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V
\
\ \
DIFFEKENTIAL CALCULUS.
"'
xi \
^.^ 2\\ Ar\
DIFFERENTIAL CALCULUS WITH
APPLICATIONS AND NUMEROUS EXAMPLES:
AN ELEMENTARY
TREATISE.
BY
JOSEPH EDWAEDS,
M.A.,
FORMERLY FELLOW OF SIDNEY SUSSEX COLLEGE, CAMBRIDGE.
'onbon:
MACMILLAN AND AND NEW YORK. 1886. [All Rights Reserved.]
CO.,
$rtut*l> at the
ntb*rsttj)
BY ROBERT MACLEHOSE, WEST NILE STREET, GLASGOW.
PREFACE. THE
object
of the
present volume
is
to
offer to
the
student a fairly complete account of the elementary portions of the Differential Calculus, unencumbered,
by
such parts of\ the subject as are not usually read in colleges
and
Where and
schools.
a choice of method exists, geometrical proofs
illustrations
have been in most cases adopted
in
preference to purely analytical processes. It has
been the constant endeavour of the author
to impress
upon the mind of the student the geometrical
meaning of
differentiation
measurement of
its
rates of growth.
character of the operator of combination
and
which
--
as a
it satisfies
aspect as a
means of
The purely
analytical
symbol and the laws have also been fully
considered.
The applications of the Calculus i
to the treatment of
PREFACE.
vi
at an earlier stage plane curves have been introduced
than usual, from the interesting and important nature
At the same
of the problems to be discussed.
the chapters on Undetermined
time,
Forms and Maxima and
Minima, which have been thereby postponed,
may be
read
in their ordinary place if thought desirable.
The
and
direct
have
hyperbolic functions
inverse
~\
been freely used, and the convenient notation
-,
to
'
denote partial differentiation, has been adopted. It is
sets of easy illustrative
hoped that the frequent
examples introduced throughout the text will be found useful before attacking the
the copious
Many
selections
at
more
difficult
ends
the
of
problems in
the
chapters.
of these examples have been selected from various
university and college examination papers, others from
Home
papers set in the India and
Civil Service
and
Woolwich examinations, and many are new. I
have to thank the Rev. H.
P.
Gurney, M.A., formerly
Senior Fellow of Clare College, Cambridge, for the kind interest he has taken in the preparation of this work,
and
for
much
many
assisted
useful
suggestions.
I
have also been
in the revision of proof sheets and in
the verification of examples
by
J.
Wilson, Esq.,
M.A V
PR ErA CE. formerly Fellow of Christ's College, one of H.M. Inspectors of Schools,
and
also
by H. G. Edwards,
B.A., late Scholar of Queen's College.
that the
book
I
Esq.,
hope therefore
will not be found to contain
many
serious
A errors. '
JOSEPH EDWARDS. 80 CAMBRIDGE GARDENS.
NORTH KENSIN GTON, November, 1886.
VV.
,
EEKATA. Page
82, line
258, Ex.
l.-For 1
(a).
b" +1
For
read b n read
.
+
CONTENTS. PRINCIPLES AND PROCESSES OF THE DIFFERENTIAL CALCULUS.
CHAPTER DEFINITIONS. Object of the Calculus,
3-9
Definitions,
LIMITS.
.......
ARTS.
1-2
I.
and Fundamental
PAGES. 1
:
2-5
.
5-9
10-12
Limits.
13-17
18-24
Undetermined Forms, Four Important Undetermined Forms,
25
Hyperbolic Functions,
16-17
26-36
Infinitesimals,
17-24
Illustrations
CHAPTER
Principles,
....
9-11
12-15
II.
FUNDAMENTAL PROPOSITIONS. 26-30
37-38
Tangent to a Curve,
39-41
Differential Coefficients,
42-44
45-54
Examples, Notation, a as Rate-Measurer, Aspect
.
.
.
30-34 34-36 37-41
55-57
Constant, Sum, Product, Quotient, Function of a Function,
58-62
Inverse Functions,
44-48
CHAPTER
42-44
III.
STANDARD FORMS. xn
........
63-67
Differentiation of
68-73 74-81
The Circular Functions, The Inverse Trigonometrical Functions,
82
Interrogative Character of the Integral Calculus,
,
a*,
log x,
.
.
.
.
.
