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If a sequence is geometric there are ways to find the sum of the first n terms, denoted Sn, without actually adding all of the terms.
To find the sum of the first Sn terms of a geometric sequence use the formula
Sn=a1(1−rn)1−r,r≠1,
where n is the number of terms, a1 is the first term and r is the common ratio.
Example 1:
Find the sum of the first 8 terms of the geometric series if a1=1 and r=2.
S8=1(1−28)1−2=255
Example 2:
Find S10 of the geometric sequence 24,12,6,⋯.
First, find r.
r=r2r1=1224=12
Now, find the sum:
S10=24(1−(12)10)1−12=306964
Example 3:
Evaluate.
∑n=1103(−2)n−1
(You are finding S10 for the series 3−6+12−24+⋯, whose common ratio is −2.)
Sn=a1(1−rn)1−rS10=3[1−(−2)10]1−(−2)=3(1−1024)3=−1023
In order for an infinite geometric series to have a sum, the common ratio r must be between −1 and 1. Then as n increases, rn gets closer and closer to 0. To find the sum of an infinite geometric series having ratios with an absolute value less than one, use the formula, S=a11−r, where a1 is the first term and r is the common ratio.
Example 4:
Find the sum of the infinite geometric sequence
27,18,12,8,⋯.
First find r:
r=a2a1=1827=23
Then find the sum:
S=a11−r
S=271−23=81
Example 5:
Find the sum of the infinite geometric sequence
8,12,18,27,⋯ if it exists.
First find r:
r=a2a1=128=32
Since r=32 is not less than one the series has no sum.
There is a formula to calculate the nth term of an geometric series, that is, the sum of the first n terms of an geometric sequence.See also: sigma notation of a series and sum of the first n terms of an arithmetic sequence
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An geometric sequence or progression, is a sequence where each term is calculated by multiplying the previous term by a fixed number.
Geometric Sequences
This fixed number is called the common ratio, r.
The common ratio can be positive or negative, an integer or a fraction.
The common ratio can be calculated by dividing any term by the one before it.
e.g. Common ratio = t n+1 ÷ t n
The first term of a geometric sequence is shown by the variable a.
Geometric Sequence | First term, a | Common ratio, r |
2, 6, 18, 54, ... | 2 | |
20, 10, 5, 2.5, ... | 20 | 10 ÷ 20 = 0.5 |
General Term, tn
A geometric sequence can be written:
First term | Second term | Third term | Fourth term | General term (n th term) | |
t 1 | t 2 | t 3 | t 4 | ... | t n |
a | ar | ar2 | ar3 | ... | ar n − 1 |
Example 1 | What is the common ratio of the geometric sequence: 20, 10, 5, 2.5,, ... | Common ratio = t n+1 ÷ t n Second term ÷ first term = t2 ÷ t1 = 10 ÷ 20 = 0.5 Check: Third term ÷ second term = 5 ÷ 10 = 0.5 The common ratio is 0.5 |
Example 2 | Find the 8th term of the geometric sequence: 3, 9, 27, 81, ... | Common ratio, r = 9 ÷ 3 = 3 using tn = ar n − 1 t8 = 3 x 3 8- 1 The 8th term is 6561 |
Example 3 | Which term of the sequence 2, 4, 8, 16, ... would be equal to 1024? | Common ratio, r = 2 Using tn = a r n-1 1024 =2 x 2 n-1 1024 is the 10th term. |
Example 4 | The third term of an geometric sequence of positive terms is 8 and the fifth term is 32. Find the first term, a, and the common ratio, r, and thus list the first four terms of the sequence. | t 3 = 8 using tn = a r n-1 32 = ar 5 − 1 32 = ar 4 4 = r2 ( dividing) The common ratio is 2 (discard -2) 8 = a x 22 The sequence is 2, 4, 8, 16, ... |
Geometric Series
If terms of a geometric sequence are added together a geometric series is formed.
2 + 4 + 8 + 16 is a finite geometric series
2 + 4 + 8 + 16 + ... is an infinte geometric series
To find the sum of the first n terms of a geometric sequence use the formula:
Sum of first n terms of a geometric sequence wherer = common ratioa = first term n = number of terms | |
OR
If the common ratio is a fraction i.e. -1 < r < 1 then an equivalent formula, shown below is easier to use.
Sum of first n terms of a geometric sequence for when -1 < r < 1 i.e. r is a fraction | |
Example What is the sum of the first 10 terms of the geometric sequence: 3, 6, 12, ...
| |
The Sum to Infinity of a Geometric Sequence
Spreadsheets are very useful for generating sequences and series.
For a geometric sequence with a common ratio greater than 1:
The formula in cell B3 is = B2*2 The formula in cell D3 is =D2 + B3 The fill down command is then used to complete the sequences. |
It can be seen that as successive terms are added the sum of the terms increases.
If there were an infinite number of terms the sum would be infinity.
For a geometric sequence with a common ratio less than 1:
The formula in cell B3 is = B2*2 The formula in cell D3 is =D2 + B3 The fill down command is then used to comlete the sequences. |
It can be seen that as successive terms are added the sum of the terms appears to be heading towards 16.
If there were an infinite number of terms the sum would be 16.
This is called the sum to infinity of a geometric sequence and only applies when the common ratio is a fraction
i.e. -1 < r < +1.
r can be positive or negative.
The following formula can be used:
Sum to infinity of geometric sequence wherer = common ratio a = first term | |
Example
Find the sum to infinity of the geometric sequence 8, 4, 2, 1, ...
a = 8 and r = 0.5
As can be seen from cell D10 in the spreadsheet above, 16 is the value the sums were heading towards.
To see this concept clearly illustrated -