276 CHAPTER 5 Series and Differential Equations
(c)
∑∞
n=1
n^2
√
n^7 + 2n
(d)
∑∞
n=0
n^2 + 2n
3 n
(e)
∑∞
n=0
(n+ 1)3n
n!
(f)
∑∞
n=1
2 n
nn
(g)
∑∞
n=1
n!
nn
(h)
∑∞
n=1
(^1
1 +^1 n
)n
- As we have already seen, the series
∑∞
n=1
1
n^2
, converges. In fact, it is
known that
∑∞
n=1
1
n^2
=
π^2
6
; a sketch of Euler’s proof is given on page
228 of the Haese-Harris textbook.^11 Using this fact, argue that
∑∞
n=0
1
(2n+ 1)^2
=
π^2
8
.
- Prove thesinusoidal p-series test, namely that
∑∞
n=1
sin
(
2 π
np
)
converges ifp > 1 ,
diverges ifp≤ 1.
(Of course, the 2πcan be replaced by any constant. Exercise 2 on
page 256 is, of course, relevant here!)
- Recall Euler’sφ-functionφ(see page 63). Determine the behavior
of the series
∑∞
n=1
1
nφ(n)
.(See Exercise 16d on page 64.)
- How about
∑∞
n=1
φ(n)
n^2
?
- Let F 0 , F 1 , F 2 , ... be the terms of the Fibonacci sequence (see
page 93). Show that
∑∞
n=0
Fn
2 n
converges and compute this sum ex-
plicitly. (Hint: you’ll probably need to work through Exercise 7
on page 106 first.)
(^11) Peter Blythe, Peter Joseph, Paul Urban, David Martin, Robert Haese, and Michael Haese,
Mathematics for the international student; Mathematics HL (Options), Haese and
Harris Publications, 2005, Adelaide, ISBN 1 876543 33 7