t has b e e n dis-
that the
idea of a graphical representation of
complex numbers was certainly " i n the air" at that time. H o w e v e r , the acceptance of this idea was very slow, and little attention was p a i d to these ideas u n t i l Gauss p u b l i s h e d his p a p e r of 1831.
The
fact that the i d e a was n e g l e c t e d u n t i l Gauss e n t e r e d t h e f i e l d s h o u l d not, I think, be taken as surprising. peatedly
shown
that
radically
new
H i s t o r i a n s of science h a v e reideas
presented only on their
o w n merits are usually neglected. T h e m e n b e f o r e Gauss w e r e all little k n o w n ;
i n d e e d t h e y are n o w k n o w n o n l y because o f t h e i r o n e
great discovery. B u t w h e n Gauss wrote, he w r o t e w i t h the authority
11
A H i s t o r y of V e c t o r Analysis
of one w h o had already acquired fame through impressive work in traditional fields and through his w i d e l y k n o w n prediction of the position of the lost p l a n e t o i d Ceres.
It m a y be n o t e d n o w a n d dis-
cussed later that the pattern exhibited in this instance w i l l recur in the later history of vectorial analysis. S e c o n d , i t has b e e n n o t e d that m o s t o f those w h o w o r k e d o n the geometrical
representation
struct analogous
methods
of c o m p l e x n u m b e r s a t t e m p t e d to confor t h r e e - d i m e n s i o n a l space. T h a t m a n y
e m b a r k e d on this quest illustrates w h a t is probably mathematically o b v i o u s : the search for a system of space analysis was a natural concomitant to the numbers. fore
idea of the
geometrical representation of complex
Up to this point only those w h o m a d e their attempts be-
1831 h a v e b e e n discussed; m a n y others also p u z z l e d over this
p r o b l e m after 1831. A m o n g t h e m was H a m i l t o n , w h o , w o r k i n g precisely in this tradition, discovered quaternions.
12
Notes 1
Gottfried W i l h e l m
Christian Leroy E. first
Leibniz, "Studies
Huygens"
in
Loemker, vol.
published
mathematische
in
und
"Christi.
Leibniz,
I
1833;
Papers
(Chicago, 1956), 3 8 1 - 3 9 6 . the
physikalische
Huygenii
in a G e o m e t r y of Situation w i t h a Letter to
Philosophical
citation
Werke,
as
vol.
aliorumque
given
I,
seculi
pt.
based
Schriften, e d . (which
C.
is
sophic, e d .
I.
translation
Gerhardt, vol.
superior)
as
on II
the
given
are
above)
and
Hermann (Leipzig,
in
and
from
Loemker and
Uylenbroek's
have
text as
trans.
Grassmann, 1894),
Gesammelte
415-416,
celebrium
is
exercitationes
H a g a e c o m i t u m 1833. fasc. I I , p . 6 . " as
1850),
given
in
Leibniz,
Mathematische
17-27, a n d on U y l e n b r o e k ' s text
Leibniz,
Hauptschriften
zur
Griindung
been checked with
the
der
Philo-
1924). Q u o -
Gerhardt's text
g i v e n i n G r a s s m a n n , Werke, v o l .
I, pt.
(cited
I, 417-420.
All quotations have been taken from Martin A. Norgaard's English translation of
the first sixteen sections of Wessel's book; A
in
virorum
text
(Berlin,
ed.
E r n s t Cassirer, trans. A. B u c h e n a u , 2nd. ed., 2 vols. ( L e i p z i g ,
tations
2
his
Letters,
I
XVIII.
mathematicae et philosophiae. Ed. Uylenbroek. Loemker
and
L e i b n i z ' essay a n d letter w e r e
Source
55-66.
Book
I
in
Mathematics,
have also
vol.
used the
I,
ed.
French
see W e s s e l , " O n C o m p l e x N u m b e r s " i n
David
Eugene
Smith
translation of Wessel's
(New
book
York,
1959),
w h i c h is cited in
n o t e (1) a b o v e . T h e t i t l e f o r W e s s e l ' s o r i g i n a l p u b l i c a t i o n i s " O m D i r e c t i o n e n s a n a l v tiske
Betegning,"
Danske
Videnskabernes
by S. Lie
and
it
appeared
Selskabs
Skrifter.
in
vol.
V
Wessel's
(1799)
essay
o f Nye
was
Samling
a f det
rediscovered
Kongelige
in
1895
D. Christensen and C. Juel; it was republished without translation by Sophus in
the
1896
Archiv for
Mathematik
og
Naturvidenskab.
In
this
connection
see
Viggo Brun, "Caspar Wessel et l'introduction geometrique des nombres c o m p l e x e s " in
Revue 3
d'histoire
Caspar
des
Wessel,
sciences, Essai
12
sur
(1959), la
V a l e n t i n e r a n d T . N . T h i e l e , trans. 4
Robert
Perceval
Graves,
20-21.
representation
analytique
de
la
direction,
ed.
H. G. Z e u t h e n and others (Copenhagen,
Life
of
Sir
William
Rowan
Hamilton,
vol.
Ill
H.
1897).
(Dublin,
1889). 5
Sir
William
Rowan
Hamilton,
Lectures
on
Quaternions
(Dublin,
1853).
All
refer-
ences are to H a m i l t o n ' s Preface, w h e r e A r a b i c n u m e r a l s set in p a r e n t h e s e s are u s e d to indicate page numbers. 6
Jean
naires
Robert
dans
contains papers
les
Essai
sur
geometriques,
a reprint of the
on
papers
Argand,
constructions
first
une
2nd
edition
maniere
ed.,
(Paris,
ed.
de J.
representer Hoiiel
les
quantites
imagi-
1874).
This
(Paris,
1806) a l o n g w i t h
selections from the
complex numbers by Frangais, Argand, Gergonne, Lacroix, and Servois,
which
were
originally
published
in
Gergonne's
Annales
des
Mathematiques,
4 ( 1 8 1 3 - 1 8 1 4 ) a n d 5 ( 1 8 1 4 - 1 8 1 5 ) . S e e t h e w o r k c i t e d i n n o t e (7) b e l o w f o r a n E n g l i s h translation series in 7
Hoiiel's
edition.
Jean
Robert
trans. A. S. 8
of Argand's
book;
Hardy
included
less
material
than
Hoiiel
from
the
o f p a p e r s i n G e r g o n n e ' s Annales b u t s u p p l i e d v a l u a b l e c o m m e n t a r y n o t f o u n d
Argand,
Imaginary
Quantities:
Their
Geometrical
Representation,
H a r d y ( N e w Y o r k , 1881).
T h e t h r e e G r e e k a u t h o r s w h o u s e d t h i s c o n c e p t are (1) t h e a u t h o r o f t h e s o - c a l l e d
"pseudo-Aristotelian
Mechanica,"
(2)
Archimedes,
and
(3)
Hero
of Alexandria.
For
13
A H i s t o r y of V e c t o r Analysis the
first
Ages
(Madison,
and
the
nique
Analytique
"On
Spirals"
third
1959),
in
see
4-5,
Marshall
41.
Lagrange,
in
The
On
CEuvres,
Works
Clagett,
The
Archimedes vol.
XI
o f Archimedes,
Science
o f Mechanics
see J o s e p h
(Paris,
trans.
Louis
1888),
Thomas
12,
in
and
Heath
the
Middle
L a g r a n g e , MecaArchimedes,
(New
York,
n.d.),
165. 9
T h e history of this concept is discussed by n u m e r o u s authors; the f o l l o w i n g are
among
the
Maddox J.
most
(New
McCormack
1962);
(4)
tischen 10
(La
A.
For
this
Salle,
Rene
(2)
111.,
Dugas,
Ernst
Mach,
1960);
(3)
"Grundlegung
vol.
example
. .
(1)
1955);
Voss,
Wissenschaften,
plane . has
important:
York,
IV, see
pt.
(1;
I
A
The
History
o f Mechanics,
Science
Max Jammer,
der
Concepts o f Force
Mechanik"
(Leipzig,
390) but note
trans.
o f Mechanics, t r a n s .
in
1901-1908),
J.
R.
Thomas
( N e w York,
Encyklopadie
der
mathema-
43-46.
that L o e m k e r wrote
"AB
b BY for one
w h e r e a s t h e U y l e n b r o e k t e x t ( s e e G r a s s m a n n , Werke, v o l . I , p t . I , 4 2 0 )
(correctly) " A Y « B Y . "
11
There
is
a
fuller
but
similar
vol. V, ed. C. I. Gerhardt (Halle,
exposition
in
Leibniz,
Mathematische
Schriften,
1858), 141-171. M a n y m i n o r statements of L e i b n i z
(for e x a m p l e , statements in letters) are referred to a n d discussed by L o u i s Couturat, La
Logique
de
Leibniz
(Paris,
ideas, particularly as discussed by A. nection
with
Grassmann
E.
Heath,
Leibniz's
in
1901),
they relate
his
which
"The
Geometrical
Characteristic"
Geometrische
Analyse
in
in
12
Louis
Couturat,
There
have b e e n a n u m b e r of studies
that have a i d e d me ruff
Beman,
American
"A
Cajori,
for
"Historical of
1912),
1924);
in
the
Leibniz
(3)
(4)
on
the
in Julian
Analysis
vol.
discussion
27
I,
of
Leibniz'
L e i b n i z ' s y s t e m was also
of Grassmann
Monist,
(Paris,
History of
(1917),
pt.
1901),
I,
a n d Its Con-
36-56,
and
by
321-399.
538.
on the early history of complex numbers
of
Mathematics"
Science,
Graphic
American
46
Monthly,
Coolidge,
Hankel,
der
The
Proceedings
33-50;
(2)
of Imaginaries 19
Geometry
Theorie
in
(1897),
Representation
Mathematical
Lowell
Hermann
full
a m o n g t h e m o s t i m p o r t a n t are (1) W o o s t e r W o o d -
the
Advancement
Note
Wessel"
167-171;
ford,
de
in this study;
Chapter
Association
Time
Logique
a
system.
The
Werke,
13
La
includes
to Grassmann's
o f the
Florian
Before
the
(September-October,
o f the
complexen
Complex
Domain
Zahlensysteme
(Ox-
(Leipzig,
1 8 6 7 ) ; (5) P . S . J o n e s , " C o m p l e x N u m b e r s : A n E x a m p l e o f R e c u r r i n g T h e m e s i n t h e Development
of
263, 340-345; of
Certain
vancement narii
Branches
o f Science
nella
and 36
Mathematics"
of
(1834),
Mathematics
317-345;
Quantities"
Analysis" 185-352;
geometria"
(1898),
Complex
in
Teacher,
47
(1954),
106-114,
257-
(6) G e o r g e P e a c o c k , " R e p o r t o n t h e R e c e n t P r o g r e s s a n d P r e s e n t State in
(7)
in
Battaglini's
(8)
G.
in
Mathematical
of
the
British
Romorino,
Giornale
Windred,
Unfortunately a recent excellent
Report
Angelo
di
Association
"Gli
matematica,
for
the
Elementi
35
(1897),
Ad-
imagi-
242-258;
" H i s t o r y of the T h e o r y of Imaginary and
Gazette,
14
study came
(1929),
533-541.
to my attention too late to take full
a d v a n t a g e o f it. T h i s i s F . D . K r a m a r ' s " V e k t o r n o e i s c h i s l e n i e k o n t s a X V I I I i n a c h a l a XIX
vv"
14
The
matics, e d . 15
be
(in
Russian)
important David
in
passage
Eugene
lstoriko-Matematicheskie
from
Smith,
Wallis
vol.
