a brief analysis of the geometric series
TRANSCRIPT
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1 A Brief Analysis Of The Geometric Series
A BriefAnalysis OfTheGeometricSeriesType 1 Mathematicalinvestigation
MD. Rakibur Rahman
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Introduction
A geometric series is essentially a sequence of real* numbers, where
each term after the first is found by multiplying the first term (t 1) by a non-zero
constant known as the common ratio (r).
For example: the sequence 2, 8, 32, 128, is a geometric sequence,
where the first term or t1 is 2, while the common ratio (r) is 4.
While the name first term is self explanatory, the common ratio is the
non-zero constant by which each receding term is multiplied by to obtain the
next. In our example, the common ratio is:
!
nd
2
st
2 t r 8= = 4
t r 2
t
t
Thus, in a more general manner, if the nth term is tn, then the previous
term is tn-1, then the common ratio or r:
1
n
n
trt
Now, the definition of a term of the geometric sequence is the first term
(t1 or a) multiplied by the common ratio to the power of the term number minus
one. To elaborate, for example: if the 1st term is 5, the common ratio is 2, then
the 4th term will be:
v v4
3
5 4 = 5 4 = 320
Again, in a more general manner, if the first term is a, the common ratio
is r, then the nth term or tn:
1 nn
t a r
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This leads us to conclude that the general geometric sequence must be
formulated as shown below:
2 3 , , , , ... , na a r a r a r a r
*Real numbers are defined as numbers that can be expressed using the real number system, and
thus excludes all imaginary and complex numbers
Sum of a geometric series
One of the most important, as well as useful applications/
functions of the geometric series is the sum of the series. If a geometric series is
defined as:
2 3 , , , , ... , na a r a r a r a r
Then the sum of the series or Sn of the first n number of terms is as follows:
!
2 3 + + ... + nn
S a a r a r a r a r
For example, 2, 8, 32, 128 is a geometric series. The sum of the first 4 terms of
the series is:
! 4
2 8 32 128 = 170S
Therefore, the sum of the first 4 terms of the given series is 170.
The sum of a geometric series is one of the most useful
applications of algebra used in our financial world. Interests, loans and
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compounding function calculations would not be possible without the use of
geometric sequences. Patterns across natural artifacts occur while following the
rules of a geometric sequence. In physics, rate of change of many functions
occur with respect to a geometric sequence. Chemical reactions at the ionic
levels occur according to a geometric approach. Biological micro-organisms
multiply and breed with respect to a geometric sequence. The importance of a
geometric sequence and the sum is essential to almost any field of education.
Derivation of the sum formula
Now, it is relatively simple to calculate the sum of the first 4
numbers, considering the fact only a few terms need to be taken into account
while calculating. However, when the sum of, for example, first 201 terms need to
be calculated, a more effective as well as efficient approach needs to be
considered. Algebra can be used to manipulate the general sequence to obtain a
more feasible equation.
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The sum of general geometric sequence is defined as:
!
2 3 1+ + ... + nn
S a a r a r a r a r
Now, the sum this geometric sequence can also be defined as:
1
1
n
b
n
b
S a r
Here, the sum of the equation1b
a r is found from when b = 1, which gives us a,
to when b = n, which gives us1n
a r .
Therefore,
!
!
!
1 2 3 1
1
1 2 3 1
1
= + + ... +
(1 ... ) ---- q ti n1
nb n
b
n
b n
b
a r a a r a r a r a r
a r a r r r r
Multiplying both sides by r in the second previous statement we get,
!
1 2 3 4
1
= + + ... +n
b n
b
r a r a r a r a r a r a r
Now, subtracting (n x a) from both sides gives us n number of as on each side,
therefore an a for each term in the series:
!
!
!
1 2 3 4
1
1 2 3 4
1
- ( ) = - + - + - ... +
- ( ) ( 1) ( 1) ( 1) ( 1) ... ( 1)
n
b n
b
n
b n
b
r a r n a a r a a r a r a r a r a
r a r n a a r a r a r a r a r
(continued on next page)
(continued from last page)
Now, factoring a on the right side we get,
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1 2
1
1 2
1
1 2
1
1 2
1
1 2
1
- ( ) ( 1 1 1 1 ... 1)
- ( ) ( ... )
( ... ) ( )
( ... )
( ... ) --
n
b n
b
n
b n
b
n
b n
b
n
b n
b
n
b n
b
r a r n a a r r r r r
r a r n a a r r r r r n
r a r a r r r r r n n a
r a r a r r r r r n n
r a r a r r r r r -- e ua tion 2
Now, subtracting equation 2 from equation 1 we get,
! !
! !
!
!
