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# 9.2: Arithmetic Sequences and Series

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Skills to Develop

• Identify the common difference of an arithmetic sequence.
• Find a formula for the general term of an arithmetic sequence.
• Calculate the $$n$$th partial sum of an arithmetic sequence.

## Arithmetic Sequences

An arithmetic sequence12, or arithmetic progression13, is a sequence of numbers where each successive number is the sum of the previous number and some constant $$d$$.

$$a_{n}=a_{n-1}+d \quad\color{Cerulean}{Arithmetic\:sequence}$$

And because $$a_{n}-a_{n-1}=d$$, the constant $$d$$ is called the common difference14. For example, the sequence of positive odd integers is an arithmetic sequence,

$$1,3,5,7,9, \ldots$$

Here $$a_{1} = 1$$ and the difference between any two successive terms is $$2$$. We can construct the general term $$a_{n}=a_{n-1}+2$$ where,

$$a_{1}=1$$
$$a_{2}=a_{1}+2=1+2=3$$
$$a_{3}=a_{2}+2=3+2=5$$
$$a_{4}=a_{3}+2=5+2=7$$
$$a_{5}=a_{4}+2=7+2=9$$
$$\vdots$$

In general, given the first term $$a_{1}$$ of an arithmetic sequence and its common difference $$d$$, we can write the following:

$$\begin{array}{l}{a_{2}=a_{1}+d} \\ {a_{3}=a_{2}+d=\left(a_{1}+d\right)+d=a_{1}+2 d} \\ {a_{4}=a_{3}+d=\left(a_{1}+2 d\right)+d=a_{1}+3 d} \\ {a_{5}=a_{4}+d=\left(a_{1}+3 d\right)+d=a_{1}+4 d} \\ {\quad\:\:\vdots}\end{array}$$

From this we see that any arithmetic sequence can be written in terms of its first element, common difference, and index as follows:

$$a_{n}=a_{1}+(n-1) d \quad\color{Cerulean}{Arithmetic\:Sequence}$$

In fact, any general term that is linear in $$n$$ defines an arithmetic sequence.

Example $$\PageIndex{1}$$:

Find an equation for the general term of the given arithmetic sequence and use it to calculate its $$100^{th}$$ term: $$7, 10, 13, 16, 19, …$$

Solution

Begin by finding the common difference,

$$d=10-7=3$$

Note that the difference between any two successive terms is $$3$$. The sequence is indeed an arithmetic progression where $$a_{1} = 7$$ and $$d = 3$$.

\begin{aligned} a_{n} &=a_{1}+(n-1) d \\ &=7+(n-1) \cdot 3 \\ &=7+3 n-3 \\ &=3 n+4 \end{aligned}

Therefore, we can write the general term $$a_{n} = 3n + 4$$. Take a minute to verify that this equation describes the given sequence. Use this equation to find the $$100^{th}$$ term:

$$a_{100}=3(100)+4=304$$

$$a_{n}=3 n+4 ; a_{100}=304$$

The common difference of an arithmetic sequence may be negative.

Example $$\PageIndex{2}$$:

Find an equation for the general term of the given arithmetic sequence and use it to calculate its $$75^{th}$$ term: $$6, 4, 2, 0, −2, …$$

Solution

Begin by finding the common difference,

$$d=4-6=-2$$

Next find the formula for the general term, here $$a_{1} = 6$$ and $$d = −2$$.

\begin{aligned} a_{n} &=a_{1}+(n-1) d \\ &=6+(n-1) \cdot(-2) \\ &=6-2 n+2 \\ &=8-2 n \end{aligned}

Therefore, $$a_{n} = 8 − 2n$$ and the $$75^{th}$$ term can be calculated as follows:

\begin{aligned} a_{75} &=8-2(75) \\ &=8-150 \\ &=-142 \end{aligned}

$$a_{n}=8-2 n ; a_{100}=-142$$

The terms between given terms of an arithmetic sequence are called arithmetic means15.

Example $$\PageIndex{3}$$:

Find all terms in between $$a_{1}=-8$$ and $$a_{7} = 10$$ of an arithmetic sequence. In other words, find all arithmetic means between the $$1^{st}$$ and $$7^{th}$$ terms.