I
may
Issledovaniia,
be
found
( N e w York,
in
15 A
(1963), Source
Book
225-290. in
Mathe-
1959), 4 6 - 5 4 .
T h e w o r d s " t o p u b l i s h " qualify this statement sufficiently that no m e n t i o n n e e d
made
in
the
text
of Leonard Euler, Charles Walmesley, and Dominique Truel.
T h e basis for attributing the geometrical representation to the first t w o of these m e n is
that it seems f r o m reading their writings on relevant subjects that they probably
had
this
representation.
The
sole
basis
for
mentioning
C a u c h y that T r u e l had this representation as early as Florian Cajori, fore
14
Wessel"
"Historical in
American
Notes on the Mathematical
Truel
is
a
statement
by
1786. F o r f u l l e r discussion see
G r a p h i c Representation of Imaginaries be-
Monthly,
19
(1912),
167-171.
T h e Earliest Traditions 16
Some
of these
difficulties
H a m i l t o n ' s efforts to 17
ische
gelehrte
Friedrich l
will
be
discussed
more
fully
in
Chapter
II, where
a t h r e e - d i m e n s i o n a l vectorial system are treated.
Gauss' untitled publication, w h i c h was a discussion of his " T h e o r i a r e s i d u o r u m
biquadraticum,
Commentatio
Anzeigen
of A p r i l
G a u s s , Werke,
»Ibid.,
19
find
secunda," 23,
vol.
II
1831.
was I
originally
have
(Gottingen,
used
1863),
published
the
text
in
as
the
given
Gotting-
in
Carl
169-178.
175.
Julian
Lowell
Coolidge,
The
Geometry
o f the
Complex
Domain
(Oxford,
1924),
28-29. 20
Hermann
Werke, v o l . 21
Felix
matische
Klein,
o f Edinburgh,
this in
Abbe
Royal
of
24
Coolidge,
25
This
is
VIII
96
Geometry
X,
sur
les
(1806), of
the
implied
Philosophical that
2
see
is
especially
(5;
in
on
the
Gilston
Proceedings
which
Mathe-
Recently
i n Proceedings
Knott,
o f the
Klein
in
Claim
"Pro-
Royal
Society
his
claim,
based
357-362. "Uber
Gauss
(Gottingen,
quantites
Arbeiten
zur
Function-
1922-1933), 55-57.
imaginaires"
the
Domain,
fact
in
Transactions
of
the
24.
that
3rd
in
an
Ser.,
had influenced him;
in
" O n
23-88.
Magazine,
implied
physikalische
Gauss' W e r k e n "
Cargill
criticism"
Complex by
von Tait,
17-23;
1900),
pt.
und
Discovery) of Quaternions"
Schlesinger,
representation of complex
same conclusion Quaternions;
the
(Leipzig,
Ludwig
discussed the authors geometrical
For
"Memoire
in
the
(1900),
document
London,
Quaternions"
Guthrie
24-34.
see
strongly
(not
23
G a u s s , Werke, v o l .
Buee,
Society
Invention
Herausgabe
Peter
a
vol.
point
der
mathematische
397-398.
of Q u a t e r n i o n s :
(1900),
G a u s s , Werke, On
the
Stand
128-133;
o f Edinburgh,
View
23
entheorie" 23
to
Gesammelte
1896), 8 - 9 ,
den
(1898),
Society
Klein's
Grassmann,
(Leipzig,
"Uber
51
Royal
fessor
2 2
II
for Gauss
the
see
pt.
Annalen,
Made of
Giinther
I,
1844
25
paper
(1844),
[31]—[57])
richly historical
as
"On
Hamilton
o f t h e six m e n w h o d i s c o v e r e d t h e
numbers, only Warren was
Hamilton's
(Hamilton,
489-495)
well
as
the
mentioned.
The
p r e f a c e t o h i s Lectures o n work
listed
in
note
(4)
above, w h e r e i n m a n y letters f r o m H a m i l t o n t o D e M o r g a n w e r e p u b l i s h e d i n w h i c h Hamilton
discussed these men.
p a p e r (4; 3 1 2 ) , (2) paper Rowan
(5;
[57]),
Hamilton,
and
vol.
H a m i l t o n e x p l i c i t l y d e n i e d h a v i n g s e e n (1) G a u s s '
M o u r e y ' s b o o k (4; 4 8 9 ) , (3) A r g a n d ' s b o o k (4; 4 3 5 ) , (4) S e r v o i s '
II
(5)
Frangais'
[Dublin,
papers
1885],
(Robert
606).
Perceval
From
the
Graves,
fact
that
Life o f Sir William
Hamilton
had not
read Servois' and Frangais' papers or Argand's book, it seems reasonable to conclude that he had Annales
not read any of the
before
1844.
Hamilton
relevant papers did
not
in
explicitly
volumes IV and V of Gergonne's
deny knowledge
of Wessel,
since
h e never, e v e n after 1843, h e a r d o f W e s s e l , a n d h e d i d not e x p l i c i t l y d e n y k n o w l e d g e of Buee's hand,
paper,
Hamilton
since
he
had already d e n i e d that
attended
the
vancement of Science, and on
the
Recent
(.B.A.A.S.
Report,
Argand's 26
See
Roots
Progress
and
John
o f Negative
the
in
Present
which
papers
Warren, Quantities
it had any merit.
meeting of the
A
from
Treatise
State
Peacock
of
on
the
1828),
Certain
briefly
Gergonne's
(Cambridge,
addition, page 9 for c o m m u t a t i v e
Branches
extent
on
"associative,"
probably
the
the
recognition
first
the
other
discussed
of
(ibid.y
"Report
Analysis" page
228)
Annales.
Geometrical page
Representation
3
for
of
the
commutative
law for multiplication, page
was aware of the associative l a w for m u l t i p l i c a t i o n , a n d page law. T h e importance of this
names
On
British Association for the Ad-
at this m e e t i n g George Peacock presented his and
185-352),
book
1833
Square law
of
18 for a hint that he
13 for the distributive
is that the discovery of quaternions d e p e n d e d to some of the
importance
"commutative,"
historical
and
statement
of these
laws.
"distributive"
was
made
by
in
On a
origin
of the
mathematical
sense
Hermann
the
Hankel,
Theorie
der
15
A H i s t o r y of V e c t o r Analysis complexen
Zahlensysteme
"These have
names
(Leipzig,
have
been
1867),
adopted
footnote
on
universally in
page
3,
not hesitated to transplant t h e m to G e r m a n soil;
was
it
seems
first
i n t r o d u c e d by Sir. W.
R.
he
said,
1840 and hence I
'distributive' and 'commuta-
tive' w e r e introduced by Servois ( G E R G O N N E ' S Ann. vol. V. tive'
where
E n g l a n d since
1814, p . 93); 'associa-
H a m i l t o n . " T h i s statement is re-
peated by both D a v i d E u g e n e S m i t h and Florian Cajori. T h e earliest recognition of the
necessity of proving the commutative
VII, Proposition the term
"associative" is
Connected with lished
in
the
"However, in
l a w for m u l t i p l i c a t i o n is in
Euclid, Book
16. T h e first p u b l i c a t i o n , t o m y k n o w l e d g e , i n w h i c h H a m i l t o n u s e d in the paper " O n a N e w Species of Imaginary Quantities,
a T h e o r y o f Q u a t e r n i o n , " c o m m u n i c a t e d N o v e m b e r 13, 1843, p u b Proceedings
of
the
Royal
Irish
Academy,
2
(1844)
424-434.
He
wrote:
virtue of the same definitions, it w i l l be f o u n d that another important
property of the o l d m u l t i p l i c a t i o n is preserved, or e x t e n d e d to the n e w , namely, that which 27
may
be
called
the
associative
character of t h e
operation.
.
.
."
Ibid., 4 2 9 - 4 3 0 .
At least no extension is suggested in his b o o k or in the t w o s u b s e q u e n t papers
w h i c h he p u b l i s h e d on this subject. Philosophical entitled
Transactions
of
"Considerations
sentation of the Square Geometrical Square
the
H i s t w o later papers w e r e b o t h p u b l i s h e d in the
Royal
of the Roots
Society
Objections
of
London,
119
(1829);
they
were
Raised Against the Geometrical Repre-
of Negative Quantities," pages 2 4 1 - 2 5 4 , and " O n the
Representation of the Power of Quantities Whose Indicies Involve the
Roots
of
251-254) Warren
Negative
Quantities,"
stated that he
pages
had written
339-359.
In
the
first
paper
(ibid.,
his book before he heard of Buee's or
M o u r e y ' s p u b l i c a t i o n ; A r g a n d was not m e n t i o n e d , p r e s u m a b l y because W a r r e n still had not heard of Argand's 28
C.
dues
V.
Mourey,
imaginaires
reprint Buee; have
of his
(Paris, 1828
book.
La 1828).
work.
vrai
Theorie
The
second
Nowhere
des
in
quantites
edition the
work
negatives
et
book
since
quantites
preten-
1861) was used; this was a
does
Mourey mention Argand or
i n fact n o m a t h e m a t i c i a n s are ever m e n t i o n e d i n the book. k n o w n Warren's
des
(Paris,
it was p u b l i s h e d after his o w n .
Mourey could not M o u r e y [ibid., I X )
m a d e the interesting c o m m e n t that his b o o k was an a b r i d g e m e n t of a longer treatise he had written but had not published. 29
16
Ibid.,
95.
CHAPTER
Sir
William
Rowan and
I.
Introduction: The
task
of the
Hamiltonian historian
w o r k of Sir W i l l i a m R o w a n estimates
of his
extreme
dinger
of Hamilton:
While
these
Hamilton Quaternions
Historiography
who
wishes
to
treat any
aspect of the
H a m i l t o n is c o m p l i c a t e d by the fact that
significance for the history of science have varied
between two wrote
TWO
positions.
discoveries
Thus,
(Quaternions,
for example,
etc.)
would
Erwin
suffice
to
Schro-
secure
H a m i l t o n in the annals of both mathematics a n d physics a h i g h l y hono u r a b l e place, s u c h p i o u s m e m o r i a l s can i n his case e a s i l y b e d i s p e n s e d with. For H a m i l t o n is virtually not dead, he h i m s e l f is alive, so to speak, not his m e m o r y . I daresay n o t a d a y passes — a n d s e l d o m an h o u r — w i t h out somebody,
somewhere
writing or printing
on
Hamilton's
this
globe,
name.
pronouncing or reading
or
T h a t is due to his f u n d a m e n t a l
d i s c o v e r i e s i n g e n e r a l d y n a m i c s . T h e H a m i l t o n i a n p r i n c i p l e has b e c o m e the cornerstone of m o d e r n physics, t h e t h i n g w i t h w h i c h a p h y s i c i s t exp e c t s every p h y s i c a l p h e n o m e n o n t o b e i n c o n f o r m i t y . . . . T h e modern development of physics is continually enhancing Hamilton's name. H i s famous analogy b e t w e e n mechanics a n d optics v i r t u a l l y anticipated wave-mechanics,
which
did
not
have to add m u c h to his
ideas, o n l y h a d to take t h e m seriously —a little m o r e seriously t h a n he was
able to take t h e m , w i t h the experimental k n o w l e d g e of a century
ago.