1 1 2 3 1 2 3 4
1 1
1 1 2 2 3 3 1 1
1 1
(1 ... ) - ( ... )
(1 ... ... )
n n
b b n n
b b
n n
b b n n n
b b
a r r a r a r r r r a r r r r r
a r r a r a r r r r r r r r r
We notice that all of the terms between 1 and rn cancels out, thus,
1 1
1 1
1
1
1
1
1
1
(1 )
(1-r) (1 )
(1 )
(1 )
( 1)
( 1)
n n
b b n
b b
n
b n
b
nn
b
b
nn
b
b
a r r a r a r
a r a r
a ra r
r
a ra r
r
Now we remember that
!
! 1
1
n
b
n
b
S a r (by definition)
Thereby giving us,
!
( 1)
( 1)
n
n
a rS
r
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In order to test the new equation, let us consider the geometric
series:
2, 4, 8, 16, 32 and 64
Now, the sum of the first 6 terms of the series by adding the terms manually is:
62 4 8 16 32 64 126S ! !
Now, the first term or a in this series is 2, while the common ratio is 2, and the
number of terms is 6. Using the formula:
6
6
( 1)
( 1)2(2 1)
1262 1
n
n
a rS
r
S
!
! !
The sum of the 6 terms given by the derived formula and the manual calculation
is equal.
Therefore, the derived formula is correct and can be used to
calculate the sum of a geometric series.
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Convergent geometric series
The simplest definition of a convergent geometric series is: A
geometric series whose sum of multiple terms converges, or approaches towards
a certain and real value. Now, convergent geometric series are unique and
therefore, have unique characteristics. There are certain circumstances under
which the sum of a geometric series tends to approach a certain value, or limit.
These circumstances are imposed upon the geometric series by two contributor,
the smaller being the first term or a, while the largest contributor is the common
ratio, or r.
The value of the first term does not have any significant effect on the converging
characteristics of the series. For our example, we will pick a to be equal to 2.
The value of the common ratio however, greatly contributes to the convergence
of the geometric series.
Fig. 1) Generic number line determined for convergence testing
-x -2 -1 -0.5
1
x
0 1
x
0.5 1 2 x
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In the number line of fig. 1, values ranging from and including x, -2, -1,
-0.5, 1
x, 0
1
x, 0.5, 1, 2 and x has been chosen. For the most obvious reasons,
0 is one of the primary choices made, as it separates positive values from
negative ones. 1 and -1 are also chosen here, because multiplication by the prior
does not change the value of the term, while the latter only causes sign change.
0.5 and -0.5 are two of the most generic and common fractions or decimal values
used in mathematics, while 1
xand
1
xrepresent general fractions, where { x >
1|x N}, or x is greater than 1, while being an element of the natural number
system. This allows to test all values up to 0 0}.
If the values of the Sn in table 2 are carefully observed, a pattern can be
observed. The Sn values 2, 4, 6, 8 represent an arithmetic sequence. In this
sequence, the first term (a) is 2, while the common difference (d) is:
! ! !2 1
4 2 2d t t
Therefore in this case, the Sn for the geometric sequence represents the tn for the
arithmetic sequence given above.
As we know for an arithmetic sequence:
At t1 = a and common ratio = r,
! ( 1)n
t a n d
In our case, a = 2 and d = 2;
!
!
!
2 ( 1)2
2 2 2
2
n
n
n
t n
t n
t n
Term numbertn for r = 1
(arn-1)
Sn(changes as n increases)
1 2 22 2 4
3 2 6
4 2 8
n 2 2n
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Table 2) Obtained values of tn and Sn for first term of 2 and common ratio of 1
Here, as n increases, 2n or Sn also increases. Thus, as n , 2n
as well. Therefore, at r = 1, the geometric sequence sum is divergent.
a = 2, r = 0.5
Following the method outlined on page 7, we get the values in table 3.
Term numbertn for r = 0.5
(arn-1)
Sn(changes as n increases)
( 1)
( 1)
na r
r
1 2 2
2 1 3
3 0.5 3.5
4 0.25 3.75
n 22n
2(2) 4n
Table 3) Obtained values of tn and Sn for first term of 2 and common ratio of 0.5
If we analyze the equation
2(2) n , we observe that as n ,
2(2) n 0. Therefore, as 2(2) n 0, 2(2) 4n 4 . Therefore, as the sum
of the geometric series is converging to a certain value, namely 4, we can
conclude that as r = 0.5, the geometric series is convergent.
a = 2, r = 0
Following the method outlined on page 7, we get the values in table 4. .
