Learning Outcomes
- Find the common ratio for a geometric sequence.
- List the terms of a geometric sequence.
- Use a recursive formula for a geometric sequence.
- Use an explicit formula for a geometric sequence.
- Use the formula for the sum of the first n terms of a geometric series.
- Use the formula for the sum of an infinite geometric series.
- Solve annuity problems.
Many jobs offer an annual cost-of-living increase to keep salaries consistent with inflation. Suppose, for example, a recent college graduate finds a position as a sales manager earning an annual salary of $26,000. He is promised a 2% cost of living increase each year. His annual salary in any given year can be found by multiplying his salary from the previous year by 102%. His salary will be $26,520 after one year; $27,050.40 after two years; $27,591.41 after three years; and so on. When a salary increases by a constant rate each year, the salary grows by a constant factor. In this section we will review sequences that grow in this way.
Terms of Geometric Sequences
Finding Common Ratios
The yearly salary values described form a geometric sequence because they change by a constant factor each year. Each term of a geometric sequence increases or decreases by a constant factor called the common ratio. The sequence below is an example of a geometric sequence because each term increases by a constant factor of 6. Multiplying any term of the sequence by the common ratio 6 generates the subsequent term.
A General Note: Definition of a Geometric Sequence
A geometric sequence is one in which any term divided by the previous term is a constant. This constant is called the common ratio of the sequence. The common ratio can be found by dividing any term in the sequence by the previous term. If [latex]{a}_{1}[/latex] is the initial term of a geometric sequence and [latex]r[/latex] is the common ratio, the sequence will be
[latex]\left\{{a}_{1}, {a}_{1}r,{a}_{1}{r}^{2},{a}_{1}{r}^{3},…\right\}[/latex].
How To: Given a set of numbers, determine if they represent a geometric sequence.
- Divide each term by the previous term.
- Compare the quotients. If they are the same, a common ratio exists and the sequence is geometric.
Example: Finding Common Ratios
Is the sequence geometric? If so, find the common ratio.
- [latex]1,2,4,8,16,\dots[/latex]
- [latex]48,12,4,2,\dots[/latex]
Q & A
If you are told that a sequence is geometric, do you have to divide every term by the previous term to find the common ratio?
No. If you know that the sequence is geometric, you can choose any one term in the sequence and divide it by the previous term to find the common ratio.
Try It
Is the sequence geometric? If so, find the common ratio.
[latex]5,10,15,20,\dots[/latex]
Try It
Is the sequence geometric? If so, find the common ratio.
[latex]100,20,4,\dfrac{4}{5},\dots[/latex]
Writing Terms of Geometric Sequences
Now that we can identify a geometric sequence, we will learn how to find the terms of a geometric sequence if we are given the first term and the common ratio. The terms of a geometric sequence can be found by beginning with the first term and multiplying by the common ratio repeatedly. For instance, if the first term of a geometric sequence is [latex]{a}_{1}=-2[/latex] and the common ratio is [latex]r=4[/latex], we can find subsequent terms by multiplying [latex]-2\cdot 4[/latex] to get [latex]-8[/latex] then multiplying the result [latex]-8\cdot 4[/latex] to get [latex]-32[/latex] and so on.
[latex]\begin{align}&{a}_{1}=-2 \\ &{a}_{2}=\left(-2\cdot 4\right)=-8 \\ &{a}_{3}=\left(-8\cdot 4\right)=-32 \\ &{a}_{4}=\left(-32\cdot 4\right)=-128 \end{align}[/latex]
The first four terms are [latex]\left\{-2,-8,-32,-128\right\}[/latex].
How To: Given the first term and the common factor, find the first four terms of a geometric sequence.
- Multiply the initial term, [latex]{a}_{1}[/latex], by the common ratio to find the next term, [latex]{a}_{2}[/latex].
- Repeat the process, using [latex]{a}_{n}={a}_{2}[/latex] to find [latex]{a}_{3}[/latex] and then [latex]{a}_{3}[/latex] to find [latex]{a}_{4,}[/latex] until all four terms have been identified.
- Write the terms separated by commons within brackets.
Example: Writing the Terms of a Geometric Sequence
List the first four terms of the geometric sequence with [latex]{a}_{1}=5[/latex] and [latex]r=-2[/latex].
Try It
List the first five terms of the geometric sequence with [latex]{a}_{1}=18[/latex] and [latex]r=\dfrac{1}{3}[/latex].
