Companies often make large purchases, such as computers and vehicles, for business use. The bookvalue of these supplies decreases each year for tax purposes. This decrease in value is called depreciation. One method of calculating depreciation is straightline depreciation, in which the value of the asset decreases by the same amount each year.
As an example, consider a woman who starts a small contracting business. She purchases a new truck for $25,000. After five years, she estimates that she will be able to sell the truck for $8,000. The loss in value of the truck will therefore be $17,000, which is $3,400 per year for five years. The truck will be worth $21,600 after the first year; $18,200 after two years; $14,800 after three years; $11,400 after four years; and $8,000 at the end of five years. In this section, we will consider specific kinds of sequences that will allow us to calculate depreciation, such as the truck’s value.
Finding Common Differences
The values of the truck in the example are said to form an arithmetic sequence because they change by a constant amount each year. Each term increases or decreases by the same constant value called the common difference of the sequence. For this sequence, the common difference is –3,400.
The sequence below is another example of an arithmetic sequence. In this case, the constant difference is 3. You can choose any term of the sequence, and add 3 to find the subsequent term.
An arithmetic sequence is a sequence that has the property that the difference between any two consecutive terms is a constant. This constant is called the common difference. If ${a}_{1}$ is the first term of an arithmetic sequence and $d$ is the common difference, the sequence will be:
Is each sequence arithmetic? If so, find the common difference.
 $\{1,2,4,8,16,\mathrm{...}\}$
 $\{3,1,5,9,13,\mathrm{...}\}$
Subtract each term from the subsequent term to determine whether a common difference exists.
 The sequence is not arithmetic because there is no common difference.
 The sequence is arithmetic because there is a common difference. The common difference is 4.
If we are told that a sequence is arithmetic, do we have to subtract every term from the following term to find the common difference?
No. If we know that the sequence is arithmetic, we can choose any one term in the sequence, and subtract it from the subsequent term to find the common difference.
Is the given sequence arithmetic? If so, find the common difference.
The sequence is arithmetic. The common difference is $\u20132.$
Is the given sequence arithmetic? If so, find the common difference.
The sequence is not arithmetic because $31\ne 63.$
Writing Terms of Arithmetic Sequences
Now that we can recognize an arithmetic sequence, we will find the terms if we are given the first term and the common difference. The terms can be found by beginning with the first term and adding the common difference repeatedly. In addition, any term can also be found by plugging in the values of $n$ and $d$ into formula below.
Given the first term and the common difference of an arithmetic sequence, find the first several terms.
 Add the common difference to the first term to find the second term.
 Add the common difference to the second term to find the third term.
 Continue until all of the desired terms are identified.
 Write the terms separated by commas within brackets.
Write the first five terms of the arithmetic sequence with ${a}_{1}=17$ and $d=3$.
Adding$\text{\hspace{0.17em}}3\text{\hspace{0.17em}}$is the same as subtracting 3. Beginning with the first term, subtract 3 from each term to find the next term.
The first five terms are $\text{\hspace{0.17em}}\{17,\text{\hspace{0.17em}}14,\text{\hspace{0.17em}}11,\text{\hspace{0.17em}}8,\text{\hspace{0.17em}}5\}$
As expected, the graph of the sequence consists of points on a line as shown in [link].
List the first five terms of the arithmetic sequence with ${a}_{1}=1$ and $d=5$.
$\left\{1,6,11,16,21\right\}$
Given any the first term and any other term in an arithmetic sequence, find a given term.
 Substitute the values given for ${a}_{1},{a}_{n},n$ into the formula$\text{\hspace{0.17em}}{a}_{n}={a}_{1}+(n1)d\text{\hspace{0.17em}}$to solve for$\text{\hspace{0.17em}}d.$
 Find a given term by substituting the appropriate values for$\text{\hspace{0.17em}}{a}_{1},n,\text{\hspace{0.17em}}$and$\text{\hspace{0.17em}}d\text{\hspace{0.17em}}$into the formula${a}_{n}={a}_{1}+(n1)d.$
Given ${a}_{1}=8$ and ${a}_{4}=14$, find ${a}_{5}$.
The sequence can be written in terms of the initial term 8 and the common difference $d$.
We know the fourth term equals 14; we know the fourth term has the form ${a}_{1}+3d=8+3d$.