The
central conception of all
modern theory in physics
is
"the
Hamiltonian." If you wish to apply modern theory to any particular probl e m , y o u m u s t start w i t h p u t t i n g t h e p r o b l e m " i n H a m i l t o n i a n f o r m . " T h u s H a m i l t o n i s o n e o f t h e greatest m e n o f s c i e n c e t h e w o r l d has p r o duced.6 In
*
1945 J.
into eclipse.7 above
all
variations.
L.
Synge lamented that Hamilton's fame was passing
Synge cited m a n y aspects of this eclipse b u t stressed
the neglect of Hamilton's contribution to the calculus of He wrote:
" H a m i l t o n was, in fact, a great c o n t r i b u t o r —
probably the greatest single contributor of all t i m e —to the calculus of variations."
(7;
15)
17
A H i s t o r y of V e c t o r Analysis
In
1940 E. T. Whittaker p u b l i s h e d a paper entitled " T h e H a m i l -
tonian ton's
Revival,"
8
reputation
century: verse
in
which
was
he maintained:
touched
about
the
since w h e n , t h e r e has b e e n a steady m o v e m e n t in t h e re-
direction:
one
after
another,
the
i n n o v a t i o n s has b e e n a p p r e c i a t e d . . . ton in
" T h e nadir of Hamil-
beginning of the present
1954:
significance 9
."
of his
" A f t e r Isaac N e w t o n , t h e greatest m a t h e m a t i c i a n of the
E n g l i s h - s p e a k i n g p e o p l e s is W i l l i a m R o w a n H a m i l t o n . . . ." In
1937
titled
great
W h i t t a k e r w r o t e of H a m i l -
E.
T.
Bell
in
his
widely
the
chapter on
Hamilton
presented
Hamilton's
life
as
"An
read
Men
Irish
a tragedy,
o f Mathematics
Tragedy."
10 11
Herein
enBell
in a sense a m a g n i f i c e n t
failure. This
disparity o f v i e w s c o n c e r n i n g H a m i l t o n , w h i c h i n fact dates
back to the nineteenth century, is central to Hamiltonian historiography. T h e m a i n source of this disparity of v i e w s relates to H a m i l ton's
work
on
quaternions.
represented
the
voted
more
than
twenty
quaternions
held
by
Hamilton
mathematics
of the
years
nearly
of his
all
believed
future
and
life
to
that
them.
mathematicians
quaternions
consequently The
of the
de-
view
of
present is
h o w e v e r quite different; the consensus n o w is that the quaternion system
is b u t one of m a n y comparable mathematical systems, and
though value
it for
is
i n t e r e s t i n g as a rather special
application.
system, it offers
little
T h e historian of today must take the above
e v a l u a t i o n of q u a t e r n i o n s as m o s t p r o b a b l y v a l i d , t h o u g h t h e r e remain
sources
of doubt.
Statements qualifying or contradicting this
evaluation — m a d e by such important scientists as E. T. Whittaker,12 George D. Birkhoff,13 and P. A. M. Dirac
14
caution
large
in the
historian,
as
do
the
two
— instill some degree of volumes by Otto F.
Fischer,15 in w h i c h the author attempted to rewrite m u c h of m o d e r n physics
in terms of Hamilton's quaternions.
E. T. Bell's v i e w of H a m i l t o n as a tragic failure certainly s t e m m e d from
the
modern victim
fact that he
felt that
mathematics. of
a
Bell
monomaniacal
deepest tragedy was
quaternions
was
are of little interest to
convinced that
delusion;
he
Hamilton was the
stated
"that
Hamilton's
neither alcohol nor marriage but his obstinate
belief that quaternions h e l d the key to the mathematics of the physical
universe."
much taker
16
of what E. however
The
passed
contributions to
problem
of quaternions
T. Whittaker wrote over
the
mathematical
also stands b e h i n d
concerning Hamilton; Whit-
problem
by
stressing
Hamilton's
physics and by arguing that quater-
nions " m a y even yet prove to be the most natural expression of the n e w physics."
17
T h e present study m u s t stand in the shadow of this dispute con-
18
Sir W i l l i a m R o w a n H a m i l t o n
and Quaternions
cerning Hamilton's greatness; nevertheless it is h o p e d that substantial
progress
toward
following analysis, not possible
to
a
solution
which
argue
may
be
achieved
in
terms
of the
w i l l be d e v e l o p e d m o r e f u l l y later.
that the
quaternion
system
is
the
It is
vectorial
system of the present day; the so-called Gibbs-Heaviside system is the
only system that merits
this distinction.
N o r is it legitimate to
a r g u e (as W h i t t a k e r h a s d o n e ) t h a t t h e q u a t e r n i o n s y s t e m w i l l b e t h e system of a future day.
B o t h of these alternatives are unacceptable;
nonetheless
argued
it
can
be
(though
previously been done) that Hamilton's historically
determinable
path to the
hence to the m o d e r n system.
in
my opinion
this
has
not
quaternion system led by an Gibbs-Heaviside
system
and
In what follows it w i l l be s h o w n that
this was in fact t h e case, a n d thus it w i l l b e c o m e clear that H a m i l ton deserves i m m e n s e credit for his w o r k in quaternions, since this work
led
reasons
to
the
now
w h y this
is
widely
so
used
system
little k n o w n
will
of vector analysis.
also be
discussed.
The
If this
analysis is f o u n d acceptable, it s h o u l d clear up the major p r o b l e m in Hamiltonian
historiography.
II.
s
Hamilton Though
in
Life
and
Fame
general a detailed discussion of a scientist's life n e e d
not be i n c l u d e d in a study such in
regard to
the
fame
Hamilton
attained
and
by
Hamilton
fluenced subsequent events. Hamilton's the
title
The the
during
Some
his
lifetime
indication
of the
strongly
in-
importance of
fame in this history may be attained by a comparison of
pages
title
as this, it is of necessity otherwise
quaternions. T h e reason for this is that
of Hamilton's
page
of
and
Grassmann's
Grassmann's Ausdehnungslehre
first of
major
1844
works.
contained
following: Hermann
Grassmann
Lehrer an der Friedrich-Wilhelms-Schule zu Stettin By
contrast,
the
title
page
of
Hamilton's
Lectures
on
Quaternions
contained: SIR W I L L I A M R O W A N H A M I L T O N , L L . D . , M . R . I . A., F E L L O W OF THE AMERICAN
SOCIETY O F ARTS A N D SCIENCES; O F T H E
SOCIETY
FOR
OF
ARTS
SCOTLAND;
NOMICAL SOCIETY OF LONDON; ERN
SOCIETY
SPONDING
OF
ANTIQUARIES
MEMBER
OF
T H E
HONORARY OR CORRESPONDING OR
ROYAL ACADEMIES
TURIN; LIN;
OF
OF THE THE
OF
ST.
OF
T H E
AND OF T H E AT
ROYAL
ASTRO-
ROYAL NORTH-
COPENHAGEN;
INSTITUTE
OF
CORREFRANCE;
M E M B E R OF T H E IMPERIAL
PETERSBURGH,
BERLIN, AND
ROYAL SOCIETIES OF EDINBURGH A N D DUBCAMBRIDGE
PHILOSOPHICAL
SOCIETY;
T H E
19
A
History
of V e c t o r Analysis
N E W YORK HISTORICAL SOCIETY; T H E SCIENCES CIETIES
AT
IN
LAUSANNE;
BRITISH
A N D
AND
OF
FOREIGN
PROFESSOR OF ASTRONOMY IN T H E AND
ROYAL
William
ASTRONOMER
Rowan
Hamilton
OF
was
was
o r p h a n e d at age
SCIENTIFIC
COUNTRIES;
SO-
ANDREWS'
UNIVERSITY OF DUBLIN;
IRELAND.
born of undistinguished ancestry
on the midnight between August 3 and 4, He
SOCIETY OF NATURAL
OTHER
fourteen,
1805, in D u b l i n , Ireland.
b u t h a d ceased to live w i t h his
parents f r o m the age of three, at w h i c h t i m e he h a d b e e n sent to live with
his
Trim,
uncle,
Ireland.
James
Hamilton,
Hamilton's
uncle,
an a
Anglican
man
clergyman
of education
serving
and
intelli-
gence, d i r e c t e d his n e p h e w ' s p r e u n i v e r s i t y education. T h e success of the uncle as tutor and the brilliance of Hamilton as student were manifested in thirteen, teen
many ways,
Hamilton
"was
languages. . . ."
brew,
Syriac,
French,
Italian,
however
only
18
of w h i c h
in
These
Persian,
the
best k n o w n
is that at age
different degrees acquainted w i t h thirlanguages
Arabic,
were
Sanskrit,
Greek,
Latin,
Hindoostanee,
He-
Malay,
Spanish, and German. T h e study of languages was one
of
Hamilton's
interests,
for
he
also
read
in
geography, religion, mathematics, astronomy, and the best of English
and
foreign
Mecanique but
not
was
in
forces. In
Celeste
literature.
and
significant Laplace's (2,1;
1823
At
detected for this
age
an
sixteen
error
study that the
demonstration
he
began
therein.
It
is
Laplace's interesting
error found by Hamilton
of the law of the parallelogram of
661-662)
Hamilton
entered Trinity College of D u b l i n University.
He h a d placed first in the entrance exam a n d h a d decided that his calling was to science. incredible.
In
knowledge
of Greek,
knowledge optime
was
"became vitations, .
His record at the University bordered on the
second
rare.
celebrity
in
Upon in
the
embarrassing
him.