49-51
51-53 54-57
58
CONTENTS.
x
PA3ES.
ARTS.
84
Table of Results to be remembered, Cases of the Form w,
85
Hyperbolic Functions.
86-87
Illustrations of Differentiation,
83
Results,
CHAPTER
59-60
.
60-61 .
.
.
.
61-62
.
.
62-65
.
.
.
.
IV.
SUCCESSIVE DIFFEKENTIATION. 88-89
Repeated Differentiations,
90-94
d dx
95-97
Standard Results and Processes,
98-100 101
as
.
.
an Operative Symbol,
72-73 74-78
.
....
78-82 82-85
Leibnitz's Theorem,
Note on Partial Fractions,
CHAPTER
85-88
.
.
V.
EXPANSIONS. 102
Enumeration
103
Method Method Method
-yl04-lll 112
of
92
Methods,
Algebraical and Trigonometrical Methods, 92-94 94-99 Taylor's and Maclaurin's Theorems,
I.
II.
.
Differentiation or Integration of
III.
known 99-101
Series,
113
Method IV.
114-119
Continuity and Discontinuity,
120
Lagrange-Formula for Remainder after n Terms
By
a Differential Equation,
.
.
101-103 104-107
of
'
Taylor's Series,
121-122 123-124
.
.
.
126-128
.
.
107-109
Cauchy and Schlomilch and Roche, Application to Maclaurin's Theorem and Special Cases of Taylor's Theorem, .
109-110
.
110
Geometrical Illustration of Lagrange-Formula, Failure of Taylor's and Maclaurin's Theorems,
.
110-111
.
111-114
Formulae
of
.
125
.
129
Examples
130
Bernoulli's
of Application of
.
.
Lagrange-Formula,
.
Numbers,
CHAPTER
114-115 115-117
VI.
PARTIAL DIFFERENTIATION.
....
132-134
Meaning
135-136
Geometrical Illustrations,
137-139
Differentials,
129-132
140-144
Total Differential and Total Differential Coefficient,
132-134
of Partial Differentiation, .
.
126-127
127-129
CONTENTS.
xi PACKS.
ARTS.
145
146-150
151-152
153 154-155
156-160 161-168
an Implicit Function, 135 135-138 Order of Partial Differentiations Commutative, Second Differential Coefficient of an Implicit Function, 138-139 Differentiation of
.
.
.
.
An An
Illustrative Process,
Important Theorem,
...... ......
Extensions of Taylor's and Maclaurin's Theorems, Homogeneous Functions. Euler's Theorems, .
141
141-143
.
143-145
.
145-152
APPLICATIONS TO PLANE CURVES.
CHAPTER
VII.
TANGENTS AND NORMALS. 169-171
172 173 174-178 179-181
182-183 184-186
....
Equation of Tangent in various Forms, Equation of Normal, Tangents at the Origin, Geometrical Results. Cartesians and Polars, Polar Subtangent, Subnormal, etc., Polar Equations of Tangent and Normal, Number of Tangents and Normals from a given ih point to a Curve of the n degree. .
.
.
.
.
187
188-190
Polar Line, Conic, Cubic, etc., Pedal Equation of a Curve,
.
.
159-161
161-163 164-165
.
.
165-169
.
.
169-171
.
.
171-172
.
.
172-174 174-175
.
.
.
175-177
195-199
Pedal Curves, , Tangential- Polar Equation, Important Geometrical Results,
200
Tangential Equation,
201-204
Inversion,
187-190
205-207
Polar Reciprocals,
190-192
191-193
194
177-181 .
....
211-213
To find the Oblique Asymptotes, Number of Asymptotes to a Curve
214
Asymptotes
215
Method
216
Particular Cases of the General Theorem,
217-218
Limiting
219-220
Asymptotes by Inspection,
n ih
of the
parallel to the Co-ordinate Axes, of Partial Fractions for Asymptotes, of
Curve at
181
181-186 186-187
VIII.
ASYMPTOTES.
Form
.
.
CHAPTER 208-210
...
.... .... .
Infinity, .
.
degree,
203-205
206
.
.
206-208
.
.
208-209
.
.
209-211
.
.
211-213
.
213-214
CONTENTS.
XI 1
PAGES.
ARTS.
21
Curve through points with
222 223-225
226-229
its
of intersection of a given curve
..... ....
