Post on 14-Aug-2020
Infinite Series
Definition. An infinite series is an expression of the form
Where the numbers uk are called the terms of the series.
1 2 3 (1)
1k k
u u u u uk
∞= + + + + +∑
=L L
Such an expression is meant to be the result of adding together infinitely many numbers. As with improper integrals, the above expression can sometimes be given a meaning and sometimes not.
Since it is physically impossible to add together an infinite number of terms, we must attempt to give expression (1) meaning through the idea of limit.
Since it is physically impossible to add together an infinite number of terms, we must attempt to give expression (1) meaning through the idea of limit.
Infinite series are used in ordinary arithmetic in the form of decimal expansions. For example when we write 2/3 = 0.6666666… we are expressing the idea that the infinite series
6 6 6 60.666 10 100 1000 10k
= + + + + +L L L
is somehow meaningful and has the value 2/3.
How might we give meaning to a series? One way is to begin by adding together all the terms of the series from term 1 to term n. The result is
1 2 31
kn nn
s u u u u uk
= + + + + = ∑=
L
and is called the nth partial sum of the series
1ku
k
∞∑=
We then focus attention on the sequence of partial sums
How might we give meaning to a series? One way is to begin by adding together all the terms of the series from term 1 to term n. The result is
1 2 31
kn nn
s u u u u uk
= + + + + = ∑=
L
and is called the nth partial sum of the series
1ku
k
∞∑=
We then focus attention on the sequence of partial sums
{ } 1 2 3
1 1 2 1 2 3 1 2
, , , , ,1
, , , , ,n
n
s s s ssn nu u u u u u u u u
∞ ==
= + + + + + +
K K
K L K
As n gets ever larger, the partial sum sn represents the sum of more and more terms of the series. Thus it is reasonable to think that if the sequence sn tends to a limit u (and therefore gets ever closer to u) the limit u is what we should mean by the sum of all the terms. Thus we are led to the following definition.
As n gets ever larger, the partial sum sn represents the sum of more and more terms of the series. Thus it is reasonable to think that if the sequence sn tends to a limit u (and therefore gets ever closer to u) the limit u is what we should mean by the sum of all the terms. Thus we are led to the following definition.
Definition. Suppose that is a series and that
is the corresponding sequence of partial sums. If the sequence
converges to a limit s, we say that the series
converges to s and that s is the sum of the series. If the sequence of partial sums diverges, we say the series diverges, and therefore has no sum.
{ } 1sn n∞
=1ku
k
∞∑=
{ } 1sn n∞
= 1ku
k
∞∑=
Example. Determine whether the series
converges or diverges, and if it converges, find its sum.1 1 1 1− + − +L
Example. Determine whether the series
converges or diverges, and if it converges, find its sum.1 1 1 1− + − +L
Solution. We see that s1 = 1, s2 = 0, s3 = 1, s4 = 0, …
Since this sequence oscillates between 0 and 1, it will not eventually get and stay close to any number, and so it has no limit.
Example. Determine whether the series
converges or diverges, and if it converges, find its sum.1 1 1 1− + − +L
Solution. We see that s1 = 1, s2 = 0, s3 = 1, s4 = 0, …
Since this sequence oscillates between 0 and 1, it will not eventually get and stay close to any number, and so it has no limit.
Thus the series does not converge and so has no sum.
1 1 1 1− + − +L
Without a formal definition, this sequence could, and did, cause controversy.
On one hand you can reason that the sum should be
On the other hand we could write the series as
The definition shows us that no meaning at all can be attached to the series.
( ) ( )1 1 1 1 0− + − + =L
( ) ( )1 1 1 1 1 1+ − + + − + + =L
Geometric Series
One special type of series occurs frequently and is easily handled. That is the series
This is called a geometric series, and r is called the ratio. Each term is multiplied by r to produce the next term.
2 3 =0
kka ar ar ar ar ark
∞+ + + + + ∑
=L L
Geometric Series
One special type of series occurs frequently and is easily handled. That is the series
This is called a geometric series, and r is called the ratio. Each term is multiplied by r to produce the next term.
2 3 =0
kka ar ar ar ar ark
∞+ + + + + ∑
=L L
Note here that we have begun the series with a subscript 0 rather than 1, and so started with the 0th term instead of the first term. Actually we can begin the series with any subscript, just as was the case with a sequence, but 0 and 1 are the most common starting points..
The geometric series is handled by a simple algebraic trick.
The nth partial sum of the series is 0
kark
∞∑=
2 3 nn
s a ar ar ar ar= + + + +L
The geometric series is handled by a simple algebraic trick.