.
year
the
This
wish
year
Hamilton
was
third
physics.
an
optime
for
another
optime
for his
his
T h e w i n n i n g of even a single
winning
the
intellectual their
awarded year
second
circle
optime,
Hamilton
of Dublin;
number,
poured
and in
in-
upon
. " (2,1; 2 0 9 ) H a m i l t o n r e s o l v e d t o a t t e m p t t o w i n i n h i s f i n a l University was
mer of Ireland. creative
honors
he
his
from
Gold
for
Medals
not fulfilled, was
offered
fessor of A s t r o n o m y at the
in
year
and
of mathematical very
a
his
for the
in
both
classics
during the
and in
science.
s u m m e r after his third
honor of becoming Andrews'
Pro-
University of D u b l i n and Royal Astrono-
H i s s t u d e n t days w e r e also d i s t i n g u i s h e d b y success
endeavors. some
of
He
them.
wrote
numerous
Researches
in
poems science
and
received
begun
in
his
seventeenth year on certain questions in mathematical optics led to
20
Sir W i l l i a m R o w a n H a m i l t o n
his
now famous
1824
and
"Theory
published
of Systems
with
Other important papers
of Rays,"
which
further developments
in
the
same
line
and Quaternions
was
read
four years
in
later.19
of development came in
1830,
1831, a n d 1837. H i s a i m in these papers ( w h i c h e x t e n d to over
three
hundred
science his
in
pages)
terms
mathematical
methods
for
was
of his
methods
use
in
to
reduce
optics
"Characteristic in
optics
dynamics.
to
a
Function."
led
The
Hamilton
mathematical
The
success
of
to extend these
distinguished
historian
of
m e c h a n i c s R e n e D u g a s has s u m m a r i z e d the nature a n d i m p o r t a n c e of Hamilton's
work in
I n short, jealous
optics
and
dynamics:
of the formal perfection w h i c h Lagrange had been
able to give to dynamics, and w h i c h optics lacked, H a m i l t o n undertook the rationalisation of geometrical optics.
He
d i d this by d e v e l o p i n g a
formal theory w h i c h was free of all metaphysics a n d w h i c h , moreover, s u c c e e d e d in a c c o u n t i n g for a l l t h e e x p e r i m e n t a l facts. . . . Then,
returning to
dynamics,
Hamilton presented the
l a w o f varying
action i n a f o r m v e r y l i k e t h a t w h i c h h e h a d d i s c o v e r e d i n o p t i c s . T h u s h e r e d u c e d t h e g e n e r a l p r o b l e m o f d y n a m i c s (for c o n s e r v a t i v e systems) to the solution of t w o simultaneous equations in partial derivatives, or to the determination of a single function satisfying these t w o equations.
Hamilton's
g u i d i n g idea is continuous f r o m his optical w o r k to his
w o r k in d y n a m i c s — i n this fact lies his greatness a n d his p o w e r .
Here
was a synthesis that L o u i s de Broglie was to rediscover a n d t u r n to his o w n account; a synthesis that was, it appears, to be Schrodinger's direct inspiration.20 These
works
certainly
contributed
to
was probably thinking of them w h e n in
Hamilton's
fame;
Jacobi
1842 he referred to H a m i l -
t o n a s " l e L a g r a n g e d e v o t r e p a y s . " (2,111; 5 0 9 ) O f t e n h o w e v e r s u c h highly
mathematical
otherwise
for
basis
new
two
refraction. colleague In
this
At
phenomena
of Hamilton,
he
was and
wrote
siderable
vigorous
and
"perhaps made.
.
the .
most
popular fame.
predicted
on
It was
a theoretical
Humphrey
men
Whewell's
and
Airy
remarkable
friend
in
prediction
predicted (2,1;
635)
a very con-
England and on the
praise
referred
both
time
and
prediction.
predicted.
"excited at the
scientific
636)
finding
had not been
discovery
Lloyd,
to verify Hamilton's
successful,
which
immediate,
he
in optics, internal and external conical
among
(2,1;
21
request,
attempted
third
sensation
not produce
1832
completely a
that this
Continent. . . ."
do
in
Hamilton's
phenomena Graves
papers
Hamilton;
for
to
Hamilton
the
that
was
discovery
has
ever
as
been
. " (2,1; 6 3 7 ) D e M o r g a n w r i t i n g i n 1 8 6 6 s t a t e d : " O p t i c i a n s
had no more i m a g i n e d the possibility of such a thing, than astronomers
had
imagined
the
planet
Neptune,
which
Leverrier
and
21
A
History
of V e c t o r Analysis
A d a m s calculated into existence. t o g e t h e r as,
perhaps,
predictions." No
2 2
the
Pliicker of Bonn
experiment
These two things deserve to rank
t w o most remarkable of verified scientific
i n p h y s i c s has
wrote:
made
such a strong impression on my
m i n d as that of conical refraction. A single ray of light e n t e r i n g a crystal and leaving as a l u m i n o u s cone: this is something unheard of and without
analogy.
wave
Mr.
H a m i l t o n p r e d i c t e d it, starting f r o m the f o r m of the
w h i c h h a d b e e n d e d u c e d b y a l o n g calculation f r o m a n abstract
theory. I confess I w o u l d have h a d little hope of seeing an experimental confirmation theory
of such
which
an
extraordinary
Fresnel's
genius
had
result,
recently
predicted by the created.
But
mere
since
Mr.
L l o y d h a d d e m o n s t r a t e d that the e x p e r i m e n t a l results w e r e i n c o m p l e t e accordance w i t h the predictions of M r . H a m i l t o n , all prejudice against a t h e o r y s o m a r v e l o u s l y l o f t y has b e e n f o r c e d t o d i s a p p e a r . (2,1; 6 3 7 ) T h e fame that came to
Hamilton because
of this
discovery was in-
creased by the fact that it w a s m a d e , l i k e nearly all the discoveries d i s c u s s e d t h u s far, b e f o r e Also was
his
literary
close figures
friendship such as
ridge.
Numerous
worth,
and
had up
H a m i l t o n h a d r e a c h e d his t h i r t i e t h year.
illustrative of, a n d c o n t r i b u t o r y to, H a m i l t o n ' s p o p u l a r fame with
William
Wordsworth
and
other
Maria Edgeworth and Samuel Taylor Cole-
letters
passed
between
Hamilton
and
Words-
each visited the other on m a n y occasions. W o r d s w o r t h
said that H a m i l t o n was one of t w o m e n to w h o m he could look (the
other was Coleridge). To this H a m i l t o n replied:
" I f I am to
look d o w n on you, it is only as L o r d Rosse looks d o w n in his teles c o p e to see t h e stars of h e a v e n r e f l e c t e d . " By
1835
Hamilton's
fame
was
(2,111; 2 3 7 )
established.
In
that year he
was
knighted and received a medal from the Royal Society; in addition he
finished
ton's In
a paper on algebraic couples, w h i c h is the first of Hamil-
publications to be of direct importance for the present study.
1837
h e l d this covery
he
was
elected president of the Royal
position
(1843)
until
1843 to
ment
of quaternions. of
resignation
of quaternions.
from
Honors
his
The
received
Sciences along
Irish Academy and
1845, soon after his dis-
last t w e n t y - t w o years
of his life,
1865, w e r e for the most part devoted to the develop-
all
sorts
continued
these deserves final mention. In ton
in
notice
that the
to
be
bestowed
on
him.
One
of
1865, the year of his death, H a m i l -
newly
founded
National
Academy of
of t h e U n i t e d States h a d e l e c t e d h i m a F o r e i g n Associate,
with
Hamilton's
fourteen
other men.
The
name at the head of the
members
had voted to
place
list of F o r e i g n Associates, pre-
s u m a b l y signifying that in their o p i n i o n he was the greatest living scientist.
In
this
j u d g m e n t does
22
they were
attest to the
probably overly enthusiastic, but their fact,
which
is
very significant for this
Sir W i l l i a m
study,
that
great.
Hamilton's
fame
Rowan
among
Hamilton
his
and Quaternions
contemporaries
had b e e n completed, b u t he was still nearly u n k n o w n . in
was
very
At this same time the majority of Grassmann's scientific w o r k
his
1862
Ausdehnungslehre
now "Professor am
III.
Hamilton
It was
had
Gymnasium
and
Complex
changed zu
only
His subtitle
slightly;
it
was
Stettin."
Numbers
stated previously that H a m i l t o n ' s
was in the tradition of the work done on
discovery of quaternions complex numbers, and in
this regard the history of the geometrical representation of c o m p l e x numbers
and associated ideas
was
given.
But there
was
a second
line of d e v e l o p m e n t in studies on c o m p l e x n u m b e r s that also l e d to quaternions. This line of development was established by H a m i l t o n himself in his titled:
l o n g a n d i m p o r t a n t essay p u b l i s h e d in
1837 and en-
"Theory of Conjugate Functions, or Algebraic Couples; with
a Preliminary Pure Time."
and Elementary Essay on Algebra as the This
paper is
important
in
itself;
Science of
indeed one mathe-
matician referred to it as a greater c o n t r i b u t i o n to algebra than his of quaternions.23
discovery sections:
Hamilton's
paper is divided into three
the first section, w h i c h consists of " G e n e r a l Introductory
Remarks,"
was
written
last;
the
second
section,
an
essay
" O n
Algebra as the Science of Pure T i m e " was w r i t t e n in 1835; a n d the third or
section,
Algebraic
(2,11;
containing Couples,"
his
was
"Theory for
the
of
most
Conjugate part
Functions,
written
in
1833.
144) N e g l e c t of t h e historical s e q u e n c e of t h e c o m p o s i t i o n has
led to
a n u m b e r of historical
Hamilton
began
the
misconceptions.
paper by
writing:
T h e study of Algebra may be p u r s u e d in three very different schools, the Practical, the Philological, or the Theoretical, according as A l g e b r a itself is a c c o u n t e d an I n s t r u m e n t , or a L a n g u a g e , or a C o n t e m p l a t i o n ; according
as
ease
thought,
(the
of operation, agere,
or
the f a r i ,
s y m m e t r y of expression, or
the
sapere,)
is
or clearness
eminently
prized
of
and
sought for. T h e Practical p e r s o n seeks a R u l e w h i c h he m a y a p p l y , t h e P h i l o l o g i c a l person seeks a F o r m u l a w h i c h he m a y w r i t e , the T h e o r e t i c a l p e r s o n seeks a T h e o r e m o n w h i c h h e m a y m e d i t a t e . (3; 2 9 3 ) He then proceeded to
state that t h e a i m o f this p a p e r w a s theoreti-
cal. The
thing
aimed
at,
is
to
improve
the
Science,
not
the
Art
nor
the
L a n g u a g e o f A l g e b r a . T h e i m p e r f e c t i o n s s o u g h t t o b e r e m o v e d , are confusions of t h o u g h t , a n d obscurities or errors of reasoning; riot difficulties of application of an instrument nor failures of symmetry in expression.... F o r i t has n o t f a r e d w i t h t h e p r i n c i p l e s o f A l g e b r a a s w i t h t h e p r i n ciples
of Geometry.