Explicit Formulas for Geometric Sequences
Using Explicit Formulas for Geometric Sequences
Because a geometric sequence is an exponential function whose domain is the set of positive integers, and the common ratio is the base of the function, we can write explicit formulas that allow us to find particular terms.
[latex]{a}_{n}={a}_{1}{r}^{n - 1}[/latex]
Let’s take a look at the sequence [latex]\left\{18\text{, }36\text{, }72\text{, }144\text{, }288\text{, }…\right\}[/latex]. This is a geometric sequence with a common ratio of 2 and an exponential function with a base of 2. An explicit formula for this sequence is
[latex]{a}_{n}=18\cdot {2}^{n - 1}[/latex]
A General Note: Explicit Formula for a Geometric Sequence
The nth term of a geometric sequence is given by the explicit formula:
[latex]{a}_{n}={a}_{1}{r}^{n - 1}[/latex]
Example: Writing Terms of Geometric Sequences Using the Explicit Formula
Given a geometric sequence with [latex]{a}_{1}=3[/latex] and [latex]{a}_{4}=24[/latex], find [latex]{a}_{2}[/latex].
Try It
Given a geometric sequence with [latex]{a}_{2}=4[/latex] and [latex]{a}_{3}=32[/latex] , find [latex]{a}_{6}[/latex].
Example: Writing an Explicit Formula for the nth Term of a Geometric Sequence
Write an explicit formula for the [latex]n\text{th}[/latex] term of the following geometric sequence.
[latex]\left\{2,10,50,250,\dots\right\}[/latex]
Try It
Write an explicit formula for the following geometric sequence.
[latex]\left\{-1,3,-9,27,\dots\right\}[/latex]
In real-world scenarios involving arithmetic sequences, we may need to use an initial term of [latex]{a}_{0}[/latex] instead of [latex]{a}_{1}[/latex]. In these problems we can alter the explicit formula slightly by using the following formula:
[latex]{a}_{n}={a}_{0}{r}^{n}[/latex]
Example: Solving Application Problems with Geometric Sequences
In 2013, the number of students in a small school is 284. It is estimated that the student population will increase by 4% each year.
- Write a formula for the student population.
- Estimate the student population in 2020.
Try It
A business starts a new website. Initially the number of hits is 293 due to the curiosity factor. The business estimates the number of hits will increase by 2.6% per week.
- Write a formula for the number of hits.
- Estimate the number of hits in 5 weeks.
The following video provides a short lesson on some of the topics covered in this lesson.
A couple decides to start a college fund for their daughter. They plan to invest $50 in the fund each month. The fund pays 6% annual interest, compounded monthly. How much money will they have saved when their daughter is ready to start college in 6 years? In this section we will learn how to answer this question. To do so we need to consider the amount of money invested and the amount of interest earned.
Geometric Series
Just as the sum of the terms of an arithmetic sequence is called an arithmetic series, the sum of the terms in a geometric sequence is called a geometric series. Recall that a geometric sequence is a sequence in which the ratio of any two consecutive terms is the common ratio, [latex]r[/latex]. We can write the sum of the first [latex]n[/latex] terms of a geometric series as
[latex]{S}_{n}={a}_{1}+{a}_{1}r+{a}_{1}{r}^{2}+…+{a}_{1}{r}^{n - 1}[/latex].
Just as with arithmetic series, we can do some algebraic manipulation to derive a formula for the sum of the first [latex]n[/latex] terms of a geometric series. We will begin by multiplying both sides of the equation by [latex]r[/latex].
[latex]r{S}_{n}={a}_{1}r+{a}_{1}{r}^{2}+{a}_{1}{r}^{3}+…+{a}_{1}{r}^{n}[/latex]
Next, we subtract this equation from the original equation.
[latex]\begin{align}{S}_{n}&={a}_{1}+{a}_{1}r+{a}_{1}{r}^{2}+…+{a}_{1}{r}^{n - 1} \\ -r{S}_{n}&=-\left({a}_{1}r+{a}_{1}{r}^{2}+{a}_{1}{r}^{3}+…+{a}_{1}{r}^{n}\right) \\ \hline \left(1-r\right){S}_{n}&={a}_{1}-{a}_{1}{r}^{n}\end{align}[/latex]
Notice that when we subtract, all but the first term of the top equation and the last term of the bottom equation cancel out. To obtain a formula for [latex]{S}_{n}[/latex], factor [latex]a_1[/latex] on the right hand side and divide both sides by [latex]\left(1-r\right)[/latex].