Solution

Begin by finding the common difference $$d$$. In this case, we are given the first and seventh term:

$$\begin{array}{l}{a_{n}=a_{1}+(n-1) d\quad \color{Cerulean} { Use \: n=7.}} \\ {a_{7}=a_{1}+(7-1) d} \\ {a_{7}=a_{1}+6 d}\end{array}$$

Substitute $$a_{1} = −8$$ and $$a_{7} = 10$$ into the above equation and then solve for the common difference $$d$$.

\begin{aligned} 10 &=-8+6 d \\ 18 &=6 d \\ 3 &=d \end{aligned}

Next, use the first term $$a_{1} = −8$$ and the common difference $$d = 3$$ to find an equation for the $$n$$th term of the sequence.

\begin{aligned} a_{n} &=-8+(n-1) \cdot 3 \\ &=-8+3 n-3 \\ &=-11+3 n \end{aligned}

With $$a_{n} = 3n − 11$$, where $$n$$ is a positive integer, find the missing terms.

\left. \begin{aligned} a_{1}&=3(1)-11=3-11=-8\\ a_{2} &=3(2)-11=6-11=-5 \\ a_{3} &=3(3)-11=9-11=-2 \\ a_{4} &=3(4)-11=12-11=1 \\ a_{5} &=3(5)-11=15-11=4 \\ a_{6} &=3(6)-11=18-11=7 \\ a_{7}&=3(7)-11=21-111=10 \end{aligned} \right\} \color{Cerulean}{arithmetic\:means}

$$-5,-2,1,4,7$$

In some cases, the first term of an arithmetic sequence may not be given.

Example $$\PageIndex{4}$$:

Find the general term of an arithmetic sequence where $$a_{3} = −1$$ and $$a_{10} = 48$$.

Solution

To determine a formula for the general term we need $$a_{1}$$ and $$d$$. A linear system with these as variables can be formed using the given information and $$a_{n}=a_{1}+(n-1) d$$:

$$\left\{\begin{array}{c}{a_{3}=a_{1}+(3-1) d} \\ {a_{10}=a_{1}+(10-1) d}\end{array}\right. \Rightarrow \left\{\begin{array}{l}{-1=a_{1}+2 d \quad\color{Cerulean}{Use \:a_{3}=-1.}} \\ {48=a_{1}+9 d\quad\:\color{Cerulean}{Use\: a_{10}=48.}}\end{array}\right.$$

Eliminate $$a_{1}$$ by multiplying the first equation by $$−1$$ and add the result to the second equation.

$$\left\{\begin{array}{l}{-1=a_{1}+2 d} \\ {48=a_{1}+9 d}\end{array}\right. \quad\stackrel{\color{Cerulean}{x(-1)}}{\Longrightarrow} \color{black}{+} \left\{\begin{array}{l} {1=-a_{1}-2d} \\ {48=a_{1}+9d} \end{array}\right. \\$$

\begin{aligned} 49 &=7 d \\ 7 &=d \end{aligned}

Substitute $$d = 7$$ into $$−1 = a_{1} + 2d$$ to find $$a_{1}$$.

$$-1=a_{1}+2(7)$$
$$-1=a_{1}+14$$
$$-15=a_{1}$$

Next, use the first term $$a_{1} = −15$$ and the common difference $$d = 7$$ to find a formula for the general term.

\begin{aligned} a_{n} &=a_{1}+(n-1) d \\ &=-15+(n-1) \cdot 7 \\ &=-15+7 n-7 \\ &=-22+7 n \end{aligned}

$$a_{n}=7 n-22$$

Exercise $$\PageIndex{1}$$

Find an equation for the general term of the given arithmetic sequence and use it to calculate its $$100^{th}$$ term: $$\frac{3}{2}, 2, \frac{5}{2}, 3, \frac{7}{2}, \dots$$

$$a_{n}=\frac{1}{2} n+1; a_{100}=51$$

## Arithmetic Series

An arithmetic series16 is the sum of the terms of an arithmetic sequence. For example, the sum of the first $$5$$ terms of the sequence defined by $$a_{n} = 2n − 1$$ follows:

\begin{aligned} S_{5} &=\sum_{n=1}^{5}(2 n-1) \\ &=[2(\color{Cerulean}{1}\color{black}{)}-1]+[2(\color{Cerulean}{2}\color{black}{)}-1]+[2(\color{Cerulean}{3}\color{black}{)}-1]+[2(\color{Cerulean}{4}\color{black}{)}-1]+[2(\color{Cerulean}{5}\color{black}{)}-1] \\ &=1+3+5+7+9 \\ &=25 \end{aligned}