We can find the common difference $d$.
Find the fifth term by adding the common difference to the fourth term.
Notice that the common difference is added to the first term once to find the second term, twice to find the third term, three times to find the fourth term, and so on. The tenth term could be found by adding the common difference to the first term nine times or by using the equation ${a}_{n}={a}_{1}+\left(n1\right)d.$
Given ${a}_{3}=7$ and ${a}_{5}=17$, find ${a}_{2}$.
${a}_{2}=2$
Using Recursive Formulas for Arithmetic Sequences
Some arithmetic sequences are defined in terms of the previous term using a recursive formula. The formula provides an algebraic rule for determining the terms of the sequence. A recursive formula allows us to find any term of an arithmetic sequence using a function of the preceding term. Each term is the sum of the previous term and the common difference. For example, if the common difference is 5, then each term is the previous term plus 5. As with any recursive formula, the first term must be given.
The recursive formula for an arithmetic sequence with common difference $d$ is:
Given an arithmetic sequence, write its recursive formula.
 Subtract any term from the subsequent term to find the common difference.
 State the initial term and substitute the common difference into the recursive formula for arithmetic sequences.
Write a recursive formula for the arithmetic sequence.
The first term is given as $\mathrm{18}$. The common difference can be found by subtracting the first term from the second term.
Substitute the initial term and the common difference into the recursive formula for arithmetic sequences.
We see that the common difference is the slope of the line formed when we graph the terms of the sequence, as shown in [link]. The growth pattern of the sequence shows the constant difference of 11 units.
Do we have to subtract the first term from the second term to find the common difference?
No. We can subtract any term in the sequence from the subsequent term. It is, however, most common to subtract the first term from the second term because it is often the easiest method of finding the common difference.
Write a recursive formula for the arithmetic sequence.
$\begin{array}{l}{a}_{1}=25\hfill \\ {a}_{n}={a}_{n1}+12,\text{for}n\ge 2\hfill \end{array}$
Using Explicit Formulas for Arithmetic Sequences
We can think of an arithmetic sequence as a function on the domain of the natural numbers; it is a linear function because it has a constant rate of change. The common difference is the constant rate of change, or the slope of the function. We can construct the linear function if we know the slope and the vertical intercept.
To find the yintercept of the function, we can subtract the common difference from the first term of the sequence. Consider the following sequence.
The common difference is $50$, so the sequence represents a linear function with a slope of $50$. To find the $y$intercept, we subtract $50$ from$200:\text{\hspace{0.17em}}200(50)=200+50=250$. You can also find the $y$intercept by graphing the function and determining where a line that connects the points would intersect the vertical axis. The graph is shown in [link].
Recall the slopeintercept form of a line is$\text{\hspace{0.17em}}y=mx+b.\text{\hspace{0.17em}}$When dealing with sequences, we use ${a}_{n}$ in place of $y$ and $n$ in place of $x.\text{\hspace{0.17em}}$If we know the slope and vertical intercept of the function, we can substitute them for $m$ and $b$ in the slopeintercept form of a line. Substituting$\text{\hspace{0.17em}}50\text{\hspace{0.17em}}$for the slope and $250$ for the vertical intercept, we get the following equation:
We do not need to find the vertical intercept to write an explicit formula for an arithmetic sequence. Another explicit formula for this sequence is ${a}_{n}=20050(n1)$, which simplifies to$\text{\hspace{0.17em}}{a}_{n}=50n+250.$
An explicit formula for the $n\text{th}$ term of an arithmetic sequence is given by
Given the first several terms for an arithmetic sequence, write an explicit formula.
 Find the common difference, ${a}_{2}{a}_{1}.$
 Substitute the common difference and the first term into ${a}_{n}={a}_{1}+d(n1).$
Write an explicit formula for the arithmetic sequence.
The common difference can be found by subtracting the first term from the second term.
The common difference is 10. Substitute the common difference and the first term of the sequence into the formula and simplify.
The graph of this sequence, represented in [link], shows a slope of 10 and a vertical intercept of $8$.
Write an explicit formula for the following arithmetic sequence.
${a}_{n}=533n$
Finding the Number of Terms in a Finite Arithmetic Sequence
Explicit formulas can be used to determine the number of terms in a finite arithmetic sequence. We need to find the common difference, and then determine how many times the common difference must be added to the first term to obtain the final term of the sequence.