The nth partial sum of the series is 0
kark
∞∑=
2 3 nn
s a ar ar ar ar= + + + +L
then 2 3 1n nn
rs ar ar ar ar ar += + + + +L and therefore
2 2 3 1
1 1
[ ](1 ).
n n nn n
n n
s rs a ar ar ar ar ar ar ar ara ar a r
+
+ +− =
− = + + + − + + + += −
L L
The geometric series is handled by a simple algebraic trick.
The nth partial sum of the series is 0
kark
∞∑=
2 3 nn
s a ar ar ar ar= + + + +L
then 2 3 1n nn
rs ar ar ar ar ar += + + + +L and therefore
2 2 3 1
1 1
[ ](1 ).
n n nn n
n n
s rs a ar ar ar ar ar ar ar ara ar a r
+
+ +− =
− = + + + − + + + += −
L L
We have if
(it is easily seen that the series diverges if r = 1 or r = −1 )
11 1
n
nrs a
r
+ −= −
1r≠
If |r| > 1, sn does not converge. If |r| < 1, sn does converge since powers of r tend to 0. We therefore have
If |r| > 1, sn does not converge. If |r| < 1, sn does converge since powers of r tend to 0. We therefore have
If |r| ≥ 1, the series diverges. If |r| < 1, the series does converge and
Therefore s is the sum of the series.
0
kark
∞∑=
11lim lim .1 1
n
nr as s a
r rn n
+ −= = = − −→∞ →∞
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
2 3 4 52 2 2 2 8 16 323 3 3 3 27 81 2431
k
k
+∞ = + + + = + + +∑ =
L L
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
2 3 4 52 2 2 2 8 16 323 3 3 3 27 81 2431
k
k
+∞ = + + + = + + +∑ =
L L
Solution. This is a geometric series, since each term is multiplied by 2/3 to get the next. We have a = 8/27 and r = 2/3. Since the ratio has absolute value less than 1, the series converges to
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
2 3 4 52 2 2 2 8 16 323 3 3 3 27 81 2431
k
k
+∞ = + + + = + + +∑ =
L L
Solution. This is a geometric series, since each term is multiplied by 2/3 to get the next. We have a = 8/27 and r = 2/3. Since the ratio has absolute value less than 1, the series converges to
8827
21 913
ar= =
− −
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
1 2 3 43 3 3 3 9 27 812 2 2 2 4 8 161
k
k
+∞ − = − + − + − + = − + −∑ =L L
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
1 2 3 43 3 3 3 9 27 812 2 2 2 4 8 161
k
k
+∞ − = − + − + − + = − + −∑ =L L
Solution. This is a geometric series, since each term is multiplied by 2/3 to get the next. We have a = 9/4 and r = −3/2. Since the ratio has absolute value greater than 1, the series diverges.
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
1 4 5 6
5
ke e e e
k π π π π
−∞ = + + +∑ =L
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
1 4 5 6
5
ke e e e
k π π π π
−∞ = + + +∑ =L
Solution. This is a geometric series, since each term is multiplied by e/π to get the next. We have a = e4/ π4 and r = e/π. Since the ratio has absolute value less than 1, the series converges to
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
1 4 5 6
5
ke e e e
k π π π π
−∞ = + + +∑ =L
Solution. This is a geometric series, since each term is multiplied by e/π to get the next. We have a = e4/ π4 and r = e/π. Since the ratio has absolute value less than 1, the series converges to
4 4 4
4 4 31 .
1 ( ) ( )1
a e e eer e e
πππ π π π
π
= = =− − −−
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
3 1 6255 7 771 1
kk k
k k
−∞ ∞ =∑ ∑ = =
Example. Determine whether the series
converges or diverges, and if it converges determine the sum.
3 1 6255 7 771 1
kk k
k k
−∞ ∞ =∑ ∑ = =
Solution. This is a geometric series, since each term is multiplied by the ratio 625/7 to get the next. Since the ratio has absolute value greater than 1, the series diverges.
Every decimal that eventually repeats a string of digits endlessly is said to be repeating. Every rational number can be expressed as a repeating decimal, and conversely every repeating decimal converges to a rational number. Examples of repeating decimals are.
Every decimal that eventually repeats a string of digits endlessly is said to be repeating. Every rational number can be expressed as a repeating decimal, and conversely every repeating decimal converges to a rational number. Examples of repeating decimals are.