Adding $$5$$ positive odd integers, as we have done above, is managable. However, consider adding the first $$100$$ positive odd integers. This would be very tedious. Therefore, we next develop a formula that can be used to calculate the sum of the first $$n$$ terms, denoted $$S_{n}$$, of any arithmetic sequence. In general,

$$S_{n}=a_{1}+\left(a_{1}+d\right)+\left(a_{1}+2 d\right)+\ldots+a_{n}$$

Writing this series in reverse we have,

$$S_{n}=a_{n}+\left(a_{n}-d\right)+\left(a_{n}-2 d\right)+\ldots+a_{1}$$

And adding these two equations together, the terms involving $$d$$ add to zero and we obtain $$n$$ factors of $$a_{1} + a_{n}$$:

$$2 S_{n}=\left(a_{1}+a_{n}\right)+\left(a_{1}+a_{n}\right)+\ldots+\left(a_{n}+a_{1}\right)$$
$$2 S_{n}=n\left(a_{1}+a_{n}\right)$$

Dividing both sides by $$2$$ leads us the formula for the $$n$$th partial sum of an arithmetic sequence17:

$$S_{n}=\frac{n\left(a_{1}+a_{n}\right)}{2}$$

Use this formula to calculate the sum of the first $$100$$ terms of the sequence defined by $$a_{n} = 2n − 1$$. Here $$a_{1} = 1$$ and $$a_{100} = 199$$.

\begin{aligned} S_{100} &=\frac{100\left(a_{1}+a_{100}\right)}{2} \\ &=\frac{100(1+199)}{2} \\ &=10,000 \end{aligned}

Example $$\PageIndex{5}$$:

Find the sum of the first $$50$$ terms of the given sequence: $$4,9,14,19,24, \dots$$

Solution

Determine whether or not there is a common difference between the given terms.

$$d=9-4=5$$

Note that the difference between any two successive terms is $$5$$. The sequence is indeed an arithmetic progression and we can write

\begin{aligned} a_{n} &=a_{1}+(n-1) d \\ &=4+(n-1) \cdot 5 \\ &=4+5 n-5 \\ &=5 n-1 \end{aligned}

Therefore, the general term is $$a_{n} = 5n − 1$$. To calculate the $$50^{th}$$ partial sum of this sequence we need the $$1^{st}$$ and the $$50^{th}$$ terms:

\begin{aligned} a_{1} &=4 \\ a_{50} &=5(50)-1=249 \end{aligned}

Next use the formula to determine the $$50^{th}$$ partial sum of the given arithmetic sequence.

\begin{aligned} S_{n} &=\frac{n\left(a_{1}+a_{n}\right)}{2} \\ S_{50} &=\frac{50 \cdot\left(a_{1}+a_{50}\right)}{2} \\ &=\frac{50(4+249)}{2} \\ &=25(253) \\ &=6,325 \end{aligned}

$$S_{50}=6,325$$

Example $$\PageIndex{6}$$:

Evaluate: $$\sum_{n=1}^{35}(10-4 n)$$.

Solution

In this case, we are asked to find the sum of the first $$35$$ terms of an arithmetic sequence with general term $$a_{n} = 10 − 4n$$. Use this to determine the $$1^{st}$$ and the $$35^{th}$$ term.

$$a_{1}=10-4(1)=6$$
$$a_{35}=10-4(35)=-130$$

Next use the formula to determine the $$35^{th}$$ partial sum.

\begin{aligned} S_{n} &=\frac{n\left(a_{1}+a_{n}\right)}{2} \\ S_{35} &=\frac{35 \cdot\left(a_{1}+a_{35}\right)}{2} \\ &=\frac{35[6+(-130)]}{2} \\ &=\frac{35(-124)}{2} \\ &=-2,170 \end{aligned}

$$-2,170$$

Example $$\PageIndex{7}$$:

The first row of seating in an outdoor amphitheater contains $$26$$ seats, the second row contains $$28$$ seats, the third row contains $$30$$ seats, and so on. If there are $$18$$ rows, what is the total seating capacity of the theater?