Given the first three terms and the last term of a finite arithmetic sequence, find the total number of terms.
 Find the common difference $d.$
 Substitute the common difference and the first term into ${a}_{n}={a}_{1}+d(n\u20131).$
 Substitute the last term for ${a}_{n}$ and solve for $n.$
Find the number of terms in the finite arithmetic sequence.
The common difference can be found by subtracting the first term from the second term.
The common difference is $7$. Substitute the common difference and the initial term of the sequence into the $n\text{th}$ term formula and simplify.
Substitute $41$ for ${a}_{n}$ and solve for $n$
There are eight terms in the sequence.
Find the number of terms in the finite arithmetic sequence.
There are 11 terms in the sequence.
Solving Application Problems with Arithmetic Sequences
In many application problems, it often makes sense to use an initial term of ${a}_{0}$ instead of ${a}_{1}.$ In these problems, we alter the explicit formula slightly to account for the difference in initial terms. We use the following formula:
A fiveyear old child receives an allowance of $1 each week. His parents promise him an annual increase of $2 per week.
 Write a formula for the child’s weekly allowance in a given year.
 What will the child’s allowance be when he is 16 years old?

The situation can be modeled by an arithmetic sequence with an initial term of 1 and a common difference of 2.
Let $A$ be the amount of the allowance and $n$ be the number of years after age 5. Using the altered explicit formula for an arithmetic sequence we get:

We can find the number of years since age 5 by subtracting.
We are looking for the child’s allowance after 11 years. Substitute 11 into the formula to find the child’s allowance at age 16.
The child’s allowance at age 16 will be $23 per week.
A woman decides to go for a 10minute run every day this week and plans to increase the time of her daily run by 4 minutes each week. Write a formula for the time of her run after n weeks. How long will her daily run be 8 weeks from today?
The formula is ${T}_{n}=10+4n,\text{\hspace{0.17em}}$and it will take her 42 minutes.
Access this online resource for additional instruction and practice with arithmetic sequences.
Key Equations
recursive formula for nth term of an arithmetic sequence  ${a}_{n}={a}_{n1}+d\phantom{\rule{1}{0ex}}n\ge 2$ 
explicit formula for nth term of an arithmetic sequence  $\begin{array}{l}{a}_{n}={a}_{1}+d(n1)\end{array}$ 
Key Concepts
 An arithmetic sequence is a sequence where the difference between any two consecutive terms is a constant.
 The constant between two consecutive terms is called the common difference.
 The common difference is the number added to any one term of an arithmetic sequence that generates the subsequent term. See [link].
 The terms of an arithmetic sequence can be found by beginning with the initial term and adding the common difference repeatedly. See [link] and [link].
 A recursive formula for an arithmetic sequence with common difference $d$ is given by ${a}_{n}={a}_{n1}+d,n\ge 2.$ See [link].
 As with any recursive formula, the initial term of the sequence must be given.
 An explicit formula for an arithmetic sequence with common difference $d$ is given by ${a}_{n}={a}_{1}+d(n1).$ See [link].
 An explicit formula can be used to find the number of terms in a sequence. See [link].
 In application problems, we sometimes alter the explicit formula slightly to ${a}_{n}={a}_{0}+dn.$ See [link].
Section Exercises
Verbal
What is an arithmetic sequence?
A sequence where each successive term of the sequence increases (or decreases) by a constant value.
How is the common difference of an arithmetic sequence found?
How do we determine whether a sequence is arithmetic?
We find whether the difference between all consecutive terms is the same. This is the same as saying that the sequence has a common difference.
What are the main differences between using a recursive formula and using an explicit formula to describe an arithmetic sequence?
Describe how linear functions and arithmetic sequences are similar. How are they different?
Both arithmetic sequences and linear functions have a constant rate of change. They are different because their domains are not the same; linear functions are defined for all real numbers, and arithmetic sequences are defined for natural numbers or a subset of the natural numbers.
Algebraic
For the following exercises, find the common difference for the arithmetic sequence provided.
$\{5,11,17,23,29,\mathrm{...}\}$
$\left\{0,\frac{1}{2},1,\frac{3}{2},2,\mathrm{...}\right\}$
The common difference is $\frac{1}{2}$
For the following exercises, determine whether the sequence is arithmetic. If so find the common difference.