[latex]{S}_{n}=\dfrac{{a}_{1}\left(1-{r}^{n}\right)}{1-r}\text{ r}\ne \text{1}[/latex]
A General Note: Formula for the Sum of the First n Terms of a Geometric Series
A geometric series is the sum of the terms in a geometric sequence. The formula for the sum of the first [latex]n[/latex] terms of a geometric sequence is represented as
[latex]{S}_{n}=\dfrac{{a}_{1}\left(1-{r}^{n}\right)}{1-r}\text{ r}\ne \text{1}[/latex]
How To: Given a geometric series, find the sum of the first n terms.
- Identify [latex]{a}_{1},r,\text{and}n[/latex].
- Substitute values for [latex]{a}_{1},r[/latex], and [latex]n[/latex] into the formula [latex]{S}_{n}=\dfrac{{a}_{1}\left(1-{r}^{n}\right)}{1-r}[/latex].
- Simplify to find [latex]{S}_{n}[/latex].
Example: Finding the First n Terms of a Geometric Series
Use the formula to find the indicated partial sum of each geometric series.
- [latex]{S}_{11}[/latex] for the series [latex] 8 + -4 + 2 + \dots [/latex]
- [latex]\sum\limits _{k=1}^6 3\cdot {2}^{k}[/latex]
Try It
Use the formula to find the indicated partial sum of each geometric series.
[latex]{S}_{20}[/latex] for the series [latex]1\text{,}000 + 500 + 250 + \dots [/latex]
Use the formula to determine the sum [latex]\sum\limits _{k=1}^{8}{3}^{k}[/latex]
Example: Solving an Application Problem with a Geometric Series
At a new job, an employee’s starting salary is $26,750. He receives a 1.6% annual raise. Find his total earnings at the end of 5 years.
Try It
At a new job, an employee’s starting salary is $32,100. She receives a 2% annual raise. How much will she have earned by the end of 8 years?
Using the Formula for the Sum of an Infinite Geometric Series
Thus far, we have looked only at finite series. Sometimes, however, we are interested in the sum of the terms of an infinite sequence rather than the sum of only the first n terms. An infinite series is the sum of the terms of an infinite sequence. An example of an infinite series is [latex]2+4+6+8+\dots[/latex].
This series can also be written in summation notation as [latex] \sum\limits _{k=1}^{\infty} 2k[/latex], where the upper limit of summation is infinity. Because the terms are not tending to zero, the sum of the series increases without bound as we add more terms. Therefore, the sum of this infinite series is not defined. When the sum is not a real number, we say the series diverges.
Determining Whether the Sum of an Infinite Geometric Series is Defined
If the terms of an infinite geometric series approach 0, the sum of an infinite geometric series can be defined. The terms in this series approach 0:
[latex]1+0.2+0.04+0.008+0.0016+\dots[/latex]
The common ratio is [latex]r=0.2[/latex]. As n gets large, the values of of [latex]r^n[/latex] get very small and approach 0. Each successive term affects the sum less than the preceding term. As each succeeding term gets closer to 0, the sum of the terms approaches a finite value. The terms of any infinite geometric series with [latex]-1<r<1[/latex] approach 0; the sum of a geometric series is defined when [latex]-1<r<1[/latex].
DETERMINING WHETHER THE SUM OF AN INFINITE GEOMETRIC SERIES IS DEFINED
The sum of an infinite series is defined if the series is geometric and [latex]-1<r<1[/latex].
How To: Given the first several terms of an infinite series, determine if the sum of the series exists.
- Find the ratio of the second term to the first term.
- Find the ratio of the third term to the second term.
- Continue this process to ensure the ratio of a term to the preceding term is constant throughout. If so, the series is geometric.
- If a common ratio, r, was found in step 3, check to see if [latex]-1<r<1[/latex]. If so, the sum is defined. If not, the sum is not defined.
Example: Determining Whether the Sum of an Infinite Series is Defined
Determine whether the sum of each infinite series is defined.
- [latex]12+8+4+/dots[/latex]
- [latex]\dfrac{3}{4}+\dfrac{1}{2}+\dfrac{1}{3}+\dots[/latex]
- [latex]\sum\limits _{k=1}^{\infty}{27}\cdot\left(\dfrac{1}{3}\right)^k[/latex]
- [latex]\sum\limits _{k=1}^{\infty}{5k}[/latex]
try it
Determine whether the sum of the infinite series is defined.
