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A TREATISE ON THE DIFFERENTIAL GEOMETRY OF PURVES AND SURFACES
BY
LUTHER PFAHLER EISENHA...
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I xSm*^i?c?^n
A TREATISE ON THE DIFFERENTIAL GEOMETRY OF PURVES AND SURFACES
BY
LUTHER PFAHLER EISENHART PROFESSOR OF MATHEMATICS IN PRINCETON UNIVERSITY
GINN AND COMPANY BOSTON
NEW YORK CHICAGO LONDON
CvA
COPYRIGHT,
1909,
BY
LUTHER PFAHLER EJSENHART ALL RIGHTS RESERVED 89-8
gftc
SUftengum
GINN AND COMPANY PRILTORS BOSTON
PKOU.S.A.
6 A-.ATH..
STAT.
LIBRARY
PEEFACE This book
is
a development from courses which I have given in
number of years. During this time I have come to more would be accomplished by my students if they had an otherwise adapted to the introductory treatise written in English and Princeton for a feel that
use of
men
beginning their graduate work.
the method Chapter I is devoted to the theory of twisted curves, in general being that which is usually followed in discussions of this I have introduced the idea of moving axes, subject. But in addition and have derived the formulas pertaining thereto from the previously
In this way the student is made familiar with a method which is similar to that used by Darboux in the first volume of his Lemons, and to that of Cesaro in his Geometria obtained Frenet-Serret formulas.
not only of great advantage in the treat ment of certain topics and in the solution of problems, but it is valu
This method
Intrinseca.
is
able in developing geometrical thinking.
book may be divided into three parts. The deals with the geometry of a sur first, consisting of Chapters II-YI, face in the neighborhood of a point and the developments therefrom,
The remainder
of the
such as curves and systems
of curves defined
by
differential
equa
which the
by large extent the method from the discussion of two quad properties of a surface are derived ratic differential forms. However, little or no space is given to the tions.
To a
is that of Gauss,
and their invariants. In algebraic treatment of differential forms in the first chapter, defined as addition, the method of moving axes, an to has been extended so as to be applicable investigation of the properties
of
surfaces
and groups
of
surfaces.
The extent
of the
no attempt has theory concerning ordinary points a discussion For the consider been made to exceptional problems. of such questions as the existence of integrals of differential equa tions and boundary conditions the reader must consult the treatises which deal particularly with these subjects. In Chapters VII and VIII the theory previously developed is as the quadrics, ruled applied to several groups of surfaces, such total curvature, and constant of surfaces minimal surfaces, surfaces, is
surfaces with plane
and spherical
so great that
lines of curvature. iii
PEEFACE
iv
The idea
of applicability of surfaces is introduced in Chapter III as a particular case of conformal representation, and throughout the
book attention
called to examples of applicable surfaces. However, the general problems concerned with the applicability of surfaces are discussed in Chapters IX and X, the latter of which deals entirely is
with the recent method
of
Weingarten and
its
developments.
The
remaining four chapters are devoted to a discussion of infinitesimal deformation of surfaces, congruences of straight lines and of
circles,
and
triply orthogonal systems of surfaces. It will be noticed that the book contains
student will find that applications of
the
w hereas r
certain of
others
many them
constitute
examples, and the are merely direct
extensions of the
formulas, theory which might properly be included as portions of a more ex tensive treatise. At first I felt constrained to give such references as
would enable the reader to consult the journals and treatises from which some of these problems were taken, but finally it seemed best to furnish no such key, only to remark that the Encyklopadie der mathematisclicn Wissenschaften may be of assistance. And the same
may
be said about references to the sources of the subject-matter of Many important citations have been made, but there has
the book.
not been an attempt to give every reference. However, I desire to acknowledge my indebtedness to the treatises of Darboux, Bianchi, and Scheffers. But the difficulty is that for many years I have con sulted these authors so freely that now it is impossible for except in certain cases, what specific debts I owe to each.
me
to say,
In its present form, the material of the first eight chapters has been given to beginning classes in each of the last two years; and the remainder of the book, with certain enlargements, has constituted an advanced course which has been followed several times. It is im suitable credit for the suggestions made and for me to
give possible the assistance rendered by my students during these years, but I am conscious of helpful suggestions made by my colleagues, Professors Veblen, Maclnnes, and Swift, and by my former colleague, Professor Bliss of Chicago. I wish also to thank Mr. A. K. Krause for making the drawings for the figures. It remains for me to express my appreciation of the courtesy shown by Ginn and Company, and of the assistance given by them during the printing of this book.
LUTHER PFAHLER E1SENHART
CONTENTS CHAPTEE
I
CURVES IN SPACE PAGE
SECTION
12.
PARAMETRIC EQUATIONS OF A CURVE OTHER FORMS OF THE EQUATIONS OF A CURVE LINEAR ELEMENT TANGENT TO A CURVE ORDER OF CONTACT. NORMAL PLANK CURVATURE. RADIUS OF FIRST CURVATURE OSCULATING PLANE PRINCIPAL NORMAL AND BINORMAL OSCULATING CIRCLE. CENTER OF FIRST CURVATURE TORSION. FRENET-SERRET FORMULAS FORM OF CURVE IN THE NEIGHBORHOOD OF A POINT. THE SIGN OF TORSION CYLINDRICAL HELICES
13.
INTRINSIC EQUATIONS.
14.
RICCATI EQUATIONS
15.
THE DETERMINATION OF THE COORDINATES OF A CURVE DEFINED
16.
MOVING TRIHEDRAL ILLUSTRATIVE EXAMPLES
1.
2. 3. 4. 5. 6.
7. 8.
9.
10. 11.
....
BY 17.