No
candid
and
intelligent
person can
doubt the
23
A H i s t o r y of V e c t o r Analysis truth
of the
chief properties
o f Parallel
Lines,
as
set f o r t h
by E U C L I D
i n his E l e m e n t s , t w o t h o u s a n d years ago; t h o u g h h e m a y w e l l desire t o see t h e m t r e a t e d i n a c l e a r e r a n d b e t t e r m e t h o d . T h e d o c t r i n e i n v o l v e s no
obscurity
nor
confusion
of
thought,
and
leaves
in
the
mind
no
reasonable g r o u n d for d o u b t , a l t h o u g h i n g e n u i t y m a y usefully be exercised in improving the plan of the argument. But it requires no peculiar scepticism to doubt, or even to disbelieve, the doctrine of Negatives and I m a g i n a r i e s , w h e n s e t f o r t h (as i t h a s c o m m o n l y b e e n ) w i t h p r i n c i p l e s like
these:
that
the
numbers plied t h e
that
a
remainder denoting one
greater is
magnitude
less
than
magnitudes
by the
other,
may
be
nothing;
each
less
subtracted from that
two
than
a
negative
nothing,
less,
and
numbers, o r
may be
multi-
a n d t h a t t h e p r o d u c t w i l l b e a positive n u m -
ber, or a n u m b e r d e n o t i n g a m a g n i t u d e greater than nothing; and that a l t h o u g h t h e square o f a n u m b e r , o r t h e p r o d u c t o b t a i n e d b y m u l t i p l y i n g that be
number
by
itself,
is
therefore
always positive,
whether the
number
p o s i t i v e o r n e g a t i v e , y e t t h a t n u m b e r s , c a l l e d imaginary, c a n b e f o u n d
or conceived or d e t e r m i n e d , a n d operated on by all the rules of positive and
negative
they
have
selves
numbers,
negative
squares,
as
i f t h e y w e r e s u b j e c t t o t h o s e r u l e s , although
and
must
therefore
be
s u p p o s e d to
be t h e m -
neither positive or negative, nor yet n u l l numbers, so that the
m a g n i t u d e s w h i c h t h e y are s u p p o s e d t o d e n o t e can n e i t h e r b e greater t h a n n o t h i n g , n o r less t h a n n o t h i n g , n o r e v e n e q u a l t o n o t h i n g . I t m u s t b e h a r d t o f o u n d a S C I E N C E o n s u c h g r o u n d s a s t h e s e . . . . (3; 294)
Hamilton
then
asked
w h e t h e r e x i s t i n g A l g e b r a , i n t h e state t o w h i c h i t has b e e n a l r e a d y u n f o l d e d b y t h e m a s t e r s o f its r u l e s a n d o f its l a n g u a g e , offers i n d e e d n o rudiment which Algebra:
a
may encourage
Science
a hope
properly so called;
of developing a S C I E N C E of strict, pure, a n d i n d e p e n d e n t ;
d e d u c e d b y v a l i d r e a s o n i n g s f r o m its o w n i n t u i t i v e p r i n c i p l e s ; a n d t h u s n o t less a n o b j e c t o f p r i o r i c o n t e m p l a t i o n t h a n G e o m e t r y , n o r less d i s t i n c t , i n its o w n e s s e n c e , f r o m t h e R u l e s w h i c h i t m a y t e a c h o r use, a n d f r o m t h e S i g n s b y w h i c h i t m a y express its m e a n i n g . (3; 2 9 5 ) Hamilton
concluded
ment"
295) a n d elaborated on this idea by writing:
(3;
The folded is
argument into
an
possible,
for
"that
the
chiefly
Intuition
conclusion
independent
rests
the
Pure on
that
the
or
that
Science,
the
of T I M E
existence
notion a
is
such
o f time
Science
of certain
a rudi-
may
be
of Pure
priori
unTime
intuitions,
c o n n e c t e d w i t h that n o t i o n of t i m e , a n d fitted to b e c o m e the sources of a pure Science; and on the actual deduction of such a Science from those p r i n c i p l e s , w h i c h t h e a u t h o r c o n c e i v e s t h a t h e has b e g u n . (3; 2 9 6 - 2 9 7 ) In velop
the
second
the
real
section
of this
number system
concept of time.
paper
on
the
Hamilton attempted to basis
of the
intuition
de-
of the
In this w a y he b e l i e v e d he c o u l d justify the use of
negative n u m b e r s as c o r r e s p o n d i n g to steps in time. It
is
derived
24
generally from
Kant.
believed Such
that
Hamilton's
stress
on
m a y n o t b e t h e case, for Kant's
time
was
name is
Sir W i l l i a m R o w a n
never
mentioned
these
ideas
he
did
Pure
in
mention
Reason
the
paper.
Preface
Kant
(4;
In
to
and
"encouraged
v i e w . . . ." after
in
the
Hamilton's
his
Lectures
wrote
[him]
that
to
[2]) As early as
mentioning geometry:
nected made
became
with by
other."
Hamilton
reading
K a n t four
in
years
Hamilton wrote:
later
exposition
Quaternions
reading
(4;
Kant's
and
of
[2]-[3]) Critique
publish
of this
1827 H a m i l t o n wrote, i m m e d i a t e l y
"The
intimately
each
on
entertain
sciences
adopt here a v i e w of Algebra w h i c h propose)
Hamilton and Quaternions
I
of Space
have
intertwined
(2,1;
229)
letters
it
From
seems
after m a k i n g t h e
and Time
(to
elsewhere v e n t u r e d to and
indissolubly
con-
a n u m b e r of statements
quite
clear that
he
statement.24
above
began
In
1835
"and my o w n convictions, mathematical and meta-
physical, have b e e n so long and so strongly converging to this point (confirmed I
cannot
no
doubt
easily
of late by the
yield
to
the
stare at my strange t h e o r y . "
study of Kant's
authority (2,11;
142)
of those It thus
Pure Reason),
other
friends
seems
that who
that at most
K a n t served as a catalyst for the d e v e l o p m e n t of his ideas a n d as a confirmation
of them.
In the third part of the Conjugate
of his essay is part
is
essay H a m i l t o n p r e s e n t e d his " T h e o r y o f
Functions, or Algebraic Couples." W h i l e the second part generally considered of minor importance, the third
universally
admitted
to
be
of great importance,
for herein
H a m i l t o n d e v e l o p e d c o m p l e x n u m b e r s in terms of ordered pairs of real numbers in almost exactly the same w a y as it is done in m o d e r n mathematics.25 T h e stress
in this section was not on time, although
the interpretation of the couples in terms of time was given. Hamilton
at no point in the paper mentioned Warren or the geometrical
interpretation of complex n u m b e r s ; f r o m this it seems probable that H a m i l t o n believed (like Gauss) that the geometrical representation was
an aid to
intuition,
b u t not a satisfactory justification for com-
plex numbers. Essentially w h a t H a m i l t o n d i d in this section was to set u p o r d e r e d pairs o f r e a l n u m b e r s (a, b ) a n d d e f i n e o p e r a t i o n s o n them.
T h e s e operations w e r e all
numbers.
He
equivalent to In the and
then
complex
THEORY
denotes
showed
an
OF
done
that the
numbers SINGLE
in terms of the rules for real
couples thus considered were
o f t h e f o r m a - h bi.
N U M B E R S , the
IMPOSSIBLE
He
symbol
EXTRACTION,
or a
wrote:
V ^ T is
merely
absurd,
IMAGI-
N A R Y N U M B E R ; but i n the T H E O R Y O F C O U P L E S , the same symbol V - l REAL
is
significant, COUPLE,
square-root
o f the
and
denotes
namely
couple
(—1,
(as 0).
a we In
POSSIBLE have the
just
EXTRACTION, now
latter theory,
seen)
the
or
a
principal
therefore, though
not in the former, this sign V — l may properly be e m p l o y e d ; a n d we m a y write,
if
a, + a2V-l
we
choose,
for
any
couple
(au
a2)
whatever,
(a,,
a2)
=
(3; 4 1 7 - 4 1 8 )
25
A
History
Hamilton
of V e c t o r Analysis
concluded
the
essay b y
writing:
t h e p r e s e n t Theory o f Couples i s p u b l i s h e d . . .
to s h o w .
.
.
that expres-
sions w h i c h seem a c c o r d i n g to c o m m o n v i e w s to be m e r e l y symbolical, and quite
incapable
of being interpreted,
m a y pass
into the w o r l d of
thoughts, and acquire reality and significance, if Algebra be v i e w e d as not
a
mere
Art or
Language,
but as
the
Science
of Pure T i m e .
The
author hopes to p u b l i s h hereafter m a n y other applications of this v i e w ; especially to Equations and Integrals, and to a T h e o r y of Triplets and Sets
of Moments,
Steps, a n d N u m b e r s , w h i c h includes this T h e o r y of
C o u p l e s . (3; 4 2 2 ) The
" T h e o r y of Triplets" that he sought was of course the extension
of the
complex
It is and
number system
clear from
importance
this
to three
paper that
of the
dimensions.
Hamilton
associative,
understood the
commutative,
nature
and distributive
laws.26 T h e majority of mathematicians appreciated the significance of these
laws
had been
only
after
number
developed which
Hamilton's
"Theory"
systems
(especially
quaternions)
did not obey them.
was
poorly received.
Most mathematicians
d i d n o t agree w i t h H a m i l t o n ' s stress o n t i m e , a n d a f e w felt t h e n e e d for
the
d e v e l o p m e n t of c o m p l e x
geometrical
one.
That
Gauss
numbers
and
justification of complex numbers
Bolyai
on
a basis
other than
rejected the
a
geometrical
is almost certainly d u e to the fact
that they both had previously discovered non-Euclidean geometry. W h e n n o n - E u c l i d e a n g e o m e t r y b e c a m e k n o w n (after 1860), mathematicians
then
numbers
became
interested
in
the
in terms of ordered pairs of real
Hamilton's
"Essay"
was
quaternions
numbers.
an
important event in the history of the
for
a
discovery
of
Hamilton
on
direction,
in addition to the
the
development of complex
number
of
quest for higher complex quest in terms
reasons. numbers
First, from
it
set
another
of a m e t h o d of analysis
for t h r e e - d i m e n s i o n a l space. Second, t h r o u g h his m e t h o d of couples at
least
Hamilton
himself became
convinced of the
legitimacy
of
c o m p l e x n u m b e r s , a n d m o r e i m p o r t a n t l y he also o b t a i n e d a m e t h o d that c o u l d be e x t e n d e d in such a w a y as to assure the legitimacy of higher
complex
numbers,
formed
for example by triplets or quad-
r u p l e t s (as i n t h e c a s e o f q u a t e r n i o n s ) . T o p u t i t a n o t h e r w a y , b y t h i s method cantly
H a m i l t o n was prepared, perhaps to discover, m o r e signifi-
to
accept
as
legitimate,
"four-dimensional"
complex
num-
b e r s (as q u a t e r n i o n s ) , e v e n i f n o g e o m e t r i c a l j u s t i f i c a t i o n w e r e t o b e available. from
Support for the above analysis is f o u n d in a letter of 1841
Hamilton to
As
to T r i p l e t s ,
De I
Morgan:
m u s t a c k n o w l e d g e , that t h o u g h I fancied m y s e l f at
one time to be in possession of something w o r t h publishing about them,
26
Sir W i l l i a m R o w a n
Hamilton
and Quaternions
I never could resolve the p r o b l e m w h i c h you have justly signalised as t h e m o s t i m p o r t a n t i n t h i s b r a n c h o f ( f u t u r e ) A l g e b r a : t o assign t w o s y m b o l s O a n d &), s u c h t h a t t h e o n e s y m b o l i c a l e q u a t i o n a + M l + co) = a , +
+ c,&>
shall give the three equations b = bu c = c,
a = au
B u t , i f m y v i e w o f A l g e b r a b e j u s t , i t must b e p o s s i b l e , i n some w a y o r o t h e r , t o i n t r o d u c e n o t o n l y t r i p l e t s b u t polyplets, s o a s i n s o m e s e n s e t o satisfy the s y m b o l i c a l e q u a t i o n a= (a,, a2, . .