Asymptotes, Newton's Theorem, Other Definitions of Asymptotes, Curve in general on opposite sides of the Asymptote
..... ... .....
at opposite extremities.
230 231-233 234-235
236
Curvilinear Asymptotes, Linear Asymptote obtained
Exceptions,
by Expansion,
215-216
.
.
216-218
.
.
219-221
.
221-224
Polar Equation to Asymptote, Circular Asymptotes,
CHAPTER
215
224
IX.
SINGULAR POINTS.
..... ....
238-240
Concavity and Convexity, Points of Inflexion and Undulation,
229-231
241-248
Analytical Conditions,
231-238
249-250
Multiple Points,
251-253 254-257
Double Points, To examine the Nature
258-259
To
260-261
262-263
Singularities of Transcendental Curves, Maclaurin's Theorem with regard to Cubics,
264
Points of Inflexion on a Cubic are Collinear,
237
238-240
.
.
240-242
.
on a Curve, 242-248
of a specified point discriminate the Species of a Cusp,
.
.
CHAPTER
.
.
248-253
.
.
254-256
.
.
256-257
.
.
257-258
X.
CURVATURE. 265-266 267-268 269-271
272-275 276-279
280 281-282
283
284 285
Angle of Contingence. Average Curvature, Curvature of a Circle. Radius of Curvature, Formula for Intrinsic Equations, Formulae for Cartesian Equations Curvature at the Origin, Formula for Pedal Equations, Formulae for Polar Curves,
.
.
....
Tangential -Polar Formula, Conditions for a Point of Inflexion,
.
.
286-290
291-294
Intrinsic Equations,
.
266-268
268-269 269-272
273-275 276-277
277-278
....
Co-ordinates of Centre of Curvature, Involutes and Evolutes,
265-266
.
.
278 278-279 279-281
281-285 285-288
CONTENTS.
xiii
ARTS.
PACKS.
295-297
Contact.
298 299-300
Osculating Circle, Conic of Closest Contact,
301
Tangent and Normal as Axes; x and y
Analytical Conditions,
.
.
.
288-293
.
293-294
.
294-297
CHAPTER
in terms of
297-298
s,
XI.
ENVELOPES.
Parameter
302-303
Families of Curves
304
The Envelope touches each
;
;
Envelope,
.
of the Intersecting
31 1
.
Mem-
bers of the Family,
311-312
.
305
General Investigation of Equation to Envelope,
306-307
313-314 Envelope of A\* + 2B\ + C=0, Indeterminate Multipliers, 315-318 Several Parameters. Converse Problem. Given the Family and the Envelope to tind the Relation between the Parameters, 318-320 320 Evolutes, Pedal Curves, 321-322
308-311
312 313 314
312-313
.
.
CHAPTER
XII.
CURVE TRACING. 315-317
Nature of the Problem
Order
;
of
Procedure in
....
Cartesians,
318-319 320-321
322 323-325
326
Examples, Newton's Parallelogram, Order of Procedure for Polar Curves, Curves of the Classes r = a sin nd, r sin nd .
Curves of the
Class rn
.
= a* cos nd.
330-333
...
.
.
333-340 340-344
.
.
.
.
.
.
344-345
.
.
345-347
.
.
347-352
a,
Spirals,
APPLICATION TO THE EVALUATION OF SINGULAR FORMS AND MAXIMA
AND MINIMA CHAPTER
VALUES. XIII.
UNDETERMINED FORMS. 327-329
Forms
330
Algebraical Treatment,
331-334
Form
335
Form
to be discussed,
I**
-,
x
oo
,
.
.
.
.
... ... .
361-362 362-365
365-369
369
CONTENTS.
XIV
PAGES.
ARTS.
836-338
Form
00
369-373
00
339
Form
340
Forms 0, 00,
341
A Useful
342
dy
dx
co
oo
,
373
.
1*,
374
Example,
374
of Doubtful
Value at a Multiple Point,
CHAPTER
375
XIV.
MAXIMA AND MINIMA ONE INDEPENDENT VARIABLE.
...... .... ...... ....... ......
343-344
Elementary Methods,
345-347
The General Problem.
348-349
Properties of
Definition,
Maxima and Minima
Values. for Discovery and Discrimination,
381-383 384-386
Criteria
.
386-392
350
Analytical Investigation,
393-395
351
396-398
352-353
Implicit Functions, Several Dependent Variables,
354
Function of a Function,
400-404
355
Singularities,
404-405
.