ITS INTRINSIC
FUNDAMENTAL THEOREM
1
3
4 6
8 9
10 12 14
16 18
20 22
25
27
EQUATIONS
30
.33
18.
OSCULATING SPHERE
37
19.
BERTRAND CURVES TANGENT SURFACE OF A CURVE INVOLUTES AND EVOLUTES OF A CURVE MINIMAL CURVES
39
20. 21. 22.
CHAPTER
41
43 .
47
II
CURVILINEAR COORDINATES ON A SURFACE. ENVELOPES 23.
24. 25. 26.
PARAMETRIC EQUATIONS OF A SURFACE PARAMETRIC CURVES TANGENT PLANE ONE-PARAMETER FAMILIES OF SURFACES. ENVELOPES v
52 54 56
....
59
CONTENTS
vi SECTION 27. 28. 29.
PAGE
DEVELOPABLE SURFACES. RECTIFYING DEVELOPABLE APPLICATIONS OF THE MOVING TRIHEDRAL ENVELOPE OF SPHERES. CANAL SURFACES
CHAPTER
....
61 04
66
III
LINEAR ELEMENT OF A SURFACE. DIFFERENTIAL PARAME TERS. CONFORMAL REPRESENTATION 30.
LINEAR ELEMENT
70
31.
ISOTROPIC DEVELOPABLE
72
32.
TRANSFORMATION OF COORDINATES ANGLES BETWEEN CURVES. THE ELEMENT OF AREA FAMILIES OF CURVES MINIMAL CURVES ON A SURFACE VARIATION OF A FUNCTION DIFFERENTIAL PARAMETERS OF THE FIRST ORDER DIFFERENTIAL PARAMETERS OF THE SECOND ORDER SYMMETRIC COORDINATES ISOTHERMIC AND ISOMETRIC PARAMETERS ISOTHERMIC ORTHOGONAL SYSTEMS CONFORMAL REPRESENTATION ISOMETRIC REPRESENTATION. APPLICABLE SURFACES CONFORMAL REPRESENTATION OF A SURFACE UPON ITSELF CONFORMAL REPRESENTATION OF THE PLANE SURFACES OF REVOLUTION CONFORMAL REPRESENTATIONS OF THE SPHERE
33. 34. 35.
36. 37. 38. 39.
40. 41.
42. 43. 44. 45. 46. 47.
72
....
74
78 81 82
84
....
88 91
93
95 98
.... .
.
100 101
104 107 109
.
CHAPTER IV GEOMETRY OF A SURFACE IN THE NEIGHBORHOOD OF A POINT
....
50.
FUNDAMENTAL COEFFICIENTS OF THE SECOND ORDER RADIUS OF NORMAL CURVATURE PRINCIPAL RADII OF NORMAL CURVATURE
51.
LINES OF CURVATURE.
52.
TOTAL AND MEAN CURVATURE EQUATION OF EULER. DUPIN INDICATRIX CONJUGATE DIRECTIONS AT A POINT. CONJUGATE SYSTEMS
48. 49.
53. 54.
57. 58.
FUNDAMENTAL FORMULAS
56.
117
118
EQUATIONS OF RODRIGUES
ASYMPTOTIC LINES. CHARACTERISTIC LINES CORRESPONDING SYSTEMS ON Two SURFACES GEODESIC CURVATURE. GEODESICS
55.
.
114
121
123
124 .
.......
126 128
130
...
131 133
CONTENTS
vii
PAGE
SECTION 59. GO. 61.
62.
GEODESIC TORSION SPHERICAL REPRESENTATION RELATIONS BETWEEN A SURFACE AND ITS SPHERICAL REPRE SENTATION HELICOIDS
137 141
143 146
CHAPTEE V FUNDAMENTAL EQUATIONS. THE MOVING TRIHEDRAL 63.
ClIRISTOFFEL SYMBOLS
152
64.
THE EQUATIONS OF GAUSS AND OF CODAZZI FUNDAMENTAL THEOREM FUNDAMENTAL EQUATIONS IN ANOTHER FORM
153
65. 66. 67. 68.
69.
70. 71.
72. 73. 74. 75. 76.
157
160
TANGENTIAL COORDINATES. MEAN EVOLUTE THE MOVING TRIHEDRAL FUNDAMENTAL EQUATIONS OF CONDITION LINEAR ELEMENT. LINES OF CURVATURE CONJUGATE DIRECTIONS AND ASYMPTOTIC DIRECTONS. SPHER ICAL REPRESENTATION FUNDAMENTAL RELATIONS AND FORMULAS PARALLEL SURFACES SURFACES OF CENTER FUNDAMENTAL QUANTITIES FOR SURFACES OF CENTER SURFACES COMPLEMENTARY TO A GIVEN SURFACE .
.
162 166
168 171 172
174 177 179 .
181
184
CHAPTER VI SYSTEMS OF CURVES. GEODESICS 77. 78. 79. 80.
81. 82.
83.
84. 85.
86. 87.
88.
89. 90.
ASYMPTOTIC LINES SPHERICAL REPRESENTATION OF ASYMPTOTIC LINES FORMULAS OF LELIEUVRE. TANGENTIAL EQUATIONS CONJUGATE SYSTEMS OF PARAMETRIC LINES. INVERSIONS SURFACES OF TRANSLATION ISOTHERMAL-CONJUGATE SYSTEMS SPHERICAL REPRESENTATION OF CONJUGATE SYSTEMS TANGENTIAL COORDINATES. PROJECTIVE TRANSFORMATIONS EQUATIONS OF GEODESIC LINES GEODESIC PARALLELS. GEODESIC PARAMETERS GEODESIC POLAR COORDINATES AREA OF A GEODESIC TRIANGLE LINES OF SHORTEST LENGTH. GEODESIC CURVATURE GEODESIC ELLIPSES AND HYPERBOLAS
189
.... ....