Term number
tn for r = 0
(arn-1)
Sn(changes as n increases)
( 1)( 1)
n
a r
r
1 2 2
2 0 2
3 0 2
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4 0 2
n 0 2
Table 4) Obtained values of tn and Sn for first term of 2 and common ratio of 0
We observe from the above table that as n, Sn=2.
Therefore, the sum of the geometric series converges to the value of the
first term, when the common ratio is 0. In other words, a common ratio of 0
results in a convergent geometric series.
a = 2, r = -2
Following the method outlined on page 7 for r = 2, we get the values in
table 5.
Term numbertn for r = -2
(arn-1)
Sn(changes as n increases)
( 1)
( 1)
na r
r
1 2 2
2 -4 -2
3 8 6
4 -16 -10
n ( 2)n 2 2
( )( 2)n
Table 5) Obtained values of tn and Sn for first term of 2 and common ratio of -2
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In2 2
( )( 2)n , as n , (-2) , therefore2 2
( )( 2)n .
Thus, as the common ratio of a geometric series is -2, the sum of the series is
not convergent (i.e. divergent).
a = 2, r = -1
Following the method outlined on page 8 for r =1, we get the values in
table 6 for r = -1 and a = 2.
Term numbertn for r = -1
(arn-1)
Sn(changes as n increases)
1 2 2
2 -2 0
3 2 2
4 -2 0
n 2 ( 1)nv 2 if n is odd, 0 if n is even
Table 6) Obtained values of tn and Sn for first term of 2 and common ratio of -1
We can see from the Sn values that as n increases, when n is an odd
number the sum is 2, while when n is odd the sum is 0. Thus, the sum oscillates
between 0 and 2. Therefore, it does not converge or diverge, and is therefore
neither convergent nor divergent.
a = 2, r = -0.5
Following the method outlined on page 9, we get the values in table 7.
Term numbertn for r = -0.5
(arn-1)
Sn(changes as n increases)
( 1)
( 1)
na r
r
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1 2 2
2 -1 1
3 0.5 1.5
4 -0.25 1.25
n1
4( )2
n
4 1 4( )
3 2 3
n
Table 7) Obtained values of tn and Sn for first term of 2 and common ratio of -0.5
If we analyze the equation4 1 4
( )2
n , we see that as n,
1( )
2
n
as well. Therefore, this leads to the conclusion that4 1
( )2
n , and thus
the sum of the series converges to4
3at larger values of n. Therefore, at r = -0.5,
the geometric series is convergent.
a = 2, r = x
Following the method outlined on page 7, we get the values in table 8 for
a = 2 and r = x.
Term numbertn for r = x
(arn-1)
Sn(changes as n increases)
( 1)
( 1)
na r
r
1 2 2
2 2x 2+2x
3 2x2 2+2x+2x2
4 2x3 2+2x+2x2+2x3
n 12xn 2 21
n
xx
Table 8) Obtained values of tn and Sn for first term of 2 and common ratio of x
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Here, we see that as the value of n approaches larger and larger values,
2 2
1
nx
x
, so does the value of xn. This is because { x > 1|x N}, and therefore
as the value of the exponent increases, so does the value of the positive natural
integer which is greater than 1. Therefore, as n ,2 2
1
nx
x
, for x, given {
x > 1|x N}. Therefore, the series is not convergent for given values of x at { x >
1|x N}.
a = 2, r = -x
Following the method outlined on page 7, we get the values in table 9 for
a = 2 and r = -x.
Term numbertn for r = -x
(arn-1)
Sn(changes as n increases)
( 1)
( 1)
na r
r
1 2 2
2 -2x 2-2x
3 2x2 2-2x+2x2
4 -2x3 2-2x+2x2-2x3
n12( )nx
2( ) 2
1
nx
x
Table 9) Obtained values of tn and Sn for first term of 2 and common ratio of -x
Analysis of the equation2( ) 2
1
nx
x
shows us that as n, (-x)n .
This is because when n is odd, the value of (-x)n becomes -xn, and after being
divided by the negative denominator, the sum approaches positive infinity. The
scenario is the opposite for when n is even, and thus the sum approaches
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negative infinity. However, this is insignificant, because for neither case the
geometric series converges to a certain value. Therefore, for a common ratio of
x, the geometric series is divergent*.
*Divergent stands for not convergent, or not converging towards a certain value.
a = 2, r =1
x
Following the method outline in the previous pages, we obtain the values
in table 10.
