110 Chapter 2 • Sequences
Therefore, Xnk ---+ L.
Part 2 ( {::::): Exercise 3. •Example 2.6.9 Find lim (1 +
2
1
) n
n---+cx::i nSolution: By writing out the first few terms of the sequence, we have(^1 + 2 ~)^1 , (1 + ~) 4 '^2 (1 + ~) 6 ,^3 (1 + ~) 8 4 , (1 + ~) 10 5 ' ....
We can rewrite these terms as(
1 )10
1+-
10Thus, { ( 1 +
2
~ n is a suOOequence of { J ( 1+ ff} Hence,lim (1 + 2-)n = lim J(1 + .!.)n =
n->oo 2n n->oo nlim (1 + .!.)n = yle. D
n->oo nCorollary 2.6.10 (Application to Proving Divergence)
(a) If a sequence has two subsequences that converge to different limits,
then it diverges.
(b) If a sequence has a divergent subsequence, then it diverges.
Examples 2.6.11 The following sequences diverge:
{
(a) The sequence 1+(-l)n}.
2= {O, 1, 0, 1, 0, 1, 0, 1, 0, 1, · · ·} diverges. It
has a subsequence {O, 0, 0, · · ·} converging to 0, and a subsequence {1, 1, 1, · · ·}
converging to l.
{
(b) The sequence l,l,2,^1 1 1 1 1}
2
, 3,
3
,4,
4
,5,
5, ... ,n,;,, ... diverges. It has
a subsequence {1, 2, 3, 4, 5, · · ·} that diverges. D
Theorem 2.6.12 (a) A sequence diverges to +oo {::} every subsequence di-
verges to +oo.
(b) A sequence diverges to -oo {::} every subsequence diverges to -oo.