.
an);
a being here one symbol, as indicative of one (complex) thought; and f l j , a2, . . . a n d e n o t i n g n r e a l n u m b e r s , p o s i t i v e o r n e g a t i v e ; t h a t i s , i n o t h e r w o r d s , n dates, in t h e c h r o n o l o g i c a l sense of t h e w o r d , o n l y excluding
outward
marks
and
measures,
and
the
notion
of cause
and
e f f e c t . (2,11; 3 4 3 ) Moreover,
after
1843
point of v i e w for his he made this perusal
Hamilton
discovery one
of my
old
stressed
the
importance
discovery of quaternions.
essay,
day w h e n
I
He
of
this
said in fact that
" b e i n g t h e n fresh f r o m a re-
renewed
my
attempts
to
combine
my
g e n e r a l n o t i o n o f sets o f n u m b e r s , c o n s i d e r e d a s s u g g e s t e d b y sets of moments
of time,
with
geometrical
considerations
of points and
lines in t r i d i m e n s i o n a l space. . . . " 2 7
IV. At
Hamilton
s
end
of his
the
Discovery "Essay"
seeking a triplet system. find triplets
as
of
early as
of 1837
not alone
that John system
Hamilton from
at
which
T.
for
in his
1830.
(4;
and
least was
Graves 1836,
similar
(4;
[36]-[37])
De
Morgan,
had
"as
In in
tried
to or
been
1841 which
one
form
in
a
higher
he
was
Morgan
had
received asked
Hamilton
o w n statement
than
correspondence sent
of that year
That
complex
earlier
Graves
Hamilton
Hamilton De
conjecture
property.
perhaps
at w h i c h time to
stated that
shown by Hamilton's
early, had
[39]) T h e
distributive
quest is
Graves space
Hamilton
He h a d , in fact, m a d e d e f i n i t e a t t e m p t s to
entailed abandonment of the was
Quaternions
letter
Hamilton
2 8
on the subject
Hamilton
constructed a
number
myself."
from
a system in
1835.
Augustus
about his
trip-
lets. W i t h this letter w a s a c o p y o f D e M o r g a n ' s 1 8 4 1 p a p e r " O n t h e Foundation
of Algebra,"
2 9
brief discussion of triplets. When lets, t h e
by
1843
Hamilton
framework
within
in (4;
which
De
Morgan
had
included
a
[41]—[42])
began
another intense
which
the
search
search
for trip-
had to be conducted
27
A H i s t o r y of V e c t o r Analysis
was clear to him. T h e following m a y be taken as an outline of the properties that he consciously h o p e d the n e w n u m b e r s w o u l d have. 1. T h e associative property for addition and multiplication. T h u s if
N,
N\
and
(N
+
N')
+
2. T h e N + 3.
N'
N" N"
are
three
and
commutative
=
N'
The
+
N
and
distributive
4. T h e
such
N(N'N")
=
property NN'
=
numbers,
then
N + ( N ' + N") =
and
multiplication.
(NN')N". for
addition
N(N'
+
N'N.
property.
N")
=
NN'
+
NN".
p r o p e r t y that division is u n a m b i g u o u s . T h u s if N a n d N'
are any g i v e n c o m p l e x n u m b e r s , it is always possible to a n d only one n u m b e r X N
and
N')
such
that
(in
general,
NX =
a n u m b e r of t h e
find
one
same f o r m as
N'.
5. T h e property that the n e w n u m b e r s obey the law of the moduli. T h u s if any three triplets c o m b i n e so that {ax
bxi +
+
cj)(a2 +
b2i +
c2j) =
a3 +
b3i +
b22
c 22) =
(a32 +
fo32
c3j,
then (a,2 6. T h e
+
b2
+
c2){a2
+
+
+
c32):
property that the n e w numbers w o u l d have a significant
i n t e r p r e t a t i o n i n t e r m s o f t h r e e d i m e n s i o n a l space. It is well
k n o w n that ordinary c o m p l e x n u m b e r s have all these
properties, w i t h the exception that their geometrical interpretation is for t w o - d i m e n s i o n a l space. In one sense, then, the above is simply
a
detailed
which
statement that
would be
Hamilton
sought for n e w
numbers
directly analogous to ordinary complex numbers.
Of the above properties o n l y the c o m m u t a t i v e property for multiplication h a d to be a b a n d o n e d for quaternions. W i t h limits as restrict i v e a s these H a m i l t o n c o u l d o n l y b e satisfied w i t h quaternions, for, as C. S. Peirce p r o v e d in 1881, " o r d i n a r y real algebra, o r d i n a r y algeb r a w i t h i m a g i n a r i e s , a n d real q u a t e r n i o n s are t h e o n l y associative algebras in w h i c h division by finites always yields an unambiguous quotient." erties
are
30
It is s i g n i f i c a n t to ask at this p o i n t w h i c h of t h e s e p r o p -
retained
for the
scalar (dot)
a n d v e c t o r (cross)
m u l t i p l i c a t i o n s in m o d e r n vector analysis.
product
For the dot product the
associative l a w for multiplication is not relevant, and both the law of the m o d u l i and the unambiguity of division must be abandoned.31 For the must be
cross
product the
associative
and commutative properties
abandoned.32 Moreover division is not unambiguous, and
the l a w of the m o d u l i fails as well.33 F r o m the above comparison of the properties of quaternions and vectors it is e v i d e n t that at least in some ways quaternions not o n l y are s i m p l e r t h a n m o d e r n vectors b u t also entail f e w e r innovations.
28
Sir W i l l i a m R o w a n
In the
period
immediately
after
their
Hamilton
discovery
and Quaternions
quaternions
were
criticized because of the abandonment of the commutative property for m u l t i p l i c a t i o n .
It is an interesting historical speculation in this
regard as to what w o u l d have commutative
and
associative
sion was in general
been
said of a system in w h i c h the
properties
failed,
ent types of multiplication were defined. context of the above attempts to
and
in w h i c h divi-
impossible, and in w h i c h m o r e o v e r t w o differIn any case it was
properties that H a m i l t o n in
in the
1843 r e n e w e d his
triplets.34
find
O n O c t o b e r 16,
1843, H a m i l t o n discovered quaternions.
the best description
Perhaps
of the circumstances surrounding this event is
contained in a letter H a m i l t o n wrote in 1865 to his son A r c h i b a l d H. Hamilton: I f I m a y b e a l l o w e d t o s p e a k o f myself i n c o n n e x i o n w i t h t h e s u b j e c t , I m i g h t d o s o i n a w a y w h i c h w o u l d b r i n g you i n , b y r e f e r r i n g t o a n antequaternionic t i m e ,
when
the
of a V e c t o r ,
conception
you
were as
a
m e r e child, b u t h a d c a u g h t f r o m m e
r e p r e s e n t e d b y a Triplet:
and indeed I
happen to be able to p u t the finger of m e m o r y u p o n the year a n d m o n t h — October, 1843 — w h e n h a v i n g r e c e n t l y r e t u r n e d f r o m visits to C o r k a n d Parsonstown, connected w i t h a M e e t i n g of the British Association, the desire to discover the
laws
of the
multiplication referred to regained
w i t h me a certain strength a n d earnestness, w h i c h h a d for years b e e n dormant, b u t was t h e n on the p o i n t of b e i n g gratified, a n d was occasionally talked of w i t h you. E v e r y m o r n i n g in the early part of the abovecited month, on my c o m i n g d o w n to breakfast, your (then) little brother W i l l i a m E d w i n , a n d y o u r s e l f , u s e d t o a s k m e , " W e l l , P a p a , c a n y o u multiply t r i p l e t s " ? W h e r e t o I of the head:
was always o b l i g e d to r e p l y , w i t h a sad shake
" N o , I c a n o n l y add a n d s u b t r a c t t h e m . "
B u t on the 16th day of the same m o n t h — w h i c h h a p p e n e d to be a M o n day, and a C o u n c i l day of the Royal Irish A c a d e m y — I was w a l k i n g in to attend and preside, a n d your m o t h e r was w a l k i n g w i t h me, along the Royal Canal, to w h i c h she h a d perhaps d r i v e n ; a n d a l t h o u g h she t a l k e d with
me
now
and then,
my m i n d , w h i c h that
I
and a
felt
at
spark
l o n g years
to
gave
once
the
flashed come
yet
a n under-current o f t h o u g h t w a s
going on in
a t l a s t a result, w h e r e o f i t i s n o t t o o m u c h t o s a y importance. forth,
the
An
herald
electric (as
circuit
seemed
to
close;
I foresaw, immediately) o f m a n y
o f d e f i n i t e l y d i r e c t e d t h o u g h t a n d w o r k , b y myself i f
s p a r e d , a n d a t a l l e v e n t s o n t h e p a r t o f others, i f I s h o u l d e v e n b e a l l o w e d to live long enough distinctly to communicate the discovery. Nor could I resist t h e i m p u l s e — u n p h i l o s o p h i c a l as it m a y h a v e b e e n —to cut w i t h a knife on a stone of B r o u g h a m B r i d g e , as we passed it, the f u n d a m e n t a l formula w i t h the symbols, i, j, k; namely i2 = j2 = which
contains
t i o n , has
the
k1 =
ijk = —1,
Solution o f t h e Problem, b u t o f c o u r s e , a s
an
inscrip-
long since m o u l d e r e d away. A more durable notice remains,
however, on the
Council
Books of the A c a d e m y for that day (October
16th, 1843), w h i c h records t h e fact, that I t h e n a s k e d for a n d o b t a i n e d
29
A
History
leave
of V e c t o r Analysis
to
Session:
read
a
Paper
on
Quaternions,
at t h e
First
General
Meeting o f t h e
w h i c h reading took place accordingly, on M o n d a y the 13th of
t h e N o v e m b e r f o l l o w i n g . (2,11; 4 3 4 - 4 3 5 ) Thus
in
a
very
nounced
the
numbers
of t h e
dramatic
discovery form
of
manner
Hamilton
quaternions.
w + ix + jy +
kz,
discovered
These
are
and
an-
hypercomplex
w h e r e w, x, y, a n d z a r e r e a l
n u m b e r s , a n d i, j, a n d /c are u n i t vectors, d i r e c t e d a l o n g the x, y, a n d z axes
respectively. ij = ji
=
The
i, j, a n d /c units obey the f o l l o w i n g laws:
k
jk
- k
kj ii
It is
to be
general
= j j
noted that for t w o
equal
q'q.
