294 CHAPTER 5 Series and Differential Equations
Example 6. (A handy trick)In the above series we may substitute
−x^2 forxand get the Maclaurin series fore−x
2
:
e−x
2
∼ 1 −x^2 +
x^4
2!
−
x^6
3!
+···=
∑∞
n=0
(−1)n
x^2 n
n!
.
Note how easy this is compared to having to calculate d
n
dxn(e
−x^2 ) (where
the chain and product rules very much complicate things!).
Example 7. (A handy trick)Let’s find the Maclaurin series expan-
sion of the functionf(x) =
sinx
x
. In this case, we certainly wouldn’t
want to compute successive derivatives of the quotient
sinx
x
. However,
remembering the Maclaurin series expansion of sinxand then dividing
byx will accomplish the same thing much more easily; the resulting
series is
sinx
x
∼ 1 −
x^2
3!
+
x^4
5!
−···=
∑∞
n=0
(−1)n
x^2 n
(2n+ 1)!
.
Example 8. The Taylor series expansion of cosx about x =
π
2
.
We have, where f(x) = cosx, that f
(π
2
)
= cos
(π
2
)
= 0, f′
(π
2
)
−sin
(π
2
)
= − 1 , f′′
(π
2
)
= −cos
(π
2
)
= 0, f′′′
(π
2
)
= sin
(π
2
)
= 1, after
which point the cycle repeats. Therefore, the Taylor series is
cosx ∼ −
(
x−π 2
)
+
(
x−π 2
) 3
3!
−
(
x−π 2
) 5
5!
+···=
∑∞
n=1
(−1)n
(
x−π 2
) 2 n− 1
(2n−1)!
.
Example 9. (A handy trick)We know that
1 +x+x^2 +x^3 +···=
∑
n=0
xn=
1
1 −x
valid for|x|< 1.
we can get further valid sums by differentiating the above:
1 + 2x+ 3x^2 + 4x^3 +··· =
∑∞
n=0
(n+ 1)xn
=
d
dx
(
1
1 −x
)
=
1
(1−x)^2
, valid for|x|< 1.