SECTION 5.3 Concept of Power Series 287
∑∞
n=0
n 2 n
2 n
=
∑∞
n=0
n which also diverges.
Therefore,
∑∞
n=0
nxn
2 n
has interval of convergence − 2 < x < 2.
Example 8. The power series
∑∞
n=0
(−1)nxn
n!
has infinite radius of con-
vergence so there are no endpoints to check.
Before closing this section, we should mention that not all power se-
ries are of the form
∑∞
n=0
anxn; they may appear in a “translated format,”
say, one like
∑∞
n=0
an(x−a)n, where ais a constant. For example, con-
sider the series in Example 4, on page 285. What would the interval of
convergence look here? We already saw that this series was guaranteed
to converge on the interval− 4 < x < 0. If x =−4, then this series
is the convergent alternating harmonic series. Ifx= 0, then the series
becomes the divergent harmonic series. Summarizing, the interval of
convergence is− 4 ≤x <0.
Exercises
- Determine the radius of convergence of each of the power series
below:
(a)
∑∞
n=0
nxn
n+ 1
(b)
∑∞
n=0
nxn
2 n
(c)
∑∞
n=0
(−1)nx^2 n
n^2 + 1
(d)
∑∞
n=0
(−1)nx^2 n
3 n
(e)
∑∞
n=0
(x+ 2)n
2 n
(f)
∑∞
n=0
(−1)n(x+ 2)n
2 n
(g)
∑∞
n=0
(2x)n
n!
(h)
∑∞
n=1
( xn
1 +^1 n
)n
(i)
∑∞
n=1
nlnnxn
2 n