$\{11.4,9.3,7.2,5.1,3,\mathrm{...}\}$
$\{4,16,64,256,1024,\mathrm{...}\}$
The sequence is not arithmetic because $164\ne 6416.$
For the following exercises, write the first five terms of the arithmetic sequence given the first term and common difference.
${a}_{1}=\mathrm{25}$, $d=\mathrm{9}$
${a}_{1}=0$, $d=\frac{2}{3}$
$$0,\text{\hspace{0.17em}}\frac{2}{3},\text{\hspace{0.17em}}\frac{4}{3},\text{\hspace{0.17em}}2,\text{\hspace{0.17em}}\frac{8}{3}$$
For the following exercises, write the first five terms of the arithmetic series given two terms.
${a}_{1}=17,\text{\hspace{0.17em}}{a}_{7}=31$
${a}_{13}=60,\text{\hspace{0.17em}}{a}_{33}=160$
$0,5,10,15,20$
For the following exercises, find the specified term for the arithmetic sequence given the first term and common difference.
First term is 3, common difference is 4, find the 5^{th} term.
First term is 4, common difference is 5, find the 4^{th} term.
${a}_{4}=19$
First term is 5, common difference is 6, find the 8^{th} term.
First term is 6, common difference is 7, find the 6^{th} term.
${a}_{6}=41$
First term is 7, common difference is 8, find the 7^{th} term.
For the following exercises, find the first term given two terms from an arithmetic sequence.
Find the first term or ${a}_{1}$ of an arithmetic sequence if ${a}_{6}=12$ and ${a}_{14}=28.$
${a}_{1}=2$
Find the first term or ${a}_{1}$ of an arithmetic sequence if ${a}_{7}=21$ and ${a}_{15}=42.\text{\hspace{0.17em}}$
Find the first term or ${a}_{1}$ of an arithmetic sequence if ${a}_{8}=40$ and ${a}_{23}=115.$
${a}_{1}=5$
Find the first term or ${a}_{1}$ of an arithmetic sequence if ${a}_{9}=54$ and ${a}_{17}=102.$
Find the first term or ${a}_{1}$ of an arithmetic sequence if ${a}_{11}=11$ and ${a}_{21}=16.$
${a}_{1}=6$
For the following exercises, find the specified term given two terms from an arithmetic sequence.
${a}_{1}=33\text{\hspace{0.17em}}$and$\text{\hspace{0.17em}}{a}_{7}=15.$ Find$\text{\hspace{0.17em}}{a}_{4}.$
${a}_{3}=17.1\text{\hspace{0.17em}}$and$\text{\hspace{0.17em}}{a}_{10}=\mathrm{15.7.}$ Find${a}_{21}.$
${a}_{21}=13.5$
For the following exercises, use the recursive formula to write the first five terms of the arithmetic sequence.
${a}_{1}=39;\text{}{a}_{n}={a}_{n1}3$
${a}_{1}=19;\text{}{a}_{n}={a}_{n1}1.4$
$19,20.4,21.8,23.2,24.6$
For the following exercises, write a recursive formula for each arithmetic sequence.
${a}_{n}=\left\{40,60,80,\mathrm{...}\right\}$
${a}_{n}=\{17,26,35,\mathrm{...}\}$
$\begin{array}{ll}{a}_{1}=17;{a}_{n}={a}_{n1}+9\hfill & n\ge 2\hfill \end{array}$
${a}_{n}=\{1,2,5,\mathrm{...}\}$
${a}_{n}=\{12,17,22,\mathrm{...}\}$
$\begin{array}{ll}{a}_{1}=12;{a}_{n}={a}_{n1}+5\hfill & n\ge 2\hfill \end{array}$
${a}_{n}=\{15,7,1,\mathrm{...}\}$
${a}_{n}=\{8.9,10.3,11.7,\mathrm{...}\}$
$\begin{array}{ll}{a}_{1}=8.9;{a}_{n}={a}_{n1}+1.4\hfill & n\ge 2\hfill \end{array}$
${a}_{n}=\{0.52,1.02,1.52,\mathrm{...}\}$
${a}_{n}=\left\{\frac{1}{5},\frac{9}{20},\frac{7}{10},\mathrm{...}\right\}$
$\begin{array}{ll}{a}_{1}=\frac{1}{5};{a}_{n}={a}_{n1}+\frac{1}{4}\hfill & n\ge 2\hfill \end{array}$
${a}_{n}=\left\{\frac{1}{2},\frac{5}{4},2,\mathrm{...}\right\}$
${a}_{n}=\left\{\frac{1}{6},\frac{11}{12},2,\mathrm{...}\right\}$
$\begin{array}{ll}{}_{1}=\frac{1}{6};{a}_{n}={a}_{n1}\frac{13}{12}\hfill & n\ge 2\hfill \end{array}$
For the following exercises, write a recursive formula for the given arithmetic sequence, and then find the specified term.