Term numbertn for r =
1
x
(arn-1)
Sn(changes as n increases)
( 1)
( 1)
na r
r
1 2 2
22
x2+
2
x
3 22x 2+ 2
x+
22x
4 32
x 2+
2
x+
2
2
x+
3
2
x
n112( )
n
x
12( ) 2
11
n
x
x
Table 10) Obtained values of tn and Sn for first term of 2 and common ratio of1
x
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In the equation,
12( ) 2
11
n
x
x
, as n , the value of (1
x)n0. This is because of
the fact that { x > 1|x N}. Thus, as (
1
x )n
0,
1
2( )n
x 0, and therefore
12( ) 2
11
n
x
x
2 2
1 1
1
xo r
x
x
. Therefore, as the common ratio of a geometric
series is1
x, the series will converge to
2
1
x
x
as n approaches infinity, given: { x
> 1|x N}.
a = 2, r = -1
x
Following the method outline in the previous pages, we obtain the values
in table 11.
Term numbertn for r = -
1
x
(arn-1)
Sn(changes as n increases)
( 1)
( 1)
na r
r
1 2 2
2 -2
x2-
2
x
3 22x 2- 2
x+
22
x
4 - 32
x 2-
2
x+
2
2
x-
3
2
x
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n112( )
n
x
12( ) 2
11
n
x
x
Table 11) Obtained values of tn and Sn for first term of 2 and common ratio of -
1
x
In the equation:
12( ) 2
11
n
x
x
, as n ,1
( )n
x 0. This is because as x
is greater than 1 and is a natural number and is in the denominator, as its
exponents value increases, then value of
1
x decreases. As the exponent
approaches ,1
x approaches zero. Therefore, the value of
12( )n
x
approaches zero. This also implies that
12( ) 2
11
n
x
x
2
1
x
x, as n.Therefore,
when1
x is the common ratio of a geometric series, the series tends to
converge to 21
xx
, given { x > 1|x N}.
Results
Now, to sum up our results, table 12 is constructed below.
Common ratio (r) Nature of geometric series
2 divergent
1 divergent
0.5 convergent
0 convergent
-2 divergent
-1 oscillatory
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-0.5 convergent
x divergent
-x divergent
1
x convergent
1
x convergent
Table 12) Analyzed common ratios and their respective geometric series nature
We notice from the above table that only 0, 0.5, -0.5,1
x and
1x
produce geometric series which are convergent. All other values of common
ratio produce divergent series.
Now, it had been previously specified that x > 1. This range
ensures that the value of1
xproduces a value which is less than 1. We notice
from our chart that when r is equal to 1, the series in no longer convergent, but
for values of r < 1; the series is convergent (i.e. at
1
x , 0, 0.5, -0.5 and
1
x ) up
to -1< r. Again, we notice that as r is equal to -1, the series is not convergent, but
for values of r > -1, the series is convergent. This leads us to conclude the range
of the acceptable r values on a number line (in fig. 2), in order to obtain a
convergent geometric series.
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Fig. 2) The range of usable common ratios in order to obtain a geometric series
From the above figure and analyzed data we can therefore conclude that,
in order for a convergent geometric series to form
-1 < r < 1
Or, the common ratio is greater than -1 and less than 1.
Derivation of infinite sum formula
Now, we understand that in order to calculate the sum of an infinitely
continuous geometric series, the series must be convergent. Also, we know that
in order for any geometric series to be convergent, the common ratio must be
greater than -1 and less than 1.
Here, by definition:
0
b
b
S a r
g
g
!
!
In other words, the sum of an infinite series is the sum of all values from
t1 to tb or tn (here b is used instead of n for future algebraic manipulation), where
the value of b approaches infinity.
Now,
-x -2 -1 -0.5
1
x
0 1
x
0.5 1 2 x
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0
0
li
b
b
n
b
nb
S a r
S a r
g
g
!
gpg
!
!
!
Slight algebraic manipulation shows us that the prior equation is equal to
the latter, because in both the sum of the equation approaches infinity. Only in
the second one, the value of b approaches n, while the value of n approaches
infinity (making both equations equal).
0
limn
b
nb
S a rg pg
!
!
Now by definition, we know that:
0
n
b
b
a r
!
= nS
Now,
If
!
( 1)
( 1)
n
n
a r
S r
Then,
0
n
b
b
a r
!
=( 1)
( 1)
na r
r
Thus substituting this in0
limn
b
nb
S a rg
pg!
! we get,
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(a cc ording to p rope rties of limits)
( 1)lim
( 1)
lim - lim( 1) ( 1)
lim lim( 1) ( 1)
n
n
n
n n
n
n n
a rS
r
a a rS
r r
a r aSr r
gpg
gpg pg
gpg pg
!
!
!
Now, we know that -1 < r < 1; thus when n , rn0. Thus, as rn 0,
( 1)
na r
r 0.
