A sequence in which each term increases or decreases from the last by a constant factor is called a geometric sequence. We refer to the constant factor the terms are changing by as the common ratio, which will result from dividing any two successive terms $\left(\frac{t_{n+1}}{t_n}\right)$(tn+1tn).
We denote the first term in the sequence by the letter $t_1$t1 and the common ratio by the letter $r$r. For example, the sequence $4,8,16,32\dots$4,8,16,32… is geometric with $t_1=4$t1=4 and $r=2$r=2. The sequence $100,-50,25,-12.5,\dots$100,−50,25,−12.5,… is geometric with $t_1=100$t1=100 and $r=-\frac{1}{2}$r=−12.
Since, $t_2=r\times t_1$t2=r×t1, $t_3=r\times t_2$t3=r×t2 and so on, we can write any geometric sequence as the recurrence relation:
$t_{n+1}=rt_n$tn+1=rtn
We can also find an explicit formula in terms of $t_1$t1 and $r$r, this is useful for finding the $n$nth term without listing the sequence.
Let's look at a table of a concrete example to see the pattern for the explicit formula. For the sequence $5,10,20,40,\ldots$5,10,20,40,…, we have starting term of $5$5 and a common ratio of $2$2, that is $t_1=5$t1=5 and $r=2$r=2. A table of the sequence is show below:
$n$n | $t_n$tn | Pattern |
---|---|---|
$1$1 | $5$5 | $5\times2^0$5×20 |
$2$2 | $10$10 | $5\times2^1$5×21 |
$3$3 | $20$20 | $5\times2^2$5×22 |
$4$4 | $40$40 | $5\times2^3$5×23 |
... | ||
$n$n | $t_n$tn | $5\times2^{n-1}$5×2n−1 |
The pattern starts to become clear and we could guess that the tenth term becomes $t_{10}=5\times2^9$t10=5×29 and the one-hundredth term $t_{100}=5\times2^{99}$t100=5×299. And following the pattern, the explicit formula for the $n$nth term is $t_n=5\times2^{n-1}$tn=5×2n−1.
For any geometric progression with starting value $t_1$t1 and common ratio $r$r has the terms given by: $t_1,t_1r,t_1r^2,t_1r^3,...$t1,t1r,t1r2,t1r3,... We see a similar pattern to our previous table and can write down the formula for the $n$nth term:
$t_n=t_1r^{n-1}$tn=t1rn−1
For any geometric sequence with starting value $t_1$t1 and common ratio $r$r, we can express it in either of the following two forms:
$t_{n+1}=rt_n$tn+1=rtn
$t_n=t_1r^{n-1}$tn=t1rn−1
For the sequence $810,270,90,30...$810,270,90,30..., find an explicit rule for the $n$nth term and hence, find the $8$8th term.
Think: Check that the sequence is geometric, does each term differ from the last by a constant factor? Then write down the the starting value $t_1$t1 and common ratio $r$r and substitute these into the general form: $t_n=t_1r^{n-1}$tn=t1rn−1
Do: Dividing the second term by the first we get, $\frac{t_2}{t_1}=\frac{1}{3}$t2t1=13. Checking the ratio between the successive pairs we also get $\frac{1}{3}$13. So we have a geometric sequence with: $t_1=810$t1=810 and $r=\frac{1}{3}$r=13. The general formula for this sequence is: $t_n=810\left(\frac{1}{3}\right)^{n-1}$tn=810(13)n−1.
Hence, the $8$8th term is: $t_8=810\left(\frac{1}{3}\right)^7=\frac{10}{27}$t8=810(13)7=1027.
For the sequence $5,20,80,320,...$5,20,80,320,..., find $n$n if the $n$nth term is $327680$327680.
Think: Find a general rule for the sequence, substitute in $327680$327680 for $t_n$tn and rearrange for $n$n.
Do: This is a geometric sequence with $t_1=5$t1=5 and common ratio $r=4$r=4. Hence, the general rule is: $t_n=5\left(4\right)^{n-1}$tn=5(4)n−1, substituting $t_n=327680$tn=327680, we get:
$327680$327680 | $=$= | $5\left(4\right)^{n-1}$5(4)n−1 | |
$\therefore4^{n-1}$∴4n−1 | $=$= | $65536$65536 | |
$4^{n-1}$4n−1 | $=$= | $4^8$48 | Solve by guess and check, technology or logarithms. |
Hence, $n-1$n−1 | $=$= | $8$8 | |
$n$n | $=$= | $9$9 |
Hence, the $9$9th term in the sequence is $327680$327680.
If a geometric sequence has $t_3=12$t3=12 and $t_6=96$t6=96, find the recurrence relation for the sequence.
Think: To find the recurrence relation we need the starting value and common ratio. As we have two terms we can set up two equations in terms of $t_1$t1 and $r$r using $t_n=t_1r^{n-1}$tn=t1rn−1.