${a}_{n}=\left\{7\text{,}4\text{,}1\text{,}\mathrm{...}\right\};\text{\hspace{0.17em}}$Find the 17^{th} term.
${a}_{n}=\left\{4\text{,}11\text{,}18\text{,}\mathrm{...}\right\};\text{\hspace{0.17em}}$Find the 14^{th} term.
${a}_{1}=4;\text{}{a}_{n}={a}_{n1}+7;\text{}{a}_{14}=95$
${a}_{n}=\left\{2\text{,}6\text{,}10\text{,}\mathrm{...}\right\};\text{\hspace{0.17em}}$Find the 12^{th} term.
For the following exercises, use the explicit formula to write the first five terms of the arithmetic sequence.
${a}_{n}=244n$
First five terms: $20,16,12,8,4.$
${a}_{n}=\frac{1}{2}n\frac{1}{2}$
For the following exercises, write an explicit formula for each arithmetic sequence.
${a}_{n}=\{3,5,7,\mathrm{...}\}$
${a}_{n}=1+2n$
${a}_{n}=\{32,24,16,\mathrm{...}\}$
${a}_{n}=\{5\text{,}95\text{,}195\text{,}\mathrm{...}\}$
${a}_{n}=105+100n$
${a}_{n}=\left\{\mathrm{17}\text{,}\mathrm{217}\text{,}\mathrm{417}\text{,}\mathrm{...}\right\}$
${a}_{n}=\left\{1.8\text{,}3.6\text{,}5.4\text{,}\mathrm{...}\right\}$
${a}_{n}=1.8n$
${a}_{n}=\{\mathrm{18.1},\mathrm{16.2},\mathrm{14.3},\mathrm{...}\}$
${a}_{n}=\{15.8,18.5,21.2,\mathrm{...}\}$
${a}_{n}=13.1+2.7n$
${a}_{n}=\left\{\frac{1}{3},\frac{4}{3},\mathrm{3}\text{,}\mathrm{...}\right\}$
${a}_{n}=\left\{0,\frac{1}{3},\frac{2}{3},\mathrm{...}\right\}$
${a}_{n}=\frac{1}{3}n\frac{1}{3}$
${a}_{n}=\left\{5,\frac{10}{3},\frac{5}{3},\dots \right\}$
For the following exercises, find the number of terms in the given finite arithmetic sequence.
${a}_{n}=\{3\text{,}4\text{,}11\text{,}\mathrm{...}\text{,}60\}$
There are 10 terms in the sequence.
${a}_{n}=\{1.2,1.4,1.6,\mathrm{...},3.8\}$
${a}_{n}=\left\{\frac{1}{2},2,\frac{7}{2},\mathrm{...},8\right\}$
There are 6 terms in the sequence.
Graphical
For the following exercises, determine whether the graph shown represents an arithmetic sequence.
The graph does not represent an arithmetic sequence.
For the following exercises, use the information provided to graph the first 5 terms of the arithmetic sequence.