.333333333… 2.4566666666666…
12.472345345345345… .00131513151315…
0.5555555… 0.9999999…
Problem. Find the rational number that is the sum of the repeating decimal
1.333333333…
Problem. Find the rational number that is the sum of the repeating decimal
1.333333333…
Solution. This decimal is the same as the infinite series
3 13 3 31 =1+10 1010 100 1000 0
k
k
∞ + + + ∑ =L
Problem. Find the rational number that is the sum of the repeating decimal
1.333333333…
Solution. This decimal is the same as the infinite series
3 13 3 31 =1+10 1010 100 1000 0
k
k
∞ + + + ∑ =L
The series that follows the 1 is geometric with ratio 1/10. Thusit converges to the number 3
1101 31
10
=−
Problem. Find the rational number that is the sum of the repeating decimal
1.333333333…
Solution. This decimal is the same as the infinite series
3 13 3 31 =1+10 1010 100 1000 0
k
k
∞ + + + ∑ =L
The series that follows the 1 is geometric with ratio 1/10. Thusit converges to the number 3
1101 31
10
=−
The decimal therefore represents 4/3.
Problem. Find the rational number that is the sum of the repeating decimal
.99999…
Problem. Find the rational number that is the sum of the repeating decimal
.99999…
Solution. This decimal is the same as the infinite series
9 19 9 9 =10 1010 100 1000 0
k
k
∞ + + ∑ =L
Problem. Find the rational number that is the sum of the repeating decimal
.99999…
Solution. This decimal is the same as the infinite series
9 19 9 9 =10 1010 100 1000 0
k
k
∞ + + ∑ =L
The series is geometric with ratio 1/10. Thus it converges to the number 9
10 111
10
=−
Problem. Find the rational number that is the sum of the repeating decimal
.99999…
Solution. This decimal is the same as the infinite series
9 19 9 9 =10 1010 100 1000 0
k
k
∞ + + ∑ =L
The series is geometric with ratio 1/10. Thus it converges to the number 9
10 111
10
=−
The decimal therefore represents 1.
Problem. Find the rational number that is the sum of the repeating decimal
0.159159159…
Problem. Find the rational number that is the sum of the repeating decimal
0.159159159…
Solution. This decimal is the same as the infinite series
159 1159 159 159 = 3 33 6 9 10 1010 10 10 0
k
k
∞ + + ∑
=L
Problem. Find the rational number that is the sum of the repeating decimal
0.159159159…
Solution. This decimal is the same as the infinite series
159 1159 159 159 = 3 33 6 9 10 1010 10 10 0
k
k
∞ + + ∑
=L
The series is geometric with ratio 1/1000. Thus it converges to the number 159
15910001 9991
1000
= −
Problem. Find the rational number that is the sum of the repeating decimal
0.159159159…
Solution. This decimal is the same as the infinite series
159 1159 159 159 = 3 33 6 9 10 1010 10 10 0
k
k
∞ + + ∑
=L
The series is geometric with ratio 1/1000. Thus it converges to the number 159
15910001 9991
1000
= −
The decimal therefore represents 159/999.
Problem. Find the rational number that is the sum of the repeating decimal
0.212121…
Problem. Find the rational number that is the sum of the repeating decimal
0.212121…
Solution. This decimal is the same as the infinite series
21 121 21 21 = 2 22 4 6 10 1010 10 10 0
k
k
∞ + + ∑
=L
Problem. Find the rational number that is the sum of the repeating decimal
0.212121…
Solution. This decimal is the same as the infinite series
21 121 21 21 = 2 22 4 6 10 1010 10 10 0
k
k
∞ + + ∑
=L
The series is geometric with ratio 1/1000. Thus it converges to the number 21
211001 991
100
= −
Problem. Find the rational number that is the sum of the repeating decimal
0.212121…
Solution. This decimal is the same as the infinite series
21 121 21 21 = 2 22 4 6 10 1010 10 10 0
k
k
∞ + + ∑
=L
The series is geometric with ratio 1/1000. Thus it converges to the number 21
211001 991
100
= −
The decimal therefore represents 21/99.
For most series, we will try to determine convergence or divergence, but we will not be able to find the sum. The geometric series is one exception. Another is the so calledtelescoping series. The following example illustrates this case.
For most series, we will try to determine convergence or divergence, but we will not be able to find the sum. The geometric series is one exception. Another is the so calledtelescoping series. The following example illustrates this case.
Example. Find the sum of the series
1 1 1 1 11 2 2 3 3 4 4 5 1k k
+ + + + + +⋅ ⋅ ⋅ ⋅ ⋅ +
L L
For most series, we will try to determine convergence or divergence, but we will not be able to find the sum. The geometric series is one exception. Another is the so calledtelescoping series. The following example illustrates this case.