.
.
.
191
193
195 197
198 .
.
.
200 201 204 206
207 209
.... .
.
212
213
CONTENTS
viii
SECTION 91. 92. 93.
94.
PAGE
SURFACES OF LIOUVILLE INTEGRATION OF THE EQUATION OF GEODESIC LINES GEODESICS ON SURFACES OF LIOUVILLE LINES OF SHORTEST LENGTH. ENVELOPE OF GEODESICS
CHAPTEK
214 .
.
.
215 218
220
VII
QUADRICS. RULED SURFACES. MINIMAL SURFACES 95. 96.
97.
98. 99.
100.
101. 102. 103. 104. 105. 106. 107. 108.
109.
110. 111. 112. 113.
114.
CONFOCAL QUADRICS. ELLIPTIC COORDINATES FUNDAMENTAL QUANTITIES FOR CENTRAL QUADRICS FUNDAMENTAL QUANTITIES FOR THE PARABOLOIDS LINES OF CURVATURE AND ASYMPTOTIC LINES ox QUADRICS GEODESICS ON QUADRICS GEODESICS THROUGH THE UMBILICAL POINTS ELLIPSOID REFERRED TO A POLAR GEODESIC SYSTEM PROPERTIES OF QUADRICS EQUATIONS OF A RULED SURFACE LINE OF STRICTION. DEVELOPABLE SURFACES CENTRAL PLANE. PARAMETER OF DISTRIBUTION PARTICULAR FORM OF THE LINEAR ELEMENT ASYMPTOTIC LINES. ORTHOGONAL PARAMETRIC SYSTEMS MINIMAL SURFACES LINES OF CURVATURE AND ASYMPTOTIC LINES. ADJOINT MINI MAL SURFACES MINIMAL CURVES ON A MINIMAL SURFACE DOUBLE MINIMAL SURFACES ALGEBRAIC MINIMAL SURFACES ASSOCIATE SURFACES FORMULAS OF SCHWARZ .
.
226 .
....
.
.
.
.
CHAPTER
.
229
230 232 231 236
.
236 239 241
242
244 247 .
248 250
253 254
258 260
263 264
r
VIII
SURFACES OF CONSTANT TOTAL CURVATURE. TF-SURFACES. SURFACES WITH PLANE OR SPHERICAL LINES OF CUR
VATURE 115. 116. 117.
118. 119.
120. 121.
SPHERICAL SURFACES OF REVOLUTION PSEUDOSPHERICAL SURFACES OF REVOLUTION GEODESIC PARAMETRIC SYSTEMS. APPLICABILITY TRANSFORMATION OF HAZZIDAKIS TRANSFORMATION OF BIANCHI TRANSFORMATION OF BACKLUND THEOREM OF PERMUTABILITY
270 272 275
278 280 284 286
CONTENTS
ix
PAGE
SECTION
289
122.
TRANSFORMATION OF LIE
123.
JF-SURFACES.
124.
EVOLUTE OF A TF-SuitFACE SURFACES OF CONSTANT MEAN CURVATURE RULED IF-SuRFACES SPHERICAL REPRESENTATION OF SURFACES WITH PLANE LINES OF CURVATURE IN BOTH SYSTEMS SURFACES WITH PLANE LINES OF CURVATURE IN BOTH SYSTEMS SURFACES WITH PLANE LINES OF CURVATURE IN ONE SYSTEM.
125.
126.
127.
128. 129.
.
.
FUNDAMENTAL QUANTITIES
291 .
.......
131. 132.
133. 134.
296 299
300 302
305
SURFACES OF MONGE 130.
294
MOLDING SURFACES SURFACES OF JOACHIMSTHAL SURFACES WITH CIRCULAR LINES OF CURVATURE CYCLIDES OF DUPIN SURFACES WITH SPHERICAL LINES OF CURVATURE
307 308
310
312 IN
ONE 314
SYSTEM
CHAPTER IX DEFORMATION OF SURFACES 321
142.
PROBLEM OF MINDING. SURFACES OF CONSTANT CURVATURE SOLUTION OF THE PROBLEM OF MINDING DEFORMATION OF MINIMAL SURFACES SECOND GENERAL PROBLEM OF DEFORMATION DEFORMATIONS WHICH CHANGE A CURVE ON THE SURFACE INTO A GIVEN CURVE IN SPACE LINES OF CURVATURE IN CORRESPONDENCE CONJUGATE SYSTEMS IN CORRESPONDENCE ASYMPTOTIC LINES IN CORRESPONDENCE. DEFORMATION OF A
342
143.
RULED SURFACE METHOD OF MINDING
144.
PARTICULAR DEFORMATIONS OF RULED SURFACES
345
135.
136. 137.
138. 139.
140.
141.
.
323
327 331
333 336 338
344
CHAPTER X DEFORMATION OF SURFACES. THE METHOD OF WEINGARTEN 351
148.
REDUCED FORM OF THE LINEAR ELEMENT GENERAL FORMULAS THE THEOREM OF WEINGARTEN OTHER FORMS OF THE THEOREM OF WEINGARTEN
149.
SURFACES APPLICABLE TO A SURFACE OF REVOLUTION
145. 146.
147.
.... .
.
353 355 357 362
CONTENTS
x SECTION 150. 151.
PAGE
MINIMAL LINES ON THE SPHERE PARAMETRIC SURFACES OF GOURSAT. SURFACES APPLICABLE TO CERTAIN PARABOLOIDS
364
366
CHAPTER XI INFINITESIMAL DEFORMATION OF SURFACES 152.
GENERAL PROBLEM
153.
CHARACTERISTIC FUNCTION ASYMPTOTIC LINES PARAMETRIC ASSOCIATE SURFACES
154.