.
.
.
.
398-400
APPENDIX. 356-366
On
the Properties of the Cycloid,
ANSWERS TO THE EXAMPLES,
.
417-424 427-439
PEINCIPLES
AND PEOCESSES OF THE
DIFFEEENTIAL CALCULUS.
CHAPTER DEFINITIONS.
I.
LIMITS.
Primary Object of the Differential Calculus. In Nature we frequently meet with quantities 1.
observed for some period of time, are found undergo increase or decrease ; for instance, the
which, to
if
distance of a
moving
particle
from a
known
fixed point ordinate of a given
in its path, the length of a moving curve, the force exerted upon a piece of soft iron is
gradually
made
to
which
approach one of the poles of a
magnet. When such quantities are made the subject of mathematical investigation, it often becomes necessary to estimate
their rates
This
of growth.
is
the
primary
object of the Differential Calculus. 2.
In the
first
six chapters
we
shall
be concerned with
the description of an instrument for the measurement of such rates, and in framing rules for its formation and use,
and the student must make himself as proficient as possible in its manipulation. These chapters contain the whole machinery of the Differential Calculus. The remaining chapters simply consist of various applications of the methods and formulae here established.
A
DEFINITIONS.
-2
We
3.
LIMITS.
commence with an explanation
of
several
technical terms which are of frequent occurrence in this subject, and with the meanings of which the student
should be familiar from the outset. 4.
Constants and Variables.
A
CONSTANT is a quantity which, during any set of mathematical operations, retains the same value. A VARIABLE is .a quantity which, during any set of mathematical operations, does not retain the same value, but
is
capable of assuming different values.
Ex. The area of any triangle on a given base and between given parallels is a constant quantity so also the base, the distance ;
between the parallel
lines,
the
sum
of the angles of the triangle are
constant quantities. But the separate angles, the sides, the position of the vertex are variables.
It has
become conventional
to
make
a,b,C,...,a,/3,y,..., from
use of the letters
the beginning of the
alphabet to denote constants and to retain later letters, for such as u, v, iv, x, y, 2, and the Greek letters tj, f, ;
variables.
Dependent and Independent Variables, An INDEPENDENT VARIABLE is one which 5.
may
any arbitrary value that may be assigned to it* A DEPENDENT VARIABLE is owwhich assumes
take
its
in consequence of some second variable or system of variables taking up any set of arbitrary values that in >/ be assigned to them. 6.
Functions.
When one quantity depends upon another system of
others, so
that
it
or
upon a
assumes a definite
valn(x) == sec #,
= sec ,
and
53
r
(05
+ h),
SGc(x-\-h)
,
h =Q-j=Lt dx
h
cosx
cos
-
h
.
sin
-
r-
(x+h)
.
h
/
oj
9
COS^C 73. Differential Coefficient of cosec x.
If
u = (p(x) (x) = sin ~
l
x,
x = smu, and x+h = siuU h = sinU siuu,
du_ dx
T4
Uu
T^
;
Uu
STANDARD FORMS.
55
77. Differential Coefficient of
u = (f>(x) = tan~ lx,
If
# = tan h = tan
Hence therefore
u,
and
U
x-\-h = ta n
tan
u,
Uu = Ltu ax h = Lt u=u Uu
du =
and
-j
T
JLtho T
U
l
T
T
-Uu
=u tan
sec%
^ cos
+ ta,n
1
jj U
2
u
1
+x
78. Differential Coefficient
u
If
x = cotu, and x+h = cot U\ h = cot U cot u,
Hence therefore
Uu
=
-7
dx
=
J-
Uu
h
U --
U
.
Ltrr= u ^- TTT sin (
U
TTT
v
sin
.
U sin u
u) 1
1
l+cot2u 79. Differential Coefficient of sec- l x.
^
If
Hence
x = secu, and
therefore
fi
A and
= sQC Usecu,
du "= -7
T
jJth
Uu Uu =u T
o
=jL/6rr_ 9/ w
5
/i
T = Ltrr ,
-
COS
U
COS
fr
U
u
tan
TT cos u U
,
T-PP
\
-Uu y^p
sec
U-secu
COS
U
COS
TT
U
2
'
56
STANDARD FORMS.
