Advanced High-School Mathematics

(Tina Meador) #1

SECTION 5.2 Numerical Series 279


series (do this!). However, the terms decrease and tend to zero and so


by theAlternating Series Test


∑∞
n=0

(−1)nn
n^2 + 1

converges.

Exercises



  1. Test each of the series below for convergence.


(a)

∑∞
n=1

(−1)n

n+ 2
n^2 + 10n

(b)

∑∞
n=2

(−1)n
lnn

(c)

∑∞
n=1

(−1)n

lnn
ln(n^3 + 1)

(d)

∑∞
n=1

( 1

n


1

n^2

)

(e)

∑∞
n=2

(−1)n
ln lnn
lnn

(f)

∑∞
n=1

((−1)n
1 +^1 n

)n

(g)

∑∞
n=1

(−1)n

n+


n+ 1

(h)

∑∞
n=1

(−2)n
n!


  1. Determine whether each of the series above convergescondition-
    ally, convergesabsolutelyor diverges.

  2. Prove that the series the improper integral


∫∞
−∞

sinx
x

dxconverges.^14


  1. Prove that the improper integral


∫∞
0 cosx

(^2) dxconverges. (^15) (Hint:
try the substitutionu=x^2 and see if you can apply the Alternating
Series Test.)



  1. Consider the infinite series


∑∞
n=0

n
2 n

, where eachnis±1. Show that
any real number x, − 2 ≤ x ≤ 2 can be represented by such a
series by considering the steps below:

(a) Write Σ =

∑∞
n=0

n
2 n

= Σ+−Σ−, where Σ+ is the sum of the
positive terms in Σ and where Σ−is−(negative terms in Σ).

(^14) In fact, it converges toπ.
(^15) This can be shown to converge to^1
2
...π
2.

Free download pdf