- [latex]\dfrac{1}{3}+\dfrac{1}{2}+\dfrac{3}{4}+\dfrac{9}{8}+\cdots[/latex]
- [latex]24+(-12)+6+(-3)+\dots[/latex]
- [latex]\sum\limits _{k=1}^{\infty} 15\cdot(-0.3)^k[/latex]
Finding Sums of Infinite Series
When the sum of an infinite geometric series exists, we can calculate the sum. The formula for the sum of an infinite series is related to the formula for the sum of the first n terms of a geometric series.
[latex]{S}_{n}=\dfrac{{a}_{1}\left(1-{r}^{n}\right)}{1-r}[/latex]
We will examine an infinite series with [latex]r=\frac{1}{2}[/latex]. What happens to [latex]r^n[/latex] as n increases?
[latex]\begin{align} &{\left(\frac{1}{2}\right)}^{2} = \frac{1}{4} \\&{\left(\frac{1}{2}\right)}^{3} = \frac{1}{8} \\&{\left(\frac{1}{2}\right)}^{4} = \frac{1}{16} \end{align}[/latex]
The value of [latex]r^n[/latex] decreases rapidly. What happens for greater values of n?
[latex]\begin{align} &{\left(\frac{1}{2}\right)}^{10} = \frac{1}{1\text{,}024} \\&{\left(\frac{1}{2}\right)}^{20} = \frac{1}{1\text{,}048\text{,}576} \\&{\left(\frac{1}{2}\right)}^{30} = \frac{1}{1\text{,}073\text{,}741\text{,}824} \end{align}[/latex]
As n gets large, [latex]r^n[/latex] gets very small. We say that as n increases without bound, [latex]r^n[/latex] approaches 0. As [latex]r^n[/latex] approaches 0, [latex]1-r^n[/latex] approaches 1. When this happens the numerator approaches [latex]a_1[/latex]. This gives us the formula for the sum of an infinite geometric series.
A General Note: FORMULA FOR THE SUM OF AN INFINITE GEOMETRIC SERIES
The formula for the sum of an infinite geometric series with [latex]-1<r<1[/latex] is:
[latex]S=\dfrac{{a}_{1}}{1-r}[/latex]
How To: Given an infinite geometric series, find its sum.
- Identify [latex]a_1[/latex] and r.
- Confirm that [latex]-1<r<1[/latex].
- Substitute values for [latex]a_1[/latex] and r into the formula, [latex]S=\dfrac{{a}_{1}}{1-r}[/latex].
- Simplify to find S.
Example: Finding the Sum of an Infinite Geometric Series
Find the sum, if it exists, for the following:
- [latex]10+9+8+7+\dots[/latex]
- [latex]248.6+99.44+39.776+\dots[/latex]
- [latex]\sum\limits _{k=1}^{\infty}4\text{,}374\cdot\left(-\dfrac{1}{3}\right)^{k-1}[/latex]
- [latex]\sum\limits _{k=1}^{\infty}\dfrac{1}{9}\cdot\left(\dfrac{4}{3}\right)^{k}[/latex]
Example: Finding an Equivalent Fraction for a Repeating Decimal
Find the equivalent fraction for the repeating decimal [latex]0.\overline{3}[/latex].
try it
Find the sum if it exists.
- [latex]2+\dfrac{2}{3}+\dfrac{2}{9}+\dots[/latex]
- [latex]\sum\limits _{k=1}^{\infty}{0.76k+1}[/latex]
- [latex]\sum\limits _{k=1}^{\infty}\left(-\dfrac{3}{8}\right)^k[/latex]
Annuities
At the beginning of the section, we looked at a problem in which a couple invested a set amount of money each month into a college fund for six years. An annuity is an investment in which the purchaser makes a sequence of periodic, equal payments. To find the amount of an annuity, we need to find the sum of all the payments and the interest earned. In the example the couple invests $50 each month. This is the value of the initial deposit. The account paid 6% annual interest, compounded monthly. To find the interest rate per payment period, we need to divide the 6% annual percentage interest (APR) rate by 12. So the monthly interest rate is 0.5%. We can multiply the amount in the account each month by 100.5% to find the value of the account after interest has been added.
We can find the value of the annuity right after the last deposit by using a geometric series with [latex]{a}_{1}=50[/latex] and [latex]r=100.5\%=1.005[/latex]. After the first deposit, the value of the annuity will be $50. Let us see if we can determine the amount in the college fund and the interest earned.