U-u
STANDARD FORMS. definition;
chapter
Ex.
we
(i.)
but by aid of Prop. VI. of the preceding can simplify the proofs considerably.
If
x = sin
we have
dx
whence
-=-
du
and therefore
and
57
u
= cos u
;
:
-=-=- =
dx
dx
cos
u
cos~ 1 o;=
since
~2
,
we have Ex.
(ii.)
dcos~ l x= dx
u
If
x = tan
we have
dx
,
whence
-,
du
c and therefore
1
dx
,,2>
cot" 1 ^ =
and since
-
A ,
we have 1
Ex.
(iii.)
If
+a
5
u x = vers u = l
we have
dx
= sin u
whence
-y
and therefore
-r-=
;
=
sinu
cos
STANDARD FORMS.
58
whence
82.
also
d covers" 1 ^ dx
1
The Integral Calculus.
Suppose any expression in terms of x given can we find a function of which that expression is the differential ;
The problem here suggested
coefficient?
is
inverse to
The dissuch functions is the fundamental aim of the The function whose differential Calculus.
that considered in the Differential Calculus.
covery of Integral
the given expression is said to be the For example, if (x) is (x) C, C being any
+
arbitrary constant. The notation by which this "
f(j>(x)dx being read
is
expressed
integral of
Thus we have seen d/
\
-T-T-(sm
x)
'(x)
= cos x, 1+a2
'
etc.,
whence
it
follows immediately that cos xdx = sin x,
f
I
1+x* etc.,
is
with respect to x"
STANDARD FORMS. where the arbitrary constant may bemadded in each case if desired.
We
do not propose to enter upon any description of the various operations of the Integral Calculus, but it will be found that for integration we shall require to 83.
remember the same
list
of standard forms that
is
estab-
lished in the present chapter and tabulated below, and it is advantageous to learn each formula here in its double
We
have therefore ventured to tabulate the standard forms for Differentiation and Integration toaspect.
Moreover, we shall find it convenient to be gether. able to use the standard forms of integration in several of our subsequent articles.
TABLE OF RESULTS TO BE COMMITTED TO MEMORY.
= xn = ax
= ex
du
-_n
-^-
.
dx
du = -^-
.
dx
ci
K
-Y-
.
dx
a
e
u = sin x. u = cosx. u = tan x.
loge a.
= ex
x
=,
= ex
dx
dx
or
x
= cos x.
-= dx
s\u x.
= sec Tdx
*/cos
xdx
o?.
.
=T
-. a log e
= sin x.
fsinxdx
=cos x.
fsocPxdx
= tan x.
39.
/
45.
a '
/
'i
I
40.
y=
41.
y=
v=
y= a 1 y = e *cos(&tan~ o;) y=
o
t
X'-X+l
51.
'
53.
?/
=
= 55.
2/
= 1
+
y=
56.
57.
/
= logn (#),
where log w means log log log
(repeated
=
58.
>Jb
1
n
+ a+ *Jb-a tan
log a;
tan
=
59. 60. 1
-
x p O
fi5 \J f
11 W
A A V/VJ
xjC rt/ C/ ^^~ C/
61.
67. 68.
62. 69.
64.
...
times).
a
63.
+ a cos a;
b
52.
44.
'
-
48.
50. 42.
a
'
'
y= y= y=
9
c08a:
(sina;) cota:
(cota)
+(cos,
+
coth
(cothic)
1
*.
STANDARD FORMS. 71.
78.
j^L
96. Differentiate
97. Differentiate sec' 1
^
T L
*j3L>
with regard to
_ with
-
98. Differentiate tan' 1
x/l-ce Differentiate tan" 1
99.
100. Differentiate
w cc
-^-
with regard to
2
regard to sec'
1
_ 2x*
2x
with regard to sin" 1
1 log tan" ^ with regard to
Sln s
x? ..
1
X
A1 V/
X
.
102.
TIt"}/ / J. L
to oo
y*
/
(/
i>ty
.
ax
Ify =
x
-
y log aj
prove
+ fu a! 1+
1
I
= dx
1-+
lH-...tooo,
1
03. If
v = a; + - 1 x +-
x+-X
i rv A
1U4.
Tf
Liy =
+
...
tO
00,
,
cosa;
sin
j.
x
cos
105. If
106.
'
'
*7 /
_
r/c
prove
~
\
T/
c?v -
1
+ 2y + cos
=
V
=
cos
sin
a?