Thus,
(as the value of n d oes not have any effe ct o n this e uation, the limit ca n be removed )
0
- lim ( 1)
-( 1)
where -1
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2=
1 0.5
4=
3
S
S
g
g
Thus, as both algebraic manipulation and our derived formula gives us
the sum of infinity as4
3, we can verify the formula to be valid and usable in
future cases.
Interpretation of transformation for given equations
Visualization of an idea or fact is how human beings analyze critical data
as if it were simple. This is the function of a graph. Simply stated, a graph is
generally an equation plotted on multiple axes in order to represent the equation
visually, for critical analysis. Although this may be done using algebra and/or
limits, it is much easier to understand the equation visually first, and then
evaluate or confirm using algebra. We will analyze some equations now and later
interpret to how this relates to a geometric series.
Equation set 1
In the equation set 1:
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1
2
3
2 -- q ti n1
2 1 -- q ti n2
3(2 1) -- q ti n 3
x
x
x
y
y
y
!
!
!
Equation 1 undergoes a set of transformations in order to become equation 3.
Fig. 3) shows the three of these equations plotted on the same set of axis. Note
that these equations are drawn to represent the equations only, and not the
geometric series which they are meant to represent later on.
A ti-83 Plus graphing calculator may be used for plotting these graphs for
ease of analysis. The following range of variables may be used:
x: [0,9, 1]
y: [0, 12 , 1]
A screenshot* of the window is given as below:
*An artificially computer generated mod of the Ti-83+ was used via ROM dump
Now, the following graphs are plotted on y1, y2, y3 as shown:
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Now, we get the graph as given below (graph also included in fig. 3):
In general sense, a graphical transformation is when a set of changes
are made to an original equation in order to obtain a different and unique
equation. Let us consider the equation set 1 as listed above to discuss the
transformations applied there.
Referring to fig. 3), we see that Equation 1, which is1
2xy ! , is an exponential
curve which intersects the y-axis through the point (0,1). Now, the graph is
moved down (vertically translated) by 1 unit on the y-axis in order to obtain
equation 2. We can see this algebraically as well as equation 2 is 2 2 1xy ! ,
which is essentially 1 subtracted from equation 1. As we can observe in the figure,
equation 2 intersects the y axis at (0,0), which is 1 unit below the intersection of
equation 1.
Equation 3 is essentially equation 2 with a vertical stretch factor of 3. In
Lehmans terms, equation 3 has been stretched 3 units on a vertical aspect from
equation 2. This can be observed visually in figure 3, as well as mathematically,
as equation 3 is3
3(2 1)xy ! , which is basically 3 times 2 2 1xy ! .
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On a visual terrain:
1 2xy ! 2 2 1
xy ! 3
3(2 1)xy !
Equation set 2
Equation set 2 utilizes the same set of skills used in equation set 1.
Equation set 2:
1
2
3
1( ) -- e ua tion 1
2
1( ) 1 --e ua tion 22
13[( ) 1] --e ua tion 3
2
x
x
x
y
y
y
!
!
!
For equation set 2, the range of x and y are as follows:
x: [0, 9, 1)
y: [-3, 1, 1]
The window (which directly corresponds with the range) is as follows:
The graph obtained (also illustrated in fig. 4) is as follows:
Verticallytranslated by -1 unit Verticalstretch factorof 3 applied
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28 A Brief Analysis Of The Geometric Series
Referring to fig. 4, we observe that as x values approaches infinity, the y values
of the equations y1, y2, y3 respectively approach 0, -1 and -3.
From equation 1 or 11
( )2
xy ! , the equation 21
( ) 12
xy ! was
moved down 1 unit or vertically translated 1 unit down. The vertical asymptote for
equation 1, which is y = 0, was transformed into y = -1 for equation 2, which was
also vertically translated 1 unit down.
From equation 2 to 3, 21
( ) 12
xy ! or equation 2 was
transformed with a vertical stretch factor of 3 with respect to the y-axis. In this
case, the vertical asymptote was transformed from y =-1 to y = -3, which is a
vertical transformation with a stretch factor of 3 as well.
1
1( )
2
xy ! 21
( ) 12
xy ! 31
3[( ) 1]2
xy !
Equation set 3
Although equation set 3 looks very similar to equation set 2, it is
extremely different when we graph it.
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29 A Brief Analysis Of The Geometric Series
Equation set 3 is defined as follows:
1
2
3
1( )
2
1( ) 12
13[( ) 1]
2
x
x
x
y
y
y
!
!
!
We will be using the same windows as equation set 3 to graph this equation set.
After applying the values inside the calculator, we obtain the following graph:
This of course, from a direct perspective, signifies nothing but a
blank graph. However, if we look at it in an algebraic approach initially, and then
a graphical, we will understand the problem.
Our function consists of an exponential graph with a negative base.