=
T h e loss
i
ki
- i
ik
= =
kk
=
= j =
- j
—1
quaternions
q
and
of commutativity in
q',
qq'
does
not in
quaternions, while
it is v e r y i m p o r t a n t h i s t o r i c a l l y , is also significant m a t h e m a t i c a l l y , because this complicates calculations in w h i c h quaternions are used. A l l the other properties discussed above are satisfied by quaternions. T h u s it may be v e r i f i e d that q u a t e r n i o n m u l t i p l i c a t i o n is associative a n d q u a t e r n i o n division
is
unambiguous.
special m e n t i o n ,
These
are
two
important properties
which
bear
since t h e y are not preserved in the algebra of m o d e r n
vectors. There have been a n u m b e r of discussions published on the mathematical present
details
of Hamilton's
purposes
within the Almost
all
that
procedure
need
be
after his
is
his
discovery;
for the
that
Hamilton
worked
discussed above.35
context that has b e e n immediately
in
said
discovery
H a m i l t o n stated that he
"felt that it m i g h t be w o r t h my w h i l e to expend [on quaternions] the labour of at least ten 436)
Hamilton
working
(or it m i g h t be
actually
almost
spent
exclusively on
fifteen)
the
last
y e a r s t o c o m e . " (2,11;
twenty-two
quaternions.
The
years letters
of
his
life
of the first
f e w days after the discovery s h o w that H a m i l t o n felt that his system had
importance
nometry.
for
heat
electricity,36
theory,
sense
I
nions,
from
hope
spherical
trigo-
that
I
am
sions
of their principles, to
me
actually
g r o w i n g modest a b o u t t h e
quater-
m y s e e i n g s o m a n y p e e p s a n d vistas into f u t u r e expan-
pears
to
be
as
I
still
important
must for
century as the discovery of fluxions teenth."
and
(2,11; 4 4 2 ) I n 1 8 5 1 h e w r o t e : " I n g e n e r a l , a l t h o u g h i n o n e
(2,11;
assert that this d i s c o v e r y apthe
middle
of the nineteenth
was for the close of the seven-
445)
In o n e sense at least H a m i l t o n ' s discovery was e p o c h m a k i n g , for quaternions
were
the
number system which His
30
first
well-known
did not obey the
consistent
and
significant
laws of ordinary arithmetic.
" c u r i o u s , a l m o s t w i l d " (as h e c a l l e d i t [2,11; 4 4 1 ] ) d i s c o v e r y m a y
Sir W i l l i a m R o w a n
Hamilton
and Quaternions
be c o m p a r e d to the discovery of n o n - E u c l i d e a n geometry. B o t h discoveries broke bonds
set b y c e n t u r i e s o f m a t h e m a t i c a l t h o u g h t . I m -
mediately
other
after
by Augustus
1843
De
Morgan
new
(who
number
systems
were
(1846).38
T . G r a v e s ( 1 8 4 4 ) (2,11; 4 5 4 - 4 5 5 ) , a n d C h a r l e s G r a v e s This
section
publications 13,
1843,
Irish
will
on
be
concluded
by
a
quaternions through the
Hamilton
Academy,
of
read a paper on which
at
discovered
p u b l i s h e d f i v e n e w systems),37 J o h n
least
discussion
of Hamilton's
year
On
1847.
quaternions
part
was
November
before the Royal
published
in
1844.39
Either this paper or the very similar paper in the July, 1844, issue of the
Philosophical
nions.
(5,25;
Magazine
was
Quaternions,"
delivered
the
In
these
July,
1846,
papers
not analogous (the
w
first
November
Academy and published in in
his
publication
on
quater-
10-13) A m o n g the m o s t i m p o r t a n t papers are his " O n
issue
Hamilton
to
11,
1844,
of the
Philosophical
dealt w i t h
the
the
Royal
Irish
Magazine.
does
(5,29;
26-31)
fact that q u a t e r n i o n s are
ordinary complex numbers
o f w + i x + j y + kz)
to
1847,40 a n d t h e s i m i l a r p a p e r p u b l i s h e d
in that the
scalar part
n o t i n d i c a t e d i s t a n c e on an axis
un-
less, as he h a d s u g g e s t e d earlier, q u a t e r n i o n s be c o n s i d e r e d as f o u r dimensional. A n d on
Thus
account
Hamilton
of the
(writing
facility w i t h
in
the
which
third person)
this
so
stated:
c a l l e d imaginary e x -
p r e s s i o n , o r s q u a r e r o o t o f a n e g a t i v e q u a n t i t y , i s c o n s t r u c t e d b y a right line
having direction
in
space,
and
h a v i n g x,
y,
z f o r its t h r e e r e c t a n g u l a r
c o m p o n e n t s , o r p r o j e c t i o n s o n t h r e e r e c t a n g u l a r axes, h e has b e e n i n d u c e d to call the t r i n o m i a l expression itself, as w e l l as the line w h i c h it
represents,
a
VECTOR.
A
quaternion
g e n e r a l l y o f a real p a r t a n d a vector.
may
The
thus
fixing
be
said
to
consist
a s p e c i a l a t t e n t i o n on
this last part, or e l e m e n t , of a q u a t e r n i o n , by g i v i n g it a s p e c i a l n a m e , a n d d e n o t i n g it in m a n y calculations by a single a n d special sign, appears
to
the
dealing with
author to the
have
subject:
been
although
an
improvement in
the general
his
method
of
notion of treating the
constituents of the imaginary part as coordinates had occurred to h i m in his first researches. Regarded from a geometrical point of v i e w , this algebraically imagin a r y p a r t of a q u a t e r n i o n has t h u s so n a t u r a l a n d s i m p l e a s i g n i f i c a t i o n or representation in space, that the difficulty is transferred to the algebraic a l l y r e a l p a r t ; a n d w e are t e m p t e d t o ask w h a t t h i s last c a n d e n o t e i n g e o m e t r y , o r w h a t i n s p a c e m i g h t h a v e s u g g e s t e d it.41 The
origin
following
of the
word
quotation
in
vector ( a n d t h e w o r d scalar) the
similar
paper
in
is
the
clear from the Philosophical
Maga-
zine. The
a l g e b r a i c a l l y real p a r t m a y r e c e i v e . . . a l l v a l u e s c o n t a i n e d o n t h e
o n e scale o f p r o g r e s s i o n o f n u m b e r f r o m n e g a t i v e t o p o s i t i v e i n f i n i t y ; w e shall
call
it t h e r e f o r e
the
scalar part,
or
simply the
scalar o f t h e q u a t e r -
n i o n , a n d s h a l l f o r m its s y m b o l b y p r e f i x i n g , t o t h e s y m b o l o f t h e q u a t e r -
31
A
History
of V e c t o r Analysis
n i o n , t h e c h a r a c t e r i s t i c S e a l . , o r s i m p l y S., w h e r e n o c o n f u s i o n s e e m s l i k e l y t o arise f r o m u s i n g this last a b b r e v i a t i o n . O n t h e o t h e r h a n d , t h e algebraically
imaginary
part,
being
geometrically
constructed
by
a
straight l i n e or radius vector, w h i c h has, in general, for each d e t e r m i n e d q u a t e r n i o n , a d e t e r m i n e d l e n g t h a n d d e t e r m i n e d d i r e c t i o n in space, m a y be
c a l l e d t h e vector part, o r s i m p l y t h e vector o f t h e q u a t e r n i o n ;
and may
be denoted by prefixing the characteristic Vect., or V. We may therefore say
that
a
quaternion
is
in
general
parts, a n d m a y w r i t e Q = S e a l . SQ + V Q . F r o m the
(5,29;
above
quotations
introduced
cise
mathematical
The than
the
this.
scalar
sense,
analysis.
quotations
In
of its
own
scalar
and
vector
Q = S . Q + V . Q or s i m p l y Q =
it m a y be inferred that it was H a m i l t o n
term
a
sense
Hamilton
also
the
the
term
vector i n
similar
term
its
pre-
radius
vector
before.
however
they
had
and
although
used for m a n y years
above
sum
26-27)
who
had been
the
Q + Vect.
have
mark
the
introduced
a
far
greater
beginning
his
significance
of modern
symbols
S
and
vector
V because
"separation of the real a n d i m a g i n a r y parts of a q u a t e r n i o n is an operation of such frequent occurrence, and may be regarded as so fund a m e n t a l in this theory. . . of his
quaternions xi + yy'
yj + +
(5,29; 26) H a m i l t o n illustrated the use
symbols as applied to the product of the multiplication of two a a n d a',
zk a n d
zz');
V.
in
which
the
a' = x'i + y ' j + z'k, aa'
=
i(yz'
-
z y ' )
scalar parts w e r e 0.
Hamilton wrote: + j(zx'
-
x z ' )
+
Letting a =
" S . aa' = — (xx' +
k(xy'
-
yx').
.
.
(5,29; 30) It is o b v i o u s that these are e q u i v a l e n t to the m o d e r n vector
(cross)
product.42 bols,
product
using them
n o w be used. S.aa'
=
0
negative
of the
modern
scalar (dot)
in
cases
where
the
dot and
cross p r o d u c t w o u l d
Hamilton then proceeded to prove such equations as
when
Another 1847.43
and to the
H a m i l t o n and Tait m a d e very frequent use of these sym-
pair
In these
a
and
of
a'
very
papers
...1881
»
1891
1841 to 1900.
d e r i v e d f r o m this study is that d u r i n g the
period from 1841 to 1900 there w e r e 594 quaternion publications as c o m p a r e d to 217 Grassmannian analysis publications.10 H e n c e 73.2 percent there
of the
were
publications
2.73
quaternion
were
in
the
quaternion
publications
for
each
tradition,
or
Grassmannian
publication. The
results
obtained
strikingly similar. published from
when
only
books
were
considered
was
By actual count there were 38 quaternion books
1841
to
1900, whereas there w e r e
16 books pub-
lished d u r i n g this p e r i o d in the G r a s s m a n n i a n tradition. T h u s 70.4 percent
of the
books
dealt w i t h
quaternions,
or there
were
2.37
quaternion books for each book in the Grassmannian tradition. T h e quaternion
books
Grassmannian
averaged 281
tradition,
249
pages in length;
pages.11
the books of the
F r o m these numbers it may
111
A H i s t o r y of V e c t o r Analysis 8
6
6 5 4
4 3
1841 GRAPH
II.
1871
1861
1851
Quaternion Books from
1841 to
1891
1881
1900.
be inferred that interest in the tradition b e g u n w i t h H a m i l t o n was far greater t h a n that b e g u n w i t h G r a s s m a n n . T h e s e n u m b e r s have been broken d o w n into five-year intervals in Graphs I, II, IV, and V. Graph I shows the n u m b e r of quaternion publications in terms of five-year intervals Hamilton the
from
h i m s e l f are
1841 t o 1900. T h e p u b l i c a t i o n s w r i t t e n b y
indicated by
s o l i d areas.
n u m b e r of quaternion books for the
books by
Hamilton
Graph II
presents
same time intervals.
The
(including a translation and a second edition)
are i n d i c a t e d b y s o l i d areas. From
Graphs
I
and II the following conclusions may be drawn.
I n t e r e s t i n q u a t e r n i o n analysis w a s a t its h i g h e s t l e v e l d u r i n g t h e 1876-1900
period.
