Show:
World Series
P-lease tell me this converges...
A Series of Fortunate Comparisons
One Step Forward,
One Step Back
Rooting out Convergence
100

True or False: 1 - 1/2 + 1/3 - 1/4 + 1/5 + ... is a series

True or False: -1, 2, -3, 4, -5, ... is a series

True or False: If

lim_(n->oo) a_n = 0

 , then

sum_(n=1)^oo a_n

  is convergent.

True, because we are adding the terms, it is a series.

False, because we are only listing the terms, it is a sequence. 

False, because taking the limit of 

a_n

is the Divergence Test and if that limit = 0, the test is inconclusive and you'll need to try something else! 

100

In order to determine whether a series converges or diverges, what are the three conditions needed to use the Integral Test? How do you check these conditions? 

1. Continuous: check that

f(x)

 is defined for all values of x we care about (ex: seeing that the denominator never equals 0)

2. Positive: check that

f(x)

 is never negative for all values of x we care about

3. Decreasing: find

f'(x)

 and show that  

f'(x)<0

for all values of x we care about, OR show that

a_(n+1) \leq a_n

 is true for all values of n we care about

100

What is the difference between 

the Direct Comparison Test 

and 

the Limit Comparison Test? 


State both. 

Suppose that

sum a_n

 and

sum b_n

 are series with positive terms. 

Direct Comparison Test: 

(1) If

sum b_n

 is convergent and  

a_n leq b_n

 for all n, then

sum a_n

  is also convergent.

(2) If

sum b_n

 is divergent and

a_n geq b_n

 for all n, then  

sum a_n

is also divergent. 

Limit Comparison Test: 

If

lim_(n->oo) (a_n)/b_n = c

where

c>0

and is a finite number, then either both series converge or diverge. 

100

What is the Alternating Series Test? 

If the alternating series 

sum_(n=1)^oo (-1)^(n-1)b_n = b_1 - b_2 + b_3 - b_4 + ...

satisfies (1)

b_n

 is decreasing for all n and (2)

lim_(n->oo) b_n = 0

 then the series is convergent. 

100

What is the Ratio Test? What is the Root Test? 

Ratio test:

lim_(n->oo) |(a_(n+1))/a_n | = L

If L < 1, absolutely convergent

If L > 1, divergent

If L = 1, inconclusive

lim_(n->oo) root(n)(|a_n|) = L

(Same L cases as Ratio)

200

Determine whether the following series converges or diverges (state what test you used). 

sum_(n=1)^oo (2n)/(3n+1)

Since 

lim_(n->oo) (2n)/(3n+1) = 2/3 != 0 

the series diverges by the Divergence Test. 

200

Determine whether the following series is convergent or divergent:

sum_(n=1)^oo 3/n^(5/3)

Convergent p-series, p=5/3 > 1

200

Determine whether the series converges or diverges: 

sum_(n=1)^oo (9^n)/(3+10^n)

Notice that

9^n/(3+10^n) < 9^n/10^n = (9/10)^n

 for all

n geq 1

Since

sum_(n=1)^oo (9/10)^n

is a convergent geometric series,

sum_(n=1)^oo 9^n/(3+10^n)

 converges by the Direct Comparison Test. 

200

Test the series for convergence or divergence: 

2/3-2/5+2/7-2/9+2/11-...

First note that the series can be written as 

sum_(n=1)^oo (-1)^(n+1) 2/(2n+1).

Then notice that

b_n = 2/(2n+1) > 0

and

f'(x) = -4/(2x+1)^2 <0

so

{b_n}

 is decreasing and

lim_(n->oo) 2/(2n+1) = 0

Then by the Alternating Series Test, the series converges. 

200

Determine if the series is convergent or divergent:

sum_(n=2)^oo ((-1)^(n-1))/(ln n)^n

Ratio Test: 

lim_(n->oo) root(n)((1/ln n)^n) = 0

Since L<1, the series is absolutely convergent, so it converges. 

300

Determine whether the series is convergent or divergent. If it is convergent, find its sum. 

sum_(n=1)^oo 3^(n+1) 4^(-n)

Since the series can be rewritten as 

3 sum_(n=1)^oo (3/4)^n

we notice that it is geometric, and since |r|<1, the series converges to 

(9/4)/(1-3/4) = 9


300

Use the Integral Test (listing the 3 conditions) to determine whether the series is convergent or divergent: 

sum_(n=1)^oo 2/(5n-1)

The function

f(x)=2/(5x-1)

 is continuous, positive and decreasing on

[1,oo)

 so we can use the Integral Test. 