Let us take 11
( )2
xy ! as an example. If for example, x was equal to natural
numbers 0, 1 and 2, the corresponding y values would be 1, -0.5 and 0.25
respectively, using simple substitution method.
Now, let us consider non-natural numbers such as1
2. Using the
real numbers system, 11
( )2
xy ! cannot be evaluated at x =1
2, since it
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30 A Brief Analysis Of The Geometric Series
consists of taking the second root of a negative number, which cannot be
accomplished without the use of complex numbers.
This means that using a real number system, equation set 3 cannot
be graphed continuously, which results in a discontinuous function. Of course,
this can be graphed continuously using polar co-ordinates on a three dimensional
plane, however since this increases the complexity of this report and is not
included in the International Baccalaureate Standard Level curriculum, we will not
be going into details here.
Therefore we can conclude that, using the real number co-
ordination graphing system, equation set 3, which essentially consists of
exponential equations with negative bases, is only defined at:
x:[x N]*
This is verified by using the trace function of the ti-83+ and placing
x values which only consist of the natural number system, thus giving us
responding y co-ordinates.
Now, graphing the defined points on the same window as equation
set 2 in fig. 5) shows us that the points on the graphs are transformed according
to the following measures:
1
1(- )
2
xy ! 21
(- ) 12
xy ! 31
3[(- ) 1]2
xy !
The equation set 3 has the same values for vertical asymptotes as set 2.
*Hint: Incidentally, the sum of a geometric series is also defined at n:[n N]; but we will be going into
details later!
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31 A Brief Analysis Of The Geometric Series
Equation set 4
Equation set 4 is, as discussed above, only defined at x:[x N].
Equation set 4 is defined as below:
1
2
3
( 2)
( 2) 1
3[( 2) 1]
x
x
x
y
y
y
!
!
!
Again, graphing on the ti-83+ does not provide any useful visual
information. Therefore, we will be using the same graphing method as used in fig.
5); i.e. by tracing the graph at x N, and then plotting the points in fig. 6).
Our two variables x and y will be defined as:
x: [x N|0, 3, 1]
y: [-12, 12, 1]
The equation set 4 has been transformed by the following
measures, as observations from figure 6 and algebraic characteristics dictate:
1 (-2)xy ! 2 (-2) 1
xy ! 3
3((-2) 1)xy !
The given equations do not approach or converge to a certain value,
but extend towards positive and negative infinity on both axes. Therefore, they do
not have any vertical or horizontal asymptotes.
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Rewriting final equation of set 1 in terms of Sum of geometric series formula
The final equation given in equation set 1 is 3y , where:
33(2 1)xy !
Now, our purpose is to rewrite this equation in terms of the equation derived for
the sum of the geometric series, or:
!
( 1)
( 1)
n
n
a rS
r
Now,
3
3
3(2 1)
1
3(2 1)
2 1
x
x
y
y
!
!
This resembles the arbitrary equation
!
( 1)
( 1)
n
n
a rS
r
Where, a = 3, r = 2, x = n,n
S = 3y .
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33 A Brief Analysis Of The Geometric Series
This allows us to conclude that equation 3 of equation set 1
represents the sum of a geometric series, where the variables are defined as a =
3, r = 2, x = n,n
S = 3y .
Now as we know, a geometric series is defined generally as follows:
2 3 1, , , , ... , na a r a r a r a r
In this case, we know that a = 3 and r = 2,
Thus the series represented by equation set 1s final equation is:
2 13,3 (2), 3 (2) ,..., 3 (2) n
Rewriting final equation of set 2 in terms of Sum of geometric series formula
The final equation given in equation set 2 is 3y , where:
3
13[( ) 1]
2
xy !
Using algebraic manipulation,
3
3
13[( ) 1]
21
-0. {3[( ) 1]}2
0.
x
x
y
y
!
!
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34 A Brief Analysis Of The Geometric Series
3
1-1.5[( ) 1]}
21
12
x
y
!
In terms of !
( 1)( 1)
n
n
a rSr
Where a = -1.5, r =1
2, x = n,
nS =
3y
This allows us to conclude that equation 3 of equation set 2 represents the sum
of a geometric series, where the variables are defined as
a = -1.5, r =1
2, x = n, nS = 3y .
Now as we know, a geometric series is defined generally as follows:
2 3 1, , , , ... , na a r a r a r a r
In this case, we know that a = -1.5 and r =1
2,
Thus the series represented by equation set 2s final equation is:
2 11 1 11. , 1. ( ), -1. ( ) ,..., -1. ( )2 2 2
n
Rewriting final equation of set 3 in terms of Sum of geometric series formula
The final equation given in equation set 3 is3
y , where:
3
13[(- ) 1]
2
xy !