The
decrease
in
interest for the period
1881-
1885 indicated by G r a p h I is balanced by the peaking of G r a p h II for the same interval. It is important to note that H a m i l t o n wrote 73 percent of the pre-1866 quaternion publications and 19 percent of all
quaternion
publications.
It w o u l d of course be significant to compare the form of Graph I w i t h a graph s h o w i n g the rate of increase of m a t h e m a t i c a l publications
d u r i n g this
quaternion
time.
publications
Some after
idea of h o w the 1870
compares
rate with
of increase the
rate
of
of in-
crease in mathematical publications in general m a y be obtained by means of the study m a d e by H. S. W h i t e in 1915 based on an analysis
of
Graph
works III
listed
in
the
journal
Fortschritte
der
Mathematik.12
shows the n u m b e r of titles of mathematical articles a n d
b o o k s p u b l i s h e d i n t h e p e r i o d 1868 t o 1909.13 W h e n G r a p h s I a n d I I I are c o m p a r e d , it seems at first sight that interest in evident
quaternions
that
the
was
percentage
declining from
1876 to
of mathematical
1900, for it is
literature
that
was
d e v o t e d to quaternions decreases slightly. B u t this seems to be an
112
Traditions in Vectorial Analysis
1870
GRAPH
III.
Annual
'SO
N u m b e r of Titles
'90
1900
1910
of Mathematical Articles
and Books,
1868-
1909.
erroneous conclusion, for even m o r e
striking than the increase in
the n u m b e r of mathematical publications d u r i n g this period is the increase in the n u m b e r of fields of mathematical research. N u m e r ous fields —such as
non-Euclidean
geometry, mathematical logic,
group theory, as w e l l as m a n y branches of a p p l i e d mathematics — came into p r o m i n e n c e in this period. 68
48
28
16
1841
• GRAPH
IV.
1851
»
1861
>
1871
16
» 188T
Grassmannian Analysis Publications from 1841 to
»
1891
1900.
113
A H i s t o r y of V e c t o r Analysis 4
1841
M 851 GRAPH V.
1861
>1871
Grassmannian Analysis Books from
Graphs mannian
^ 1 8 8 1 — — •
1841
to
1 8 91
1900.
IV a n d V present the results of a s i m i l a r study of Grassanalysis
publications
and
books.
The
G r a s s m a n n are i n d i c a t e d b y t h e s o l i d areas.
works
written by
F r o m these graphs it
becomes clear that the b e g i n n i n g of the m a i n period of interest in Grassmannian
analysis
similar
for
period
other hand, the
came
roughly
quaternions
(1891
fifteen
years
compared
to
later than the 1876).
On the
n u m b e r of Grassmannian analysis publications for
the p e r i o d 1896 to 1900 was approaching the n u m b e r of quaternion publications
for the
same interval.
In regard to Grassmann's per-
358
88
52
52 44
American
British
GRAPH
114
VI.
Quaternion
Publications
French
by Country.
German
Other
Traditions in Vectorial Analysis
10
10 Spanish Russian
8
8
Polish Czech
Portuguese
Japanese
2
British
GRAPH
VII.
Quaternion
German
French
American
Dutch
Books by Country.
sonal contribution it is
noteworthy that he published 25 of the 33
(or 7 6 p e r c e n t ) o f t h e p u b l i c a t i o n s u p t o 1875, a n d 3 3 o f t h e total o f 2 1 7 (or 15 p e r c e n t ) of G r a s s m a n n i a n analysis p u b l i c a t i o n s . A
study
of the
two
fields
in
terms
of interest by country
is
of
significance. T h u s Graphs V I and V I I represent quaternion publications and books respectively as classified into five groups: British, American,
French,
German,
and those
of other countries. Quater-
nion books appeared in ten languages as follows (the n u m b e r after 125
32 28
16
16
GRAPH
French
American
British
VIII.
Grassmannian given
height
Analysis on
this
height on Graph VI
Publications
scale
indicates
indicates
2x
Other
German
by x
Country.
(Note
publications,
that
then
an
if any equal
publications.)
115
A H i s t o r y of V e c t o r Analysis
12
1 American GRAPH
each
IX.
Grassmannian Analysis
language
which
French
indicates
the
German
Italian
Books by Country.
number
of books):
English
(12,
of
1 0 w e r e p u b l i s h e d i n B r i t a i n a n d 2 i n A m e r i c a ) , F r e n c h (8),
German
(8),
Dutch
(2),
Japanese
(2),
P o r t u g u e s e (2), C z e c h o s l o -
v a k i a n (1), P o l i s h (1), R u s s i a n (1), a n d S p a n i s h (1). T h e r e w e r e i n a d d i t i o n a n u m b e r of papers in Italian, at least one in D a n i s h , a n d at least one tive
study
paper was p u b l i s h e d in Australia. F r o m this quantita-
it
may
be
inferred that 60
(books and papers) w e r e British,
percent
of the publications
15 percent w e r e American, 9 per-
cent were French, 8 percent German, with the remaining 8 percent c o m i n g from other countries. This should be considered in relation to
the
fact
that
26
percent
of the
books
on
quaternions
were of
British origin, 5 percent of A m e r i c a n origin (the British books w e r e of course
often
used by Americans), 21
percent
of German
guages.
These
origin,
statistics
and
the
percent of French and 21
remaining were
in
other
lan-
point out that interest in quaternions was
strongest in Britain but was substantial in America, Germany, and France, a n d that it e x t e n d e d to most of the then intellectually productive
countries of the
Graphs
VIII
and
IX
world. represent
Grassmannian
analysis
publica-
tions a n d books r e s p e c t i v e l y that are classified on the same basis of country
of publication.
four countries:
Grassmannian analysis books
each in A m e r i c a and Italy. the
appeared in
12 w e r e p u b l i s h e d in G e r m a n y , 2 in France, and 1 T h e study revealed that 57 percent of
Grassmannian analysis publications appeared in Germany, 18
p e r c e n t i n A m e r i c a , 10.5 p e r c e n t i n b o t h B r i t a i n a n d F r a n c e , w i t h a
116
Traditions in Vectorial Analysis
few
works
appearing
in
Polish,
Italian,
Spanish,
Russian,
and
analysis
was
Czechoslovakian. Thus
it
appears
centralized
in
that
Germany,
interest with
in
less
Grassmannian proportionate
interest outside
Germany than the interest in quaternions outside Britain. It is notew o r t h y that for b o t h systems the country in w h i c h the most interest d e v e l o p e d after the m o t h e r country of the analysis was America.14 This study m a y be summarized by the statement that the interest in quaternion analysis was roughly t w o and one-half times as great as interest in Grassmannian analysis and extended to m o r e countries, w i t h greater interest p r o p o r t i o n a t e l y d e v e l o p i n g i n c o u n t r i e s outside the country in w h i c h the system originated. To this m a y be added the observation that there was substantial interest in quaternions from 1876 to 1900 and that although interest in Grassmannian analysis came s o m e w h a t later, it d i d by the p e r i o d 1 8 9 1 - 1 9 0 0 attain substantial It is
magnitude.
the author's belief that this
quantified study tells no m o r e
than part of the story. It does h o w e v e r s u p p l y a v a l u a b l e perspective i n t o w h i c h d e v e l o p m e n t s d i s c u s s e d i n l a t e r s e c t i o n s m a y b e set.
III.
Peter
Guthrie
Tait:
Advocate
and
Developer
of
Quaternions
T h e i m p o r t a n c e o f T a i t f o r t h i s h i s t o r y i s f o u r f o l d . (1) H e w a s t h e a c k n o w l e d g e d leader of the quaternion analysts f r o m 1865 until his death in
1901. I n d e e d e i g h t b o o k s o n q u a t e r n i o n s ( i n c l u d i n g later
editions, translations, and coauthorships) carried his title page.
name on the
(2) T a i t d e v e l o p e d q u a t e r n i o n a n a l y s i s a s a t o o l f o r re-
s e a r c h i n p h y s i c a l s c i e n c e (as H a m i l t o n h a d n o t ) a n d c r e a t e d m a n y n e w theorems in quaternion analysis w h i c h w e r e capable of b e i n g t r a n s l a t e d i n t o m o d e r n v e c t o r a n a l y s i s . (3) I t w a s p r o b a b l y t h r o u g h Tait that M a x w e l l b e c a m e interested in quaternions.
(4) T a i t w a s
the most important o p p o n e n t of m o d e r n vector analysis. Peter Guthrie Tait was born in
1831 near E d i n b u r g h , Scotland.
In 1841 he entered E d i n b u r g h A c a d e m y w h e r e one year earlier the young
James
Clerk
Maxwell
had
enrolled.
Playmates
in
their
y o u t h , t h e t w o b e c a m e fast f r i e n d s a n d f r e q u e n t c o r r e s p o n d e n t s i n their maturity. was
M a x w e l l ' s 1846 entrance into E d i n b u r g h University
followed by Tait's in
1847, w i t h the o r d e r o f e n t r y b e i n g re-
versed w h e n Tait left for C a m b r i d g e
after one
year at E d i n b u r g h
University, w h i l e M a x w e l l stayed for three. After Tait's graduation in
1852
elected
as a
Senior
Fellow
Wranger
and
of Peterhouse
First
Smith's
College,
writing the first of his m a n y books.
Prizeman
Cambridge,
and
he
was
began
This was coauthored by W. J.
117
A H i s t o r y of V e c t o r Analysis
Steele of a
(who
died
Particle.
Lectures
In
on
ordered
before
1853
Quaternions. your
Athenaeum, caught my
its
Tait As
book,
c o m p l e t i o n ) a n d w a s e n t i t l e d Dynamics
ordered
Tait
on
later
a
copy
wrote
account
of
an
of t h e j u s t - p u b l i s h e d
to
Hamilton:
"when
advertisement
in
I
the
I had NO I D E A w h a t it was about. T h e startling title
eye
in
August
'53,
and as
I
was
going off to shooting
quarters I took it and some scribbling paper w i t h me to beguile the t i m e . . . . H o w e v e r as I t o l d y o u in my first letter I got easily e n o u g h t h r o u g h t h e first six L e c t u r e s . . . ." (1; 126) On
his
return
quaternions, he
to
Cambridge
primarily
was writing.
In
at Queen's
volved
in teaching as Thomas
of the
study of
labor involved in the book
1854 he accepted the Professorship in Mathe-
matics
league
Tait d i d not continue his
because
College, well
Andrews.
Belfast,
Ireland.
Here
he became in-
as in e x p e r i m e n t a l w o r k w i t h his colHe
also
pursued
the
study
of
the
' T h e o r i e s o f H e a t , E l e c t r i c i t y a n d L i g h t . " F i n a l l y i n A u g u s t , 1857, his
interest
in
quaternions
returned
as
a result of reading H e l m -
holtz' famous paper on vortex motion. T h e n as Tait wrote to Hamilton:
"I
suddenly bethought me of certain formulae I had admired
years ago at p. 610 of y o u r Lectures — a n d w h i c h I t h o u g h t (and still think) likely to serve my purpose exactly." to
which
Tait
referred
"