Do:
$t_3$t3: | $t_1r^2=12$t1r2=12 | $.....\left(1\right)$.....(1) |
and
$t_6$t6: | $t_1r^5=96$t1r5=96 | $.....\left(2\right)$.....(2) |
If we now divide equation $\left(2\right)$(2) by equation $\left(1\right)$(1), we obtain the following:
$\frac{t_1r^5}{t_1r^2}$t1r5t1r2 | $=$= | $\frac{96}{12}$9612 |
$r^3$r3 | $=$= | $8$8 |
$\therefore r$∴r | $=$= | $2$2 |
With the common ratio found to be $2$2, then we know that, using equation $\left(1\right)$(1) $t_1\times2^2=12$t1×22=12 and so $t_1$t1 is $3$3. The recurrence relation for this sequence is given by:
$t_{n+1}=2t_n,t_1=3$tn+1=2tn,t1=3
Study the pattern for the following sequence.
$-9$−9$,$, $3.6$3.6$,$, $-1.44$−1.44$,$, $0.576$0.576 ...
State the common ratio between the terms.
Consider the first four terms in this geometric sequence: $-8$−8, $-16$−16, $-32$−32, $-64$−64
If $T_n$Tn is the $n$nth term, evaluate $\frac{T_2}{T_1}$T2T1.
Evaluate $\frac{T_3}{T_2}$T3T2
Evaluate $\frac{T_4}{T_3}$T4T3
Hence find the value of $T_5$T5.
In a geometric progression, $T_4=128$T4=128 and $T_8=32768$T8=32768.
Solve for $r$r, the common ratio in the sequence. Write both solutions on the same line separated by a comma.
For the case where $r=4$r=4, solve for $T_1$T1, the first term in the progression.
Consider the sequence in which the first term is positive. Find an expression for $T_n$Tn, the general $n$nth term of this sequence.
When given a formula for the $n$nth term we can generate a table of values for the sequence. For example in the sequence given by the formula $t_n=12\times\left(1.5\right)^{n-1}$tn=12×(1.5)n−1, by substituting for $n$n appropriately and using a calculator, we can generate the following table of the first $7$7 terms of the sequence:
$n$n | $1$1 | $2$2 | $3$3 | $4$4 | $5$5 | $6$6 |
---|---|---|---|---|---|---|
$t_n$tn | $12$12 | $18$18 | $27$27 | $40.5$40.5 | $60.75$60.75 | $91.125$91.125 |
Perhaps more interesting though is the different types of graphs that geometric sequences correspond to. The graphs are not linear like arithmetic progressions, except for the trivial case of $r=1$r=1. The path of points plotted from a geometric sequence follow an exponential curve for positive values of $r$r:
Recall from exponential graphs, sequences of the form $t_n=t_1r^{n-1}$tn=t1rn−1, where $a>0$a>0 will follow:
What we haven't previously looked at in the exponential chapter was what if $r$r is negative? The values of successive terms flip their sign so that the graph is depicted as either a growing($|r|>1$|r|>1) or diminishing($|r|<1$|r|<1) zig-zag path - alternating between points on the graph$f(n)=t_1|r|^{n-1}$f(n)=t1|r|n−1 and $f(n)=-t_1|r|^{n-1}$f(n)=−t1|r|n−1, depending on the power being odd or even.
For the geometric progression with starting value $12$12 and ratio $r=-1.5$r=−1.5, create a table and plot a graph of the sequence.
Think: This is the same as the example in the previous table but the ratio is now negative. The $n$nth term is given by $t_n=12\times\left(-1.5\right)^{n-1}$tn=12×(−1.5)n−1, the table will be the same but the sign of the terms will alternate.
Do: The new table becomes:
$n$n | $1$1 | $2$2 | $3$3 | $4$4 | $5$5 | $6$6 |
---|---|---|---|---|---|---|
$t_n$tn | $12$12 | $-18$−18 | $27$27 | $-40.5$−40.5 | $60.75$60.75 | $-91.125$−91.125 |
Checking, for $n=1$n=1, we have $t_1=12\times\left(-1.5\right)^{1-1}=12$t1=12×(−1.5)1−1=12 and for $n=2$n=2 we have $t_2=12\times\left(-1.5\right)^{2-1}=-18$t2=12×(−1.5)2−1=−18, continuing on even numbered terms become negative and odd numbered terms become positive.
Here is a graph of the two geometric sequences depicted in both tables. Note that the odd terms of the zig-zag graph coincide with the terms of the first geometric progression.
Try adjusting the values of $a=t_1$a=t1 and $r$r in the applet below to observe the effect on the plotted points.
|
For $|r|>1$|r|>1 the values will diverge as $n$n increases, the terms will keep getting larger in size without bound.
For $|r|<1$|r|<1 the values will converge as $n$n increases, each term getting smaller and smaller and approaching a limit of $0$0.
The given table of values represents terms in a geometric sequence.
