Advanced High-School Mathematics

(Tina Meador) #1

SECTION 5.4 Polynomial Approximations 293


Example 2. (A handy trick)If we wish to compute the Maclaurin
series for cosx, we could certainly follow the same procedure as for the
sinx in the above example. However, since cosx = dxd sinx, we can
likewise obtain the Maclaurin series for the cosxby differentiating that
for the sinx, this yields the series


cosx∼

d
dx

∑∞
n=0

(−1)n

x^2 n+1
(2n+ 1)!

=

∑∞
n=0

(−1)n

x^2 n
(2n)!

.

Example 3. We we wanted to compute the Maclaurin series for sinx^2 ,
then computing the higher-order derivatives of sinx^2 would be ex-
tremely tedious! A more sensible alternative would be to simply replace
xbyx^2 in the Maclaurin series for sinx:


sinx^2 ∼x^2 −

x^6
3!

+

x^10
5!


x^14
7!

+···=

∑∞
n=0

(−1)n

x^4 n+2
(2n+ 1)!

.

Example 4.(A handy trick)Since ln(1 +x) =


∫ dx
1 +x

we may start

with the geometric series


1 −x+x^2 −···=

∑∞
n=0

(−1)nxn=

1

1 +x

,

and then integrate each term to obtain the Maclaurin series for ln(1 +
x) :


ln(1 +x)∼x−
x^2
2

+

x^3
3

−···=

∑∞
n=0

(−1)n


xndx=

∑∞
n=0

xn+1
n+ 1

.

(Note that there is no constant occuring in the above integrations since
whenx= 0, ln(1 +x) = ln 1 = 0.)


Example 5. Since


dn
dxn

ex=ex= 1 atx= 0, we immediately have the

Maclaurin series expansion forex:


ex∼ 1 +x+
x^2
2!

+

x^3
3!

+··· =

∑∞
n=0

xn
n!

.
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