We can find the value of the annuity after [latex]n[/latex] deposits using the formula for the sum of the first [latex]n[/latex] terms of a geometric series. In 6 years, there are 72 months, so [latex]n=72[/latex]. We can substitute [latex]{a}_{1}=50, r=1.005,[/latex] and [latex]n=72[/latex] into the formula, and simplify to find the value of the annuity after 6 years.
[latex]{S}_{72}=\dfrac{50\left(1-{1.005}^{72}\right)}{1 - 1.005}\approx 4\text{,}320.44[/latex]
After the last deposit, the couple will have a total of $4,320.44 in the account. Notice, the couple made 72 payments of $50 each for a total of [latex]72\left(50\right) = $3,600[/latex]. This means that because of the annuity, the couple earned $720.44 interest in their college fund.
How To: Given an initial deposit and an interest rate, find the value of an annuity.
- Determine [latex]{a}_{1}[/latex], the value of the initial deposit.
- Determine [latex]n[/latex], the number of deposits.
- Determine [latex]r[/latex].
- Divide the annual interest rate by the number of times per year that interest is compounded.
- Add 1 to this amount to find [latex]r[/latex].
- Substitute values for [latex]{a}_{1},r,[/latex] and [latex]n[/latex]
into the formula for the sum of the first [latex]n[/latex] terms of a geometric series, [latex]{S}_{n}=\dfrac{{a}_{1}\left(1-{r}^{n}\right)}{1-r}[/latex]. - Simplify to find [latex]{S}_{n}[/latex], the value of the annuity after [latex]n[/latex] deposits.
Example: Solving an Annuity Problem
A deposit of $100 is placed into a college fund at the beginning of every month for 10 years. The fund earns 9% annual interest, compounded monthly, and paid at the end of the month. How much is in the account right after the last deposit?
Try It
At the beginning of each month, $200 is deposited into a retirement fund. The fund earns 6% annual interest, compounded monthly, and paid into the account at the end of the month. How much is in the account if deposits are made for 10 years?
Key Equations
recursive formula for [latex]nth[/latex] term of a geometric sequence | [latex]{a}_{n}=r{a}_{n - 1},n\ge 2[/latex] |
explicit formula for [latex]nth[/latex] term of a geometric sequence | [latex]{a}_{n}={a}_{1}{r}^{n - 1}[/latex] |
sum of the first [latex]n[/latex] terms of a geometric series |
[latex]{S}_{n}=\dfrac{{a}_{1}\left(1-{r}^{n}\right)}{1-r} , r\ne 1[/latex] |
sum of an infinite geometric series with [latex]-1<r<1[/latex] | [latex]{S}_{n}=\dfrac{{a}_{1}}{1-r}[/latex] |
Key Concepts
- A geometric sequence is a sequence in which the ratio between any two consecutive terms is a constant.
- The constant ratio between two consecutive terms is called the common ratio.
- The common ratio can be found by dividing any term in the sequence by the previous term.
- The terms of a geometric sequence can be found by beginning with the first term and multiplying by the common ratio repeatedly.
- A recursive formula for a geometric sequence with common ratio [latex]r[/latex] is given by [latex]{a}_{n}=r{a}_{n - 1}[/latex] for [latex]n\ge 2[/latex] .
- As with any recursive formula, the initial term of the sequence must be given.
- An explicit formula for a geometric sequence with common ratio [latex]r[/latex] is given by [latex]{a}_{n}={a}_{1}{r}^{n - 1}[/latex].
- In application problems, we sometimes alter the explicit formula slightly to [latex]{a}_{n}={a}_{0}{r}^{n}[/latex].
- The sum of the terms in a sequence is called a series.
- A common notation for series is called summation notation, which uses the Greek letter sigma to represent the sum.
- The sum of the terms in a geometric sequence is called a geometric series.
- The sum of the first [latex]n[/latex] terms of a geometric series can be found using a formula.
- The sum of an infinite series exists if the series is geometric with [latex]-1<r<1[/latex].
- If the sum of an infinite series exists, it can be found using a formula.
- An annuity is an account into which the investor makes a series of regularly scheduled payments. The value of an annuity can be found using geometric series.
Glossary
annuity an investment in which the purchaser makes a sequence of periodic, equal payments
common ratio the ratio between any two consecutive terms in a geometric sequence
diverge a series is said to diverge if the sum is not a real number
geometric sequence a sequence in which the ratio of a term to a previous term is a constant
geometric series the sum of the terms in a geometric sequence
infinite series the sum of the terms in an infinite sequence
series the sum of the terms in a sequence
summation notation a notation for series using the Greek letter sigma; it includes an explicit formula and specifies the first and last terms in the series