155. 156. 157. 158. 159.
....
373 374
376
378
PARTICULAR PARAMETRIC CURVES RELATIONS BETWEEN THREE SURFACES S, S v S SURFACES RESULTING FROM AN INFINITESIMAL DEFORMATION ISOTHERMIC SURFACES
CHAPTER
379
382
385 387
XII
RECTILINEAR CONGRUENCES 160.
DEFINITION OF A CONGRUENCE.
SPHERICAL REPRESENTATION
392
161.
NORMAL CONGRUENCES. RULED SURFACES OF A CONGRUENCE
393
LIMIT POINTS.
395
PRINCIPAL SURFACES 163. DEVELOPABLE SURFACES OF A CONGRUENCE. 164. ASSOCIATE NORMAL CONGRUENCES 162.
165. 166. 167.
168. 169.
170. 171. 172. 173.
FOCAL SURFACES
DERIVED CONGRUENCES FUNDAMENTAL EQUATIONS OF CONDITION SPHERICAL REPRESENTATION OF PRINCIPAL SURFACES AND OF DEVELOPABLES FUNDAMENTAL QUANTITIES FOR THE FOCAL SURFACES ISOTROPIC CONGRUENCES CONGRUENCES OF GUICIIARD PSEUDOSPHERICAL CONGRUENCES IT-CONGRUENCES CONGRUENCES OF RIBAUCOUR
........ ...... .
CHAPTER
398
401
.
.
403 406
407 409 412
414 415 417 420
XIII
CYCLIC SYSTEMS 174. 175. 176.
GENERAL EQUATIONS OF CYCLIC SYSTEMS CYCLIC CONGRUENCES SPHERICAL REPRESENTATION OF CYCLIC CONGRUENCES
426 431 .
432
CONTENTS
XI
PAGE
SECTION 177. 178.
179.
180.
SURFACES ORTHOGONAL TO A CYCLIC SYSTEM NORMAL CYCLIC CONGRUENCES CYCLIC SYSTEMS FOR WHICH THE ENVELOPE OF THE PLANES OF THE CIRCLES is A CURVE CYCLIC SYSTEMS FOR WHICH THE PLANES OF THE CIRCLES PASS THROUGH A POINT
436 437 439
440
CHAPTEE XIV TRIPLY ORTHOGONAL SYSTEMS OF SURFACES 181.
TRIPLE SYSTEM OF SURFACES ASSOCIATED WITH A
CYCLIC
SYSTEM
446
182.
GENERAL EQUATIONS. THEOREM OF DUPIN
183.
EQUATIONS OF LAME TRIPLE SYSTEMS CONTAINING ONE FAMILY OF SURFACES OF REVOLUTION TRIPLE SYSTEMS OF BIANCHI AND OF WEINGARTEN THEOREM OF RIBAUCOUR
184.
185.
186. 187. 188.
....
THEOREMS OF DARBOUX TRANSFORMATION OF COMBESCURE
INDEX
.
447 449 451
452
457 458 461
467
DIFFERENTIAL GEOMETRY CHAPTER
I
CURVES IN SPACE 1.
Parametric equations of a curve.
Consider space referred to
fixed rectangular axes, and let (x, y, z) denote as usual the coordi nates of a point with respect to these axes. In the plane 2 = draw a circle of radius r and center (a, b). The coordinates of a point P on the circle can be expressed in the form
x
(1)
a
-{-
r cos u,
y
= b H- r sin u,
2
=
0,
where u denotes the angle which the radius to P makes with the to 360, the point P describes As u varies from positive o>axis.
the circle.
The
quantities
a, 5,
r determine the position
and
size
of the circle,
whereas u determines the position of a point upon
In this sense
a variable or parameter for the equations (1) are called parametric
And
circle.
it is
equations of the circle. straight line in space
A
point on a,
/3,
Let
P
it,
The
7.
P (a, Q
6,
c),
and
is
its
determined by a direction-cosines
latter fix also the sense of the line.
be another point on the line, and let the P be denoted by u, which is positive Q
distance
P
or negative. The rectangular coordinates of are then expressible in the form (2)
it.
x
= a + ua,
y
= b + u(B,
z
c
P
+ wy. FIG. 1
To each value
u there corresponds a point on the line, and the coordinates of any point on the line are expressible as in (2). These equations are consequently parametric of
equations of the straight line. When, as in fig. 1, a line segment
pendicular to a line
OZ
PD,
of constant length
at D, revolves uniformly about
OZ
,
per
as axis,
CURVES IN SPACE
2
and at the same time
P is
locus of
D
moves along
called a circular helix.
2-axis, the initial position of
between the u,
latter
it
If
with uniform velocity, the the line OZ be taken for the
PD for the positive
and a subsequent position
a>axis,
of
PD
and the angle
be denoted by
the equations of the helix can be written in the parametric form
x
(3)
=a
z
= bu,
b is
of translation of D.
and
D
radian,
a sin u,
y
determined by the velocity of rotation of Thus, as the line PD describes a moves the distance b along OZ.
where the constant
PD
cos u,
the above equations u is the variable or parameter. Hence, with reference to the locus under consideration, the coordi indicate this by writing these nates are functions of u alone.
In
all of
We
equations
The functions / /2 / have x,
,
eral case
forms when the locus is a But we proceed to the gen when /r /2 / are any func
definite
circle, straight line or circular helix.
and consider equations
(4),
,
tions whatever, analytic for all values of u, or at least for a certain domain.* The locus of the point whose coordinates are given by (4),
u takes
as
all
values in the domain considered,
is
a curve.
Equa
tions (4) are said to be the equations of the curve in the parametric all the points of the curve do not lie in the same plane form.