${a}_{1}=0,d=4$
${a}_{1}=9;{a}_{n}={a}_{n1}10$
${a}_{n}=12+5n$
Technology
For the following exercises, follow the steps to work with the arithmetic sequence ${a}_{n}=3n2$ using a graphing calculator:
 Press [MODE]
 Select SEQ in the fourth line
 Select DOT in the fifth line
 Press [ENTER]
 Press [Y=]
 $n\text{Min}\text{\hspace{0.17em}}$is the first counting number for the sequence. Set $\text{\hspace{0.17em}}n\text{Min}=1$
 $u(n)\text{\hspace{0.17em}}$is the pattern for the sequence. Set $\text{\hspace{0.17em}}u(n)=3n2$
 $u(n\text{Min)}\text{\hspace{0.17em}}$is the first number in the sequence. Set $\text{\hspace{0.17em}}u(n\text{Min)}=1$
 Press [2ND] then [WINDOW] to go to TBLSET
 Set$\text{\hspace{0.17em}}\text{TblStart}=1$
 Set$\text{\hspace{0.17em}}\Delta \text{Tbl}=1$
 Set Indpnt: Auto and Depend: Auto
 Press [2ND] then [GRAPH] to go to the TABLE
What are the first seven terms shown in the column with the heading $u(n)\text{?}$
$1,4,7,10,13,16,19$
Use the scrolldown arrow to scroll to$n=50.$ What value is given for $u(n)\text{?}$
Press [WINDOW]. Set$\text{\hspace{0.17em}}n\text{Min}=1,n\text{Max}=5,x\text{Min}=0,x\text{Max}=6,y\text{Min}=1,\text{\hspace{0.17em}}$and$\text{\hspace{0.17em}}y\text{Max}=14.\text{\hspace{0.17em}}$Then press [GRAPH]. Graph the sequence as it appears on the graphing calculator.
For the following exercises, follow the steps given above to work with the arithmetic sequence ${a}_{n}=\frac{1}{2}n+5$ using a graphing calculator.
What are the first seven terms shown in the column with the heading$\text{\hspace{0.17em}}u(n)\text{\hspace{0.17em}}$in the TABLE feature?
Graph the sequence as it appears on the graphing calculator. Be sure to adjust the WINDOW settings as needed.
Extensions
Give two examples of arithmetic sequences whose 4^{th} terms are $9.$
Give two examples of arithmetic sequences whose 10^{th} terms are $206.$
Answers will vary. Examples: ${a}_{n}=20.6n$and${a}_{n}=2+20.4\mathrm{n.}$
Find the 5^{th} term of the arithmetic sequence $\{9b,5b,b,\dots \}.$
Find the 11^{th} term of the arithmetic sequence $\{3a2b,a+2b,a+6b\dots \}.$
${a}_{11}=17a+38b$
At which term does the sequence $\{5.4,14.5,23.6,\mathrm{...}\}$ exceed 151?
At which term does the sequence $\left\{\frac{17}{3},\frac{31}{6},\frac{14}{3},\mathrm{...}\right\}$ begin to have negative values?
The sequence begins to have negative values at the 13^{th} term, ${a}_{13}=\frac{1}{3}$
For which terms does the finite arithmetic sequence $\left\{\frac{5}{2},\frac{19}{8},\frac{9}{4},\mathrm{...},\frac{1}{8}\right\}$ have integer values?
Write an arithmetic sequence using a recursive formula. Show the first 4 terms, and then find the 31^{st} term.
Answers will vary. Check to see that the sequence is arithmetic. Example: Recursive formula: ${a}_{1}=3,{a}_{n}={a}_{n1}3.$ First 4 terms: $\begin{array}{ll}3,0,3,6\hfill & {a}_{31}=87\hfill \end{array}$
Write an arithmetic sequence using an explicit formula. Show the first 4 terms, and then find the 28^{th} term.
 Precalculus
 Preface
 Functions
 Linear Functions
 Polynomial and Rational Functions
 Exponential and Logarithmic Functions
 Trigonometric Functions
 Periodic Functions
 Trigonometric Identities and Equations
 Further Applications of Trigonometry
 Systems of Equations and Inequalities
 Introduction to Systems of Equations and Inequalities
 Systems of Linear Equations: Two Variables
 Systems of Linear Equations: Three Variables
 Systems of Nonlinear Equations and Inequalities: Two Variables
 Partial Fractions
 Matrices and Matrix Operations
 Solving Systems with Gaussian Elimination
 Solving Systems with Inverses
 Solving Systems with Cramer's Rule
 Analytic Geometry
 Sequences, Probability and Counting Theory
 Introduction to Calculus
 Appendix
The graph of each of these sequences is shown in [link]. We can see from the graphs that, although both sequences show growth, $a$ is not linear whereas $b$ is linear. Arithmetic sequences have a constant rate of change so their graphs will always be points on a line.