Example. Find the sum of the series
1 1 1 1 11 2 2 3 3 4 4 5 1k k
+ + + + + +⋅ ⋅ ⋅ ⋅ ⋅ +
L L
Solution. The technique of partial fractions shows that
1 11( 1)1 k kk k
= − +⋅ +
Thus we can rewrite the nth partial sum of the series as
1 1 1 1 1 1 11 1 1 12 2 3 3 4 11 2 2 3 1
1 11 1
ns
n nn nn
n n
= + + + = − + − + − + + − +⋅ ⋅ ⋅ + = − =
+ +
L L
Thus we can rewrite the nth partial sum of the series as
1 1 1 1 1 1 11 1 1 12 2 3 3 4 11 2 2 3 1
1 11 1
ns
n nn nn
n n
= + + + = − + − + − + + − +⋅ ⋅ ⋅ + = − =
+ +
L L
Then solim 1snn
=→∞
11 1 1 1 1 111 2 2 3 3 4 4 5 1 1k kk k k
∞+ + + + + + = =∑ ⋅ +⋅ ⋅ ⋅ ⋅ ⋅ + =
L L
Once it was believed that if the terms of a series tended to 0, then the series converged. This is false, as the following example shows.
Once it was believed that if the terms of a series tended to 0, then the series converged. This is false, as the following example shows.
1 1 1 112 3 41kk
∞= + + + + =∞∑
=L
Once it was believed that if the terms of a series tended to 0, then the series converged. This is false, as the following example shows.
1 1 1 112 3 41kk
∞= + + + + =∞∑
=L
1 1 11 12 2 2 2
s = + > + = 1 1 1 1 34 2 23 4 4 4 2
s s s= + + > + + >
1 1 1 1 1 1 1 1 48 4 45 6 7 8 8 8 8 8 2
s s s= + + + + > + + + + >
Once it was believed that if the terms of a series tended to 0, then the series converged. This is false, as the following example shows.
1 1 1 112 3 41kk
∞= + + + + =∞∑
=L
1 1 11 12 2 2 2
s = + > + = 1 1 1 1 34 2 23 4 4 4 2
s s s= + + > + + >
1 1 1 1 1 1 1 1 48 4 45 6 7 8 8 8 8 8 2
s s s= + + + + > + + + + >
and in general2
1.2n
ns +>16
52
s >
Once it was believed that if the terms of a series tended to 0, then the series converged. This is false, as the following example shows.
1 1 1 112 3 41kk
∞= + + + + =∞∑
=L
1 1 11 12 2 2 2
s = + > + = 1 1 1 1 34 2 23 4 4 4 2
s s s= + + > + + >
1 1 1 1 1 1 1 1 48 4 45 6 7 8 8 8 8 8 2
s s s= + + + + > + + + + >
and in general2
1.2n
ns +>16
52
s >
On the other hand, ( ) 11 1 1 112 3 41
k
kk
+∞ −= − + − +∑
=L converges.
Problem. Find all values of x for which the series
converges, and find the sum of the series for those values of x.
2 3( 3) 1 ( 3) ( 3) ( 3)0
kx x x xk
∞− = + − + − + − +∑
=L
Problem. Find all values of x for which the series
converges, and find the sum of the series for those values of x.
2 3( 3) 1 ( 3) ( 3) ( 3)0
kx x x xk
∞− = + − + − + − +∑
=L
The series is geometric, and the ratio is x − 3. Thus we know that it converges when | x − 3 | < 1. This is when
1 3 1 or 2 4.x x− < − < < <
Problem. Find all values of x for which the series
converges, and find the sum of the series for those values of x.
2 3( 3) 1 ( 3) ( 3) ( 3)0
kx x x xk
∞− = + − + − + − +∑
=L
The series is geometric, and the ratio is x − 3. Thus we know that it converges when | x − 3 | < 1. This is when
1 3 1 or 2 4.x x− < − < < <
When it converges, it converges to 1 11 ( 3) 4x x
=− − −
Problem. Find all values of x for which the series
converges, and find the sum of the series for those values of x.
3 3 9 272 31
kk xx x xk
∞ = + + +∑ =
L
Problem. Find all values of x for which the series
converges, and find the sum of the series for those values of x.
3 3 9 272 31
kk xx x xk
∞ = + + +∑ =
L
The series is geometric, and the ratio is 3/x. Thus we know that it converges when | 3/x | < 1. This is when
31 1.x
− < < This happens when x/3 > 1 or x/3 < −1, or
when x > 3 or x < −3.
Problem. Find all values of x for which the series
converges, and find the sum of the series for those values of x.
3 3 9 272 31
kk xx x xk
∞ = + + +∑ =
L
The series is geometric, and the ratio is 3/x. Thus we know that it converges when | 3/x | < 1. This is when
31 1.x
− < <
When it converges, it converges to 3
33 31
xx
x
=−−
This happens when x/3 > 1 or x/3 < −1, or
when x > 3 or x < −3.