When
called a space curve or a twisted curve ; otherwise, a plane curve. It is evident that a necessary and sufficient condition that a
it is
curve, defined linear relation
by equations (4), be plane, between the functions, such ofi + 5f2 +
(5) a, b, c,
dition
is satisfied
u
in (4) be replaced
0,
by any function of
v,
say
*fc*^(*0,
(6)
equations
*
+d=
that there exist a
as
d denote constants not all equal to zero. This con by equations (1) and (2), but not by (3).
where If
c/3
is
(4)
E.g. in case
when
it is
assume a new form,
u
complex,
is
two fixed values; supposed to be real, it lies on a segment between within a closed region in the plane of the complex variable.
it lies
EQUATIONS OF A CURVE It is evident that the values of x, y,
3
given by
z,
value
(7) for a
(4) for the corresponding value
are equal to those given by i u obtained from (6). Consequently equations (4) and (7) define the same curve, u and v being the respective parameters. Since
of
,
of
there
is
lytic, it
in
no restriction upon the function
except that
,
it
be ana
follows that a curve can be given parametric representation
an infinity of ways. 2. Other forms of the equations of a curve.
tions (4) be solved for w, giving parameter, equations (7) are
x
(8)
= x,
In this form the curve
is
y
u
equa
$(#), then, in terms of x as
= F (x),
z
2
= F (x).
really defined
8
by the
be a plane curve in the o?y-plane,
or, if it
If the first of
last
its
two equations,
equation
is
in the
customary form
y =/(*)
(9)
The
points in space whose coordinates satisfy the equation lie on the cylinder whose elements are parallel to the
y = F (x) z
and whose cross section by the xy-pl&ne is the curve y = F2 (x). In like manner, the equation z = F3 (x) defines a cylinder whose
2-axis
Hence the curve with the common to two cylinders equations (8) with perpendicular axes. Conversely, if lines are drawn through the points of a space curve normal to two planes perpendicular to one another, we obtain two such cylinders whose intersection is the given curve. Hence equations (8) furnish a perfectly gen elements are parallel to the #-axis. is
the locus of points
eral definition of a space curve.
in
In general, the parameter u can be eliminated from equations (4) such a way that there result two equations, each of which in
volves
all
three rectangular coordinates.
Qfa
(10)
Moreover,
if
y, z)
=
two equations
0,
<S>
a (a;,
Thus, y, z)
=
0.
of this kind be solved for
y and
we
z as
get equations of the form (8), and, in turn, of of u. Hence (4), by replacing x by an arbitrary function It will curve. a of also the are equations (10) general equations
functions of
x,
the form
be seen later that each of these equations defines a surface.
CURVES IN SPACE
4 It
should be remarked, however, that when a curve
two cylinders
as the intersection of
may happen
two surfaces
or of
(8),
is
defined (10), it
that these curves of intersection consist of several
parts, so that the
new
equations define more than the original ones.
For example, the curve defined by the parametric equations x
(i)
is
=
=
y
w,
w2
z
,
=
w3
,
a twisted cubic, for every plane meets the curve in three points. Thus, the plane
+
ax
by
-f
cz
+
=
d
meets the curve in the three points whose parametric values are the roots of the e(l uation
CM*
This cubic
lies
+
&n"
+
an
+
=
d
0.
upon the three cylinders y
=
x2
z
,
=
x3
=
y3
,
z2
.
and second cylinders is a curve of the sixth degree, of the sixth degree, whereas the last two intersect in a curve of the ninth degree. Hence in every case the given cubic is only a part of
The
intersection of the first
of the first
and third
it is
that part which lies on all three cylinders. u from equations (i), thus
the curve of intersection
Again,
we may
eliminate
xy
(ii)
=
y*
z,
=
xz,
and the second a hyperboliclies on both of these surfaces, parabolic cone. The straight line y = 0, z = but not on the cylinder y = x 2 Hence the intersection of the surfaces (ii) consists of
which the
first
defines a hyperbolic paraboloid
.
of this line
and the cubic. The generators of the paraboloid are defined by x
=
a,
for all values of the constants a
generator of the 3. is
first
=
and
ay 6.
;
y
From
z
6,
(i)
we
=
bx
;
see that the cubic meets each
family in one point and of the second family in two points.
Linear element.
the limit,
z
when
By
definition the length of an arc of a curve toward which the perimeter of an
it exists,
inscribed polygon tends as the
number
and their which such a limit
of sides increases
lengths uniformly approach zero. Curves for does not exist will be excluded from the subsequent discussion.
Consider the arc of a curve whose end points m mined by the parametric values U Q and # and let intermediate points with parametric values u^ w 2 ,
,
l
k
of the chord
mkmk+l
ma are mv m
,
,
deter
2,
.
,
be
The length
is
=V2,r/;.^,
L1
)-/v(oi
2 .
= i,
2,
3
LINEAR ELEMENT By
mean value theorem
the
5
of the differential calculus this
is
equal to
where
f
.
t
= wt +
0-
ay
M
)e
l
if
c
+
to this line is equal to \(bx"- ay")e*
bz )e
Hence,
=,
are the direction-cosines.
distance from
(23)
b
write the equa
MM
l
2
+
-]
2
+
]
+ [(az - cx )e +
2
1
.
-]
be considered an infinitesimal of the
}*.
first order,
this distance also is of the first order unless
in
which case
it is
of the second order at least.
But when
these
equations are satisfied, equations (22) define the tangent at M. Therefore, of all the lines through a point of a curve the tangent is
nearest to the curve.
* Whenever the functions x y z appear in a formula it is understood that the arc s is the parameter otherwise we use /{, /2 /3 indicating by accents derivatives with respect to the argument u. ,
;
,
,
,
CURVES IN SPACE
8 5.
When
Normal plane.