+
*
*
+
...
cc
+ Jetc.
tO
00.
t/
a? -
sin x'
v sin x + v sin
to
oo,
x .
dx
2y-l If #n = the sum
common
"T"
x
1 *J
tC
1
ft/
1
1)T*OV*
-,
-i
--
Sin
= - as dx 2-x+-JC + -
prove -^
,
ratio,
of a G. P. to
prove that
n terms
of which r
is
the
STANDARD FORMS. a+
1 ch
+
mo 108.
nGiven
/^
'
%+...+ i
i
,
r2cos20
/a
1
Oa = rsm0n +
,
3
~
-i
and
dx\Q
i
""
r cos 30 +rcos + -
CHAPTER
V.
EXPANSIONS. The student
102.
will
have already met with several
expansions of given explicit functions in ascending in T tegral powers of the independent variable for example, ;
those for (x+a) n , e x log(l-f#), ,
tan^x,
sin x, cosx,
which
occur in ordinary Algebra and Trigonometry.
The
principal
methods of development in common use
may be briefly classified as follows I. By purely Algebraical or Trigonometrical processes. II. By Taylor's or Maclaurin's Theorems. III. By Differentiation or Integration of a known :
series, or
IV.
By
equivalent process. the use of a differential equation.
These methods we proceed to explain and exemplify. 103.
Ex.
1.
METHOD
Algebraic and Trigonometrical Methods. Find the first three terms of the expansion of log sec x in I.
ascending powers of
x.
By Trigonometry oos x
=
1
1
.V
2
-
2!
Hence where
log sec
x
+ ,
X4
X*
4!
6!
-4-
log cos x x 1 xt 3? .
+ .
log
^_-_+_-...s
(1
z\
EXPANSIONS. and expanding log(l
by the logarithmic theorem we obtain
z)
9J
=
^T O
r -__ + :L_ '" 6
,r.4
,2
|
93
41^6!
.2!
__
.
"
24
720
# _ "~ 4
h ence
Ex.
log sec
x
Expand
2.
A-
6
=+"+ 2 12 45 cos 3.^ in
......
powers of
x.
4 cos% = cos 3x + 3 cos #
Since
_
,
'
r
"4f'
2!
',
_ lV r
weobtain
sin%=i
Similarly
j
(3
3
-
-3)^3 1
5
(3
-
O2n - 1
Ex.
3.
volving
Expand tan #
in
-O
:
7
;
'-
_o
powers of x as far as the term
x*. /vW>
~ ^ __
Since
tan.v=
.
-)
~"
_j_
3
5
1
'
1
/y4
/jii
l_^+^_... we may by
actual division
...
.
show that .3
tan # =# 4-
3
+
g
15
x* +
.
.
.
in-
EXPANSIONS. Ex.
Expand |{log(l + #)}
4.
in
powers of
(l+x)y=ev los(l+x
Since
we
2
x.
),
have, by expanding each side of this identity, )g8
Hence, equating
+ y(y
-
coefficients of
y
2 ,
-a
series
-
*- etc.,
which may be written in the form
EXAMPLES. 1.
Prove
2.
Prove cosher = 1
/n
+
"
(3n
-
.
Prove that
riogd+a)]^ /!
where
r
p
r\
Pk denotes
the
sum
of all products
k at a time of the
first
>
natural numbers.
104.
METHOD
II. Taylor's
and Maclaurin's Theorems.
been discovered that the Binomial, Exponential, and other well-known expansions are all particular cases It has
of one general theorem known as Taylor's Theorem, which has for its object the expansion of f(x h} in ascending integral positive powers of h, f(x) being a function of a.
+
1
of
any form
whatever.
It will
be found that such an
not always possible, but we reserve for later articles [120 to 128] a rigorous discussion of the
expansion
is
limitations of the theorem.
EXPANSIONS.
95 *
105.
The theorem
referred to is that
under certain
circumstances
'
+!/(*) +
to infinity,
...
."
expansion off(x-\-h) in powers of h. This result was first published by Taylor in 1715, in " his Methodus Incrementorum Directa et Iriversa." In
O
,+
............ (3)
etc.
Hence putting x
()
in (1),
(2), (3), ...,
4
and
we have
=/(0), A=/'(0), A, =/"(()), substituting these values in (1)
f(x) =/(())
+ xf(0) +
O
etc., ...
