Advanced High-School Mathematics

(Tina Meador) #1

SECTION 5.2 Numerical Series 273


the same behavior as the improper integral


∫∞
1

dx
xp

. But, wherep 6 = 1,


we have


∫∞
1

dx
xp

=

x^1 −p
1 −p

∣∣
∣∣


1

=





1
p− 1 ifp >^1
∞ ifp < 1.

We already know that


∑∞
n=1

1

n

diverges, so we’re done!

The p-Test works very well in conjunction with theLimit Com-
parison Test. The following two examples might help.


Example 5.


∑∞
n=1

n^2 + 2n+ 3
n^7 /^2

converges. We compare it with the series
∑∞

n=1


1

n^3 /^2

, which, by thep-test converges:

nlim→∞

Ñ
n^2 + 2n+ 3
n^7 /^2

é

(
1
n^3 /^2

) = limn→∞n

(^2) + 2n+ 3
n^2


= 1,

proving convergence.


Example 6.


∑∞
n=1

n^2 + 2n+ 3
n^7 /^3
diverges. We compare it with the series
∑∞

n=1


1

√ (^3) n, which, by thep-test diverges:
nlim→∞
Ñ
n^2 + 2n+ 3
n^7 /^3
é
Ñ
1
√ (^3) n
é = limn→∞n
(^2) + 2n+ 3
n^2


= 1,

proving divergence.


There is one more very useful test, one which works particularly
well with expressions containing exponentials and/or factorials. This
method is based on the fact that if|r|<1, then the infinite geometric

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