Order of contact.
the curve
such
is
that there are points for which
^=4
(24)
x
z
y
M
the distance from
to the tangent is of the third order at least. l In this case the tangent is said to have contact of the second order, whereas, ordinarily, the contact is of the first order. And, in gen eral, the tangent to a curve has contact of the wth order at a point,
if
the following conditions are satisfied for n
xw
V"y
^=^=^rr
25 )
When
the parameter of the curve is any whatever, equations (24), (25) are reducible to the respective equations ~jTf
fl
//
J%
Jl
-f(.n-\)
J%
J\
f (rt-1)
J
f(n-l)
Ja
2,
The plane normal contact
to the tangent to a curve at the point of normal called the plane at the point. Its equation is
is
(X
(26)
where
a,
/3,
x)
a
+ (Y
7 have the values
y}
ft
+ (Z
z)
7
=
0,
(20).
EXAMPLES Put the equations
1.
of the circular helix (3) in the
form
(8).
Express the equations of the circular helix in terms of the arc measured from a point of the curve, and show that the tangents to the curve meet the elements of the circular cylinder under constant angle. 2.
Show
3.
the curve
is
that
if
at every point of a curve the tangency
a straight
is
of the second order,
line.
Prove that a necessary and
sufficient condition that at the point (x 2/o) of = / "(BO) f(x) the tangent has contact of the nth order is/"(x ) the tangent crosses the = also, that according as n is even or odd r=/()(z ) = curve at the point or does not. 4.
,
the plane curve y .
.
.
;
Prove the following properties of the twisted cubic the cubic one and only one meets the (a) Of all the planes through a point of 3 cubic in three coincident points its equation is 3 u*x - 3 uy + z - w = 0. on a plane has a the orthogonal projection (6) There are no double points, but 5.
:
;
double point. a variable chord of the cubic and by each of (c) Four planes determined by four fixed points of the curve are in constant cross-ratio.
CUKVATUKE
FIKST
9
M
Let Jf, be two l points of a curve, As the length of the arc between these points, and A0 the angle between the tangents. The limiting value of Curvature.
6.
A0/As
as
M
l
Radius of
approaches
curvature.
first
namely dd/ds, measures the
Jf,
rate of
M
as the point of con change of the direction of the tangent at tact moves along the curve. This limiting value is called the
curvature of the curve at M, and
its reciprocal the radius of the latter will be denoted by p. first In order to find an expression for p in terms of the quantities defining the curve, we introduce the idea of spherical representa first
curvature
;
We
take the sphere * of unit radius with center at the origin and draw radii parallel to the positive directions ofthe tangents to the curve, or such a portion of it that no two tion as follows.
tangents are parallel. The locus of the extremities is a curve upon the sphere, which is in one-to-one correspondence with the
In this sense
given curve.
we have
a spherical representation, or
spherical indicatrix, of the curve.
The angle A# between the tangents to the curve at the points M, M^ is measured by the arc of the great circle between their
m
on the sphere. If ACT denotes the representative points m, l of of the the arc and m^ spherical indicatrix between length then by the result at the close of 3,
m
dO
v = lim
da
A,
0.
and the resulting equation be divided by
77
form
(X- x)a + (Y- y)l + (Z-z)c = Q, the current coordinates. When the
through the tangent at
where
of the
Jf,
y"b
+
77
z"c
first
approaches zero,
=
0.
and higher and in the
OSCULATING PLANE Eliminating
a,
c >,
from equations
11
we
(32), (33), (34)
obtain, as
the equation of the osculating plane,
X-x Y-y Z-z x
(35)
1
y
=
0.
x"
y"
From
this
we
plane
when
find that
in terms of a general
the curve
parameter
x_ x Y
is
w,
y
is defined by equations (4) the equation of the osculating
z_ z
(36)
//
fi
/,"
The plane defined by either of these equations is unique except when the tangent at the point has contact of an order higher than In the latter case equations (33), (34) are not independent, as follows from (24); and if the contact of the tangent is of the wth order, the equations =
the
first.
^+^+^
G
0?
up to and including n are not independent of this equation and (33) are inde But for r = n + pendent, and we have as the equation of the osculating plane at this
for all values of r
one another.
~\.,
X-x Y-
singular point,
x
When
Z-z =
y
0.
plane, and its plane is taken for the rry-plane, to Z = 0. Hence the osculating plane reduces the equation (35) of a plane curve is the plane of the latter, and consequently is the same for all points of the curve. Conversely, when the osculating
a curve
is
plane of a curve is the same for all its points, the curve is plane, for all the points of the curve lie in the fixed osculating plane. The equation
of the osculating plane
of
the twisted cubic
(2)
is
readily
reducible to
where JT, F, Z are current coordinates. From the definition of the osculating plane and the fact that the curve is a cubic, it follows that the osculating plane meets the curve only at the point of osculation. As equation (i) is a cubic in w, it follows that through a point (o, 2/o, ZQ) not on tne cnrve there pass three planes which osculate the cubic. Let MI, w 2 u 3 denote the parameter values of these points. ,
Then from
(i)
we have
=
3
XG,
3
?/o,
2t
i
\
n
CURVES IN SPACE
12 By means
of these relations the equation of the plane through the corresponding is reducible to
three points on the cubic
(X -
XQ) 3
7/0
- Y(
This plane passes through the point
y
(x
)
,
+
3x
2/0,
ZQ)
(Z 5
-
z
)
= 0.
hence we have the theorems
:
The points of contact of the three osculating planes of a twisted cubic through a point not on the curve lie in a plane through the point. The osculating planes at three points of a twisted cubic meet in a point which lies in the plane of the three points.