Now,
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35 A Brief Analysis Of The Geometric Series
3
3
3
13[(- ) 1]
2
1-1.5{3[(- ) 1]}
21.5
1-4.5[(- ) 1]}
21
12
x
x
x
y
y
y
!
!
!
Which is in terms of
!
( 1)
( 1)
n
n
a rS
r
3
1Where a = -4.
, r= - , x = n and y2
nS!
Now as we know, a geometric series is defined generally as follows:
2 3 1, , , , ... , na a r a r a r a r
In this case, we know that a = -4.5 and r =1
2 ,
Thus the series represented by equation set 3s final equation is:
2 11 1 14. , 4. (- ), -4. (- ) ,..., -4. ( - )2 2 2
n
Rewriting final equation of set 4 in terms of Sum of geometric series formula
The final equation given in equation set 3 is3y , where:
33((-2) 1)xy !
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36 A Brief Analysis Of The Geometric Series
Here,
3
3
3
3((-2) 1)
-3{3((-2) 1)}
3-9((-2) 1)}
2 1
x
x
x
y
y
y
!
!
!
Which is in the form
!
( 1)
( 1)
n
n
a rS
r ,
3
!
r!
,"
#
, r 2,$
= n"
nd %
nS! ! !
Now as we know, a geometric series is defined generally as follows:
2 3 1, , , , ... , na a r a r a r a r
In this case, we know that a = -9 and r = -2,
Thus the series represented by equation set 4s final equation is:
2 19, 9 (-2), -9 (-2) ,..., -9 (-2) n
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37 A Brief Analysis Of The Geometric Series
Convergence and divergence of final equation in the 4 sets
To define convergence of a graph, it is essentially when as the x co-
ordinates increases or decreases infinitely, the y co-ordinates reach a certain,
real number value. For example, in the graph y = x2, as x approaches positive
infinity, the y-values also approach positive infinity. Therefore, y = x2 is not
convergent. While on the other hand, in the equation1
yx
! , as x approaches
positive infinity, y approaches 0. Therefore,1
yx
! is converging towards y = 0.
Convergence of final equation in set 1
The final equation in equation set 1 is defined as:
3 3(2 1)xy !
Which can be rewritten as,
3
3(2 1)
2 1
x
y
!
Thereby representing the geometric series
2 13,3 (2), 3 (2) ,..., 3 (2) n
Now if we look at 3 3(2 1)xy ! algebraically, as x approaches ,
3
3
3
li& li& 3(2 1)
li& li& 3(2) li& ( 3)
li& no t d e fine d , or'
(
lso (
) ) ro a c 0 es in finit'
x
x x
x
x x x
x
y
y
y
p g p g
p g p g p g
pg
!
!
!
We can observe this in fig. 3), where we see that as x-approaches infinity, y- also
approaches infinity.
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38 A Brief Analysis Of The Geometric Series
Now, in terms of the geometric sum formula, let us consider the
sequence:
2 13,3 (2), 3 (2) ,..., 3 (2) n
( 1)
( 1)
n
n
a rS
r
!
Here a = 3, r =2
3(2 1)
(2 1)
,
li1 li1 3(2 1)
li1 d o es no t e xist, ora p p ro a c 2 es p ositi3
e infinit4
.
n
n
n
nn n
nn
S
Now
S
S
p g p g
pg
!
!
In addition, if we try to apply our infinite geometric sum
formula:
= ere -1
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39 A Brief Analysis Of The Geometric Series
Convergence of final equation in set 2
3
13[( ) 1]
2
xy ! is the final equation in set 2, and represents the
geometric series,2 11 1 11. , 1. ( ), -1. ( ) ,..., -1. ( )
2 2 2
n
Observations from fig. 4) show us that as x approaches positive infinity,
the y-values approach -3.
Algebraically,
3
3
3
3
3
13[( ) 1]
21
lim lim 3[( ) 1]2
1lim 3 lim ( ) lim 3
2
lim 0 3
lim 3
x
x
x x
x
x x x
x
x
y
y
y
y
y
pg pg
pg pg pg
pg
pg
!
!
!
!
!
Thus, as x approaches positive infinity in 31
3[( ) 1]
2
xy ! , the y
values approach -3.
Using the geometric series2 11 1 11. , 1. ( ), -1. ( ) ,..., -1. ( )
2 2 2
n ,
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40 A Brief Analysis Of The Geometric Series
( 1)
( 1)
n
n
a rS
r
!