Since the improper integral is divergent, the series  is also divergent by the Integral Test. 

300

Determine whether the series converges or diverges:

sum_(n=1)^oo 1/(sqrt(n^2+1))

Note that we can compare the series with

sum_(n=1)^oo 1/n

 so, using the Limit Comparison Test, we have that

lim_(n->oo) (1/sqrt(n^2+1))/(1/n) = 1 > 0.

Since the harmonic series diverges, so does 

sum_(n=1)^oo 1/sqrt(n^2+1)

300

Test the series for convergence or divergence: 

sum_(n=1)^oo (-1)^(n+1) n^2/(n^3+4)

Since

n^2/(n^3+4) > 0

 for

n geq 1

and

n^2/(n^3+4)

 is decreasing since

f'(x) = (x(8-x^3))/(x^3+4)^2

for

x>2

. Note also that

lim_(n->oo) (n^2)/(n^3+4) = 0

. Thus the series converges by the Alternating Series Test.

300

Determine if the series converges or diverges

sum_(n=1)^oo (10^n)/((n+1)4^(2n+1))

Ratio Test:

lim_(n->oo) (5n+5)/(8n+6) = 5/8

Since L<1, the series absolutely converges, so it always converges. 

400

Determine whether the following series is convergent or divergent. If convergent, find its sum: 

sum_(n=1)^oo (2^(n))/6^(n-1)

After rewriting the series like the following: 

6 sum_(n=1)^oo (2/6)^n

we notice that it is geometric and that because |r| > 1, the series diverges. 

400

Determine whether the series is convergent or divergent: 

sum_(n=2)^oo 1/(n ln(n))

Because

f(x)

 is continuous, positive and decreasing on

[2,oo)

 we can use the Integral Test. 

Since the improper integral diverges, the series must also diverge by the Integral Test. 

400

Determine whether the series converges or diverges:

sum_(n=1)^oo (n+1)/(n^3+n)

Using the Limit Comparison Test, we note that we can compare our series with

1/n^2

. Since we know that

lim_(n->oo) (n^2(n+1))/(n(n^2+1)) = 1 > 0

and

sum_(n=1)^oo 1/n^2

 is a convergent p-series, the series

sum_(n=1)^oo (n+1)/(n^3+n)

 also converges. 

400

Test the series for convergence or divergence:

sum_(n=1)^oo (-1)^(n+1) e^(2/n)

Notice that

lim_(n->oo) e^(2/n) = e^0 = 1

, so

lim_(n->oo) (-1)^(n-1)e^(2/n)

 does not exist. Therefore

sum_(n=1)^oo (-1)^(n-1)e^(2/n)

 diverges by the Divergence Test. 

400

Determine whether the series converges or diverges: 

sum_(n=1)^oo (n^10)/((-10)^(n+1))

Ratio Test: 

lim_(n->oo) 1/10 (1+1/n)^n = 1/10

Since L<1, the series absolutely converges, so it always converges. 

500

Determine whether the series is convergent or divergent by expressing 

sum_(n=1)^oo 3/(n(n+3))

as a telescoping sum. If it is convergent, find its sum. 

The series converges and its sum is 

11/6

500

Determine whether the following series is convergent or divergent:

sum_(n=1)^oo (sqrt(n)+4)/n^2

Since the series can be rewritten as 

sum_(n=1)^oo (sqrt(n)+4)/n^2 = sum_(n=1)^oo 1/(n^(3/2)) + 4sum_(n=1)^oo 1/n^2

we know that both series are convergent p-series. Therefore the sum of two convergent series must also converge. 

500

Determine whether the series converges or diverges: 

sum_(n=1)^oo (e^n+1)/(n e^n+1)

The series diverges - both DCT and LCT work here by comparing to harmonic series 

sum_(n=1)^oo 1/n

500

Test the series for convergence or divergence: 

sum_(n=1)^oo (-1)^(n-1) arctan(n)

Since

lim_(n->oo) arctan(n) = pi/2

 , so

lim_(n->oo) (-1)^(n-1) arctan(n)

 does not exist. Therefore the series

sum_(n=1)^oo (-1)^(n-1) arctan(n)

 diverges by the Divergence Test. 

500

Determine if the series converges or diverges

sum_(n=1)^oo (npi^n)/((-3)^(n-1))

Ratio Test:

lim_(n->oo) pi/3 (1+1/n) = pi/3

Since L>1, the series diverges.