By means of these theorems we can establish a dual relation in space by mak ing a point correspond to the plane through the points of osculation of the three osculating planes through the point, and a plane to the point of intersection of the three planes which osculate the cubic at the points where it is met by the plane. In particular, to a point on the cubic corresponds the osculating plane at the point,
and
vice versa.
8.
Principal normal and binormal.
finity of
Evidently there are an in
normals to a curve at a point.
Two
of these are of par
the normal, which lies in the osculating plane at the point, called the principal normal; and the normal, which is perpendicular to this plane, called the binormal.
ticular interest
:
If the direction-cosines of the
we have from X
:
/
binormal be denoted by X,
/>t,
z>,
(35) :
v
= (y
z"-
z
: y")
(z
z
x"~
:
z")
(*
/ -y
x").
In consequence of the identity
common
the value of the
ratio
is
reducible by means of (19) and
We
take the positive direction of the binormal to p.* be such that this ratio shall" be -f- p then (28) to
;
\ = p(y z"-z f
(37)
When (38)
the parameter u
x=
v z"),
= p(x y
general, these formulas are
:
~ P dycPz
dzcfy
~~df~
*For
is
x
x"~
282
or in other form /oof
y"),
^ = P (z
SV = /
0,
as
is
^~ P
dzd*xdxd?z
~ P dxd y
~
ds
3
seen by differentiating
2x"*=
1
dyd^x ds*
with respect to
s.
PRINCIPAL NORMAL AND BINORMAL By
definition the principal
normal
13
perpendicular to both the the convention that its positive is
tangent and binormal. We make direction is such that the positive directions of the tangent, prin cipal normal and binormal at a point have the same mutual ori entation as the positive directions of the x-, y-, z-axes respectively.
These directions are represented in fig.
2 by the lines
Hence,
if
Z,
m,
MT, MC, MB.
denote the direc
n,
tion-cosines of the principal normal,
we have*
m
(39)
=4-1,
/JL
from which
it
= mv = \ = ftn a I
I
FIG. 2
follows that
fjij
nu,
ft
n\
Iv,
7
vft^
m=
va
\7,
n
=
yl
#n,
777*,
/Ji
i^
= Z/i = Xp = am
m\, yuo:,
ftl.
,
Substituting the values of #, /3, 7; X, /u-, i^ from (19) and (37) in the m, w, the resulting equations are reducible to expressions for ,
Hence, when the parameter u (42)
is
general,
we have
l=-(W-
or in other form, 2
_ In consequence of (29) equations (42) (43)
or
by means of
dzd 2 s
be written:
da
dft
dj
ds
ds
ds
(27),
da
Hence the tangent to the principal
may
2
m
dft
dy
do-
da-
to the spherical indicatrix of a curve is parallel
normal to the curve and has the same sense. *C. Smith, Solid Geometry, llth
ed., p. 31.
CURVES IN SPACE
14 9.
Center of
circle.
Osculating
first
We
curvature.
have defined
M
the osculating plane to a curve at a point to be the limiting of the determined the and by a plane position by tangent at of the as the latter the curve. curve, approaches point l along
M
M
We
M
consider
now
the circle in this plane which has the same tan
M as the curve, and passes through M The limiting posi M approaches called the osculating
gent at
{
tion of this circle, as to the
curve at M.
7I/,
l
circle
It is evident that its center
normal at M. Hence, with reference F the coordinates of (7 denoted by Q cipal
,
X =x +
Y
rl,
where the absolute value of
y
M
when
l
X
,
-f
rm,
,
to
Z
Q,
C
is
on the prin
any fixed axes in space, are of the form
Z^=z +
rn,
r is the radius of the osculating circle.
In order to find the value of of the circle,
.
is
we
r,
does not have
return to the consideration limiting position, and
its
we
let X, F, Z\ Zj, m^ n^ r^ denote respectively coordinates of the cen ter of the circle, the direction-cosines of the diameter through and the radius. If x v y v z l be the coordinates of M^ they have the
M
values (17), and since rl If
l
is
on the
notice that
we have i
2 e*x".
-)
after reducing the
.
above equation
2
,
1-r^Z/ where
circle,
= 2(A - xtf = 2(7-^- ex -
^x ^ = 0, and through by e we have
we
divide
M
limi-t r l
becomes
r,
^x\
=
(),
and higher orders in e. In the becomes 2z 7, that is - and this equation
involves terms of the
77
+*?
first
,
reduces to
so that r
is
equal to the radius of curvature.
On
this
account the
of curvature and its center the osculating circle is called the center of first curvature for the point. Since r is positive the center circle
of curvature
is
consequently
its
(44)
on the positive half of the principal normal, and coordinates are
X =x +
pl,
Y =y + pm,
Z = z + pn. Q
CENTER OF CURVATURE The
15
normal to the osculating plane at the center of curva
line
called the polar line or polar of the curve for the corre sponding point. Its equations are
ture
is
X-x-pl = Y-y-pm = Zz
/45\
\
In
line for
C
2
fig.
pn
^
v
JJL
represents the center of curvature and
CP
the polar
M.
A curve may be looked upon as the path of a point moving under the action of a system of forces. From this point of view it is convenient to take for parameter the time which has elapsed since the point passed a given position. Let t denote this parameter. As t is a function of 8, we have dx
ds
_dx ~
_
ds
_ dt~
Hence the
may
ds
dz
~dt
~dt~
dy
C
ds~dt~ *dt
_
ds
y ~dt
rate of change of the position of the point with the time, or its velocity,
be represented by the length
manner, by means of
laid off
on the tangent
In like
we have
(41),
d^ _ ~ From
to the curve.
dt
this it is seen that the rate of
d?s
n
/ds\ 2
7
change of the velocity at a point, or the
be represented by a vector in the osculating plane at the point, through the latter and whose components on the tangent and principal normal
may
acceleration,
d*s -
1
, and -
df*
1.