;
.
.
109. It will be noticed that in the above proofs there is nothing to indicate in what cases the expansions assumed in the equations
numbered
(1) in
G
each of the
last
two
EXPANSIONS.
98
articles are illegitimate,
and we
shall
student to Arts. 120 to 128 for a fuller
have to refer the and more rigorous
discussion.
proceeding farther, that the student should satisfy himself that the well known n x e sinx, etc., expansions of such functions as (x + h) 110.
It is important, before
,
,
are really all included in the general results of Arts. 107, 108.
For example, if f(x) = xn ,f(x + h) = (x + h)", f(x) = nxn = n(n I)xu ~ 2 etc. Hence Taylor's Theorem,
-
,
gives the binomial expansion (x
+ h)" = a" + nhxn
~l
+
-^hV- + 2
. . .
i
= e? then f(x) ex f"(x) ex = 1,/(0) = 1, /'(O) = 1, etc. /(O)
Again, suppose f(x) therefore
Hence
Maclaurin's. f(x)
t
,
,
etc.,
Theorem,
=/(0) + xf(0) +
/"
nrfL
x
e
gives
the result
= l+a; +
known
+ +
...,
as the Exponential Theorem.
We
append a few examples which admit of expansion, and to which therefore the results of Arts. 107, 111.
108 apply. EXAMPLES. Prove the following results 5
= o:- x? 4- x 3
!
5
-.... !
:
EXPANSIONS.
/vi
>
,
99
3.
tan- 1 * =#->-+ 5 3
4.
e*cos
x = I + 2^cos
?r .
a?
4
+ 2*cos
+ 2W-
2ir
4
- + 2*cos -21
-+
43!
.
,
+....
4 n\ ,1
5.
6.
u
**
"7
GT"*"*
(
*
^^
f^tr^
I
Z.
^
~
. ..
'^
't
^ -
(
^
8.
S in-
^ 2 )l 9.
log sin (# + K)
= log sin ^ + h cot ^ -
2
cosec 2^ +
3!
1+
3 sm'%
.10.
METHOD 112.
III.
Expansion by Differentiation or Integration of
known
series or equivalent process.
The method Ex.
1.
To
Suppose then
of treatment is indicated in the following examples l expand tan~ x in powers of x. Gregory's Series.
= tan- = a + a^x + a.^ 2 + a$P + / (x) = ---- = ai + 2^^ + Sa^e2 + 4 4^3 + 1
.*?
f(x)
.
X ~p ^/
Hence, comparing these expansions, we have
i
a
Also,
therefore
= -1, = tan -1 = nir 1)
3
3
tan \v = nir + x- ^--+ -
3
5a 5 =l,
etc.
-'+..
. .
,
. .
.
:
:
EXPANSIONS.
100 This result
be obtained immediately by integration of the
may
1
series for 1
the constant a being determined as before.
To expand sin~ l x. = sin~ J .r = Suppose f(x) Ex.
2.
therefore
+ a ^K + a.^x* =a
=
1
2
4-
4
4
AJ 4-
.
.
.
,
But
2.4 Hence, comparing these
we have
series,
a.2 = a^ = a6 =
and
!
= !,
...
3a 3 =i,
=0, = 1.3
5%
2.4'
Also
.3.5 2.4.6'
1.3.r'
Hence
1
'
2.4
3
5
.
7
and, as before, this might have been obtained immediately bv integration of the expansion of
Ex.
3.
Again,
if
a
known
series
from it by differentiation. For example, borrowing the Ex. 2 of the next Art.,
1 2 series for (sin" ^) established in
viz.
#*
we
be given, we can obtain others
2#*
.
2.4 x6
obtain at once by differentiation 2 sin2.4
.
1
.*-
.
,
,
2.4.6
a*
2.4.6
EXAMPLES. 3
= smhlog(.>; + V 1 + ^
1.
Prove
2.
~ Prove tanh \v = x + '+--+....
>2
)
3
5
-^
=
.r
3
,1.3 ~~ >
ji> '
5
EXPANSIONS. .
And
Deduce from Ex.
3,
/i
-i
z\\
101
Art, 112,
2.4 x 1 "3 ~3~5~ "~3T5'T" % %A
fi
*
hence by putting .r=shi0, prove 2
= 1 - sin2 *
6 cot
sin4