$n$n | $1$1 | $2$2 | $3$3 | $4$4 |
---|---|---|---|---|
$T_n$Tn | $9$9 | $36$36 | $144$144 | $576$576 |
Identify $r$r, the common ratio between consecutive terms.
Write a simplified expression for the general $n$nth term of the sequence, $T_{n+1}$Tn+1.
Find the $8$8th term of the sequence.
Consider the first-order recurrence relationship defined by $T_{n+1}=3T_n,T_1=1$Tn+1=3Tn,T1=1.
Determine the next three terms of the sequence from $T_2$T2 to $T_4$T4.
Write all three terms on the same line, separated by commas.
Plot the first four terms on the graph below.
Is the sequence generated from this definition arithmetic or geometric?
Arithmetic
Geometric
Neither
The $n$nth term of a geometric progression is given by the equation $T_n=2\times3^{n-1}$Tn=2×3n−1.
Complete the table of values:
$n$n | $1$1 | $2$2 | $3$3 | $4$4 | $10$10 |
---|---|---|---|---|---|
$T_n$Tn | $\editable{}$ | $\editable{}$ | $\editable{}$ | $\editable{}$ | $\editable{}$ |
What is the common ratio between consecutive terms?
Plot the points in the table that correspond to $n=1$n=1, $n=2$n=2, $n=3$n=3 and $n=4$n=4.
If the plots on the graph were joined they would form:
a straight line
a curved line
When looking at exponential models you have encountered many applications of geometric sequences such as compound interest, exponential growth of bacteria, exponential decay of radioactive elements. If we have an amount increasing or decreasing by a constant factor at set time periods, then you can consider that process as being geometric.
After receiving $\$500$$500 for her birthday, Hayley decides to spend $10%$10% of this money each week.
a) Find a model for $B_n$Bn, the amount of birthday money she has left at the start of the $n$nth week.
At the beginning of the second week, Hayley will have spent $\$50$$50, and will only have $\$450$$450 or $90%$90% of the birthday money left. During the second week she will spend slightly less - $10%$10% of her remaining $\$450$$450 or $\$45$$45, so at the beginning of the third week $\$405$$405 will remain. The sequence of birthday dollars that remain at the beginning of the first five weeks is given as $500,450,405,364.5,328.05$500,450,405,364.5,328.05 and we can see here that this sequence is geometric with the first term $t_1=500$t1=500 and the common ratio $r=0.9$r=0.9.
Hence, $B_n=500(0.9)^{n-1}$Bn=500(0.9)n−1.
b) If instead of spending $10%$10%, Hayley decides to double her savings by setting aside an additional $10%$10% in savings each week. How long before she reaches her savings goal?
Firstly, she will add $10%$10% to the birthday money, so that at the beginning of the second week, the additional $\$50$$50 will take the total to $\$550$$550. At the beginning of week $3$3 she will add a further $10%$10% of this accrued $\$550$$550, so that the new total becomes $\$605$$605. She will keep adding $10%$10% of what ever is there at the beginning of each week until she reaches or exceeds $\$1000$$1000.
The geometric progression for this plan becomes $500,550,605,665.5,732.05,...$500,550,605,665.5,732.05,...
This progression has $t_1=500$t1=500 and $r=\frac{550}{500}=1.1$r=550500=1.1, so that the $n$nth term of the progression is given by $t_n=500\left(1.1\right)^{n-1}$tn=500(1.1)n−1.
To solve for when the balance reaches her goal of $\$1000$$1000, solve for $n$n when $t_n=1000$tn=1000;
$500\left(1.1\right)^{n-1}$500(1.1)n−1 | $=$= | $1000$1000 | |
$1.1^{n-1}$1.1n−1 | $=$= | $2$2 | Dividing both sides by 2 |
$\therefore(n-1)$∴(n−1) | $\approx$≈ | $7.27$7.27 | Solve by guess and check, technology or logarithms. |
$n$n | $\approx$≈ | $8.27$8.27 |
So $n$n must be greater than $8.27$8.27 for Hayley to have achieved her goal, so at the beginning of the $9$9th week her savings will exceed $\$1000$$1000.
Suppose you save $\$1$$1 the first day of a month, $\$2$$2 the second day, $\$4$$4 the third day, $\$8$$8 the fourth day, and so on. That is, each day you save twice as much as you did the day before.
What will you put aside for savings on the $14$14th day of the month?
What will you put aside for savings on the $30$30th day of the month?
To test the effectiveness of a new antibiotic, a certain bacteria is introduced to a body and the number of bacteria is monitored. Initially, there are $19$19 bacteria in the body, and after four hours the number is found to double.
If the bacterial population continues to double every four hours, how many bacteria will there be in the body after $24$24 hours?
The antibiotic is applied after $24$24 hours, and is found to kill one third of the germs every two hours. How many bacteria will there be left in the body $24$24 hours after applying the antibiotic? Assume the bacteria stops multiplying and round your answer to the nearest integer if necessary.