Where a = -1.5, r =1
2
1-1.5(( ) 1)
2
1( 1)
2
13( ) 3
2
1li5 3 li5 ( ) li 5 3
2
li5 0 3
li5 3
n
n
n
n
n
nn n n
n
n
nn
S
S
S
S
S
p g p g p g
pg
pg
!
!
!
!
!
Now, using the derived formula:
= where -1
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41 A Brief Analysis Of The Geometric Series
Convergence of final equation in set 3
3
13[(- ) 1]2
xy ! is the final equation in set 3, and we observe
that it is a discontinuous function, only defined at x:[x N]. This is also the same
scenario with its geometric series, where:
2 11 1 14.5, 4.5 (- ), -4.5 (- ) ,..., -4.5 (- )2 2 2
n , and n:[n N)
Algebraically,
3
3
3
3
13[(- ) 1]
2
1lim 3 lim(- ) lim 3
2
lim 0 3
lim 3
x
x
x x x
x
x
y
y
y
y
p g p g p g
pg
pg
!
!
!
!
Thus, as x approaches positive infinity, the y-values approach -3.
If we look at fig. 5) we observe that as the x co-ordinates approach
positive infinity, the y-values approach -3 as well.
In the geometric series,
2 11 1 14. , 4. (- ), -4. (- ) ,..., -4. (- )
2 2 2
n
The sum of the series represents the equation 31
3[(- ) 1]2
x
y !
Where,
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42 A Brief Analysis Of The Geometric Series
( 1)
( 1)
n
n
a rS
r
!
and a = -4.5, r=
1-
2
1-4.5[(- ) 1]
2
1( 1)
2
1li6 li6 {3[(- ) 1]}
2
1li6 3 li6 (- ) li 6 3
2
li6 3
n
n
n
nn n
n
nn n n
nn
S
S
S
S
p g p g
p g p g p g
pg
!
!
!
!
Therefore, as n approaches positive infinity, the sum of the geometric
series approaches -3.
If we examine the series using our infinite sum formula of,
= e re -1
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43 A Brief Analysis Of The Geometric Series
33((-2) 1)xy ! is the final equation in set 4, where the
geometric series represented by y3 is,
2 19, 9 (-2), -9 (-2) ,..., -9 (-2) n
Observations from fig. 6 shows us that as x- approaches positive infinity
in 3 3((-2) 1)x
y ! , the y values approach positive and negative infinity. Thus,
when x is an odd co=ordinate, the y values approach -, while when x is an even
co-ordinate, y values approach +.
Algebraically,
3
3
3
3((-2) 1)li 3 li ( 2) li 3
li d o es no t e xist, ora p p ro a c es
x
x
x x x
x
y
y
y
p g p g p g
pg
!
!
! s g
Using the geometric sum formula,
( 1)
( 1)
n
n
a rS
r
!
where a =-9 and r = -2,
-9((-2) 1)
( 2 1)
3(-2) 3
li 3 li (-2) li 3
li NE o ra p p ro a c es
n
n
n
n
n
nn n n
nn
S
S
S
S
pg pg pg
pg
s g
!
!
!
!
If we apply our infinite sum formula here,
= where -1
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44 A Brief Analysis Of The Geometric Series
Therefore, all methods of verification shows us that as
3 3((-2) 1)xy ! and its geometric series approaches positive infinity in terms
of x and n values, the responding y and Sn values do not converge to a specific
value, and is therefore divergent.
Observations
Let us consider 31
3[(- ) 1]2
xy ! in order to elaborate on our
observations, and come to a general conclusion between equations and their
respective geometric series.
The equation 31
3[(- ) 1]2
xy ! represents the geometric series:
2 11 1 14. , 4. (- ), -4. (- ) ,..., -4. (- )
2 2 2
n
Now, the initial observation made from the above equation, as well as the
other equation sets is that:
The base of the exponent, i.e.1
-2
in this case, represents the common
ratio value in its respective geometric series.
This can be verified using other equations in the sets as well.
The second observation that is made from this report is that,
The value of the first term, or a, is equal to the vertical stretch factor, i.e.
3 in this case, multiplied by the common ratio subtracted by 1.
In simpler terms: a = (vertical stretch factor) (common ratio -1)
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45 A Brief Analysis Of The Geometric Series
One can also conclude that,
a or t1 = (vertical stretch factor) (base of exponent -1) [as base of
exponent = common ratio]
The third, and most important observation made:
If the base of the exponent is less than 1 or greater than -1, then the
equation, as well as its sum of infinity of the geometric series, will converge to a
real value. On the other hand, if the base of the exponent is greater than 1 or less
than -1, then the equation as well as its sum of infinity will be divergent.
In general terms,
If zx is the given exponent in y = k(zx-1), Then:
if -1
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As the common ratio of a geometric sequence is given as:
-1