/dY I
)
P \dtj
EXAMPLES
Prove that the curvature of a plane curve defined by the equation
Show
(x,
y)dx
ex
cy p 2.
M
(J/
2
+
N
that the normal planes to the curve,
x
a sin 2
it,
y
=
a sin u cos w,
z
=
a cos M,
pass through the origin, and find the spherical indicatrix of the curve. 3.
The
4.
Derive the following properties of the twisted cubic
straight line
is
In any plane there planes can be drawn. (a)
the only real curve of zero curvature at every point.
is
one
line,
:
and only one, through which two osculating
fixed osculating planes are cut by the line of intersection of any two osculating planes in four points whose cross-ratio is constant. and four fixed points of the curve (c) Four planes through a variable tangent (6)
Four
are in constant cross-ratio. (d)
What
is
the dual of
(c)
by the
results of
7 ?
CURVES IN SPACE
16 5.
Determine the form of the function
curve x 6.
=
w,
y
=
sin w, z
so that the principal normals to the
(u) are parallel to the yz-plane.
Find the osculating plane and radius of x a cos u -f 6 sin w, y = a sin u
first
+
10. Torsion. Frenet-Serret formulas. less a
curvature of
6 cos w,
z
It has
=
c sin 2 u.
been seen
that,
un
curve be plane, the osculating plane varies as the point
moves along the curve. The change in the direction depends evidently upon the form of the curve. The ratio of the angle A^ between the binormals at two points of the curve and their curvi linear distance As expresses our idea of the mean change in the direction of the osculating plane.
And
so
we take
the limit of
one point approaches the other, as the measure of of this rate the change at the latter point. This limit is called this ratio, as
the second curvature, or torsion, of the curve, and
its
radius of second curvature, or the radius of torsion. will be denoted by r.
inverse the
The
latter
In order to establish the existence of this limit and to find an expression for
we draw
in terms of the functions defining the curve,
it
radii of the unit sphere parallel to the positive binormals
of the curve
and take the locus of the end points
a second spherical representation of the curve.
of these radii as
The
coordinates of
points of this representative curve on the sphere are X, /*, v. Pro ceeding in a manner similar to that in 6, we obtain the equation
i_
(46)
where
r dcr l is
2
ds*
the linear element of the spherical indicatrix of the
binormals. In order that a real curve have zero torsion at every point, the cosines
X,
/*,
v
must be constant. By a change of the fixed axes, which evidently has no effect upon the form of the curve, the cosines can be given the values X = 1, /* = v = 0. const. Hence a necessary It follows from (40) that a = 0, and consequently x and sufficient condition that the torsion of a real curve be zero at every point is that the curve be plane.
In the subsequent discussion
we
shall
respect to s of the direction-cosines a,
deduce them now.
From
(4T)
a
(41)
=i,
/3
need the derivatives with
&
7;
we have
=, y-.
I,
m, w;
X, p, v.
We
FRENET-SERRET FORMULAS In order to find the values of X respect to
s
/*
,
i/,
,
we
17
differentiate with
the identities,
X 2 +At2+z 2 = 1?
+
a\
,
/A
+
= 0,
7*
and, in consequence of (47), obtain
From
these,
+
= 0,
The
by
the proportion (40), follows
1
fjLfj,
vv
1
f :
fjL
:v
r
is
,: >
is
I
=
(46).
=
V
t
:
=
l*>
T
T
T
If the identity
from
the latter equation.
V A =
(48)
the result
1/r, as is seen
is
not determined by thus sign by writing the above proportion
algebraic sign of r its
0.
=l:m:n,
the factor of proportionality
We fix
r
+
X and
+ /V + yv =
\
XX
^7
vfi
be differentiated with respect to
s
reducible by (40), (47), and (48) to
I
(49)
m
and n Similar expressions can be found for Gathering to fundamental in gether these results, we have the following formulas .
the theory of twisted curves, and called the Frenet-Serret formulas
Y
\^ v v ^-/l+2),
(50)
As an example, we If the equation
:
derive another expression for the torsion.
\
= p(y z
be differentiated with respect to
"
s,
z
y")
the result
may be
written
and similar ones for WI/T, rz/r be multiplied by ?, wz, n respectively and added, we have, in consequence of (50) and (41), If this equation
y
x
z z"
(51)
y"
x
"
"
y
z
"
CUKVES IN SPACE
18
The last three of equations (50) give the rate of change of the direction-cosines of the osculating plane of a curve as the point of osculation moves along the curve. From these equations it follows that a necessary and sufficient condition that this rate of change at a point be zero is that the values of s for the point make the determinant in equation (51) vanish. At such a point the osculat
ing plane
said to be stationary.
is
Form
of curve in the neighborhood of a point. The sign of have made the convention that the positive directions of the tangent, principal normal, and binormal shall have the same 11.
We
torsion.
relative orientation as the fixed
M
2-axes respectively.
x-, y-,
When we
take these lines at a point for axes, the equations of the curve Q can be put in a very convenient form. If the coordinates be ex
pressed in terms of the arc measured from = (41) that for s
M^ we
have from (19)
and
P
When
the values of
I
and X from
the fourth of equations (50),
x
(5 2)
"
this
for
z"
-z
-
for
"
y
/
must be remarked that the new axes of coordinates are not necessarily real, so that when it is important to know whether the It
curves are real (73).
We
An
will be advisable to consider the general formulas
example of
this will be given later.
apply the preceding results to several problems. is plane the torsion is zero, and conversely. For this case equa
shall
When
it
the curve
tion (65) reduces to
=
-
ds
which the general
of
= where a
is
integral
is
p
-if J 1
ae
P
an arbitrary constant, and by
spherical indicatrix of the tangent.
=
ae~
(27)