Solution

Begin by finding a formula that gives the number of seats in any row. Here the number of seats in each row forms a sequence:

$$26,28,30, \dots$$

Note that the difference between any two successive terms is $$2$$. The sequence is an arithmetic progression where $$a_{1} = 26$$ and $$d = 2$$.

\begin{aligned} a_{n} &=a_{1}+(n-1) d \\ &=26+(n-1) \cdot 2 \\ &=26+2 n-2 \\ &=2 n+24 \end{aligned}

Therefore, the number of seats in each row is given by $$a_{n} = 2n + 24$$. To calculate the total seating capacity of the $$18$$ rows we need to calculate the $$18^{th}$$ partial sum. To do this we need the $$1^{st}$$ and the $$18^{th}$$ terms:

\begin{aligned} a_{1} &=26 \\ a_{18} &=2(18)+24=60 \end{aligned}

Use this to calculate the $$18^{th}$$ partial sum as follows:

\begin{aligned} S_{n} &=\frac{n\left(a_{1}+a_{n}\right)}{2} \\ S_{18} &=\frac{18 \cdot\left(a_{1}+a_{18}\right)}{2} \\ &=\frac{18(26+60)}{2} \\ &=9(86) \\ &=774 \end{aligned}

There are $$774$$ seats total.

Exercise $$\PageIndex{2}$$

Find the sum of the first $$60$$ terms of the given sequence: $$5, 0, −5, −10, −15, …$$

$$S_{60}=-8,550$$

## Key Takeaways

• An arithmetic sequence is a sequence where the difference $$d$$ between successive terms is constant.
• The general term of an arithmetic sequence can be written in terms of its first term $$a_{1}$$, common difference $$d$$, and index $$n$$ as follows: $$a_{n} = a_{1} + (n − 1) d$$.
• An arithmetic series is the sum of the terms of an arithmetic sequence.
• The $$n$$th partial sum of an arithmetic sequence can be calculated using the first and last terms as follows: $$S_{n}=\frac{n\left(a_{1}+a_{n}\right)}{2}$$.

Exercise $$\PageIndex{3}$$

Write the first $$5$$ terms of the arithmetic sequence given its first term and common difference. Find a formula for its general term.

1. $$a_{1}=5 ; d=3$$
2. $$a_{1}=12 ; d=2$$
3. $$a_{1}=15 ; d=-5$$
4. $$a_{1}=7 ; d=-4$$
5. $$a_{1}=\frac{1}{2} ; d=1$$
6. $$a_{1}=\frac{2}{3} ; d=\frac{1}{3}$$
7. $$a_{1}=1 ; d=-\frac{1}{2}$$
8. $$a_{1}=-\frac{5}{4} ; d=\frac{1}{4}$$
9. $$a_{1}=1.8 ; d=0.6$$
10. $$a_{1}=-4.3 ; d=2.1$$

1. $$5,8,11,14,17 ; a_{n}=3 n+2$$

3. $$15,10,5,0,-5 ; a_{n}=20-5 n$$

5. $$\frac{1}{2}, \frac{3}{2}, \frac{5}{2}, \frac{7}{2}, \frac{9}{2} ; a_{n}=n-\frac{1}{2}$$

7. $$1, \frac{1}{2}, 0,-\frac{1}{2},-1 ; a_{n}=\frac{3}{2}-\frac{1}{2} n$$

9. $$1.8,2.4,3,3.6,4.2 ; a_{n}=0.6 n+1.2$$

Exercise $$\PageIndex{4}$$

Given the arithmetic sequence, find a formula for the general term and use it to determine the $$100^{th}$$ term.

1. $$3, 9, 15, 21, 27,…$$
2. $$3, 8, 13, 18, 23,…$$
3. $$−3, −7, −11, −15, −19,…$$
4. $$−6, −14, −22, −30, −38,…$$
5. $$−5, −10, −15, −20, −25,…$$
6. $$2, 4, 6, 8, 10,…$$
7. $$\frac{1}{2}, \frac{5}{2}, \frac{9}{2}, \frac{13}{2}, \frac{17}{2}, \ldots$$
8. $$-\frac{1}{3}, \frac{2}{3}, \frac{5}{3}, \frac{8}{3}, \frac{11}{3}, \ldots$$
9. $$\frac{1}{3}, 0,-\frac{1}{3},-\frac{2}{3},-1, \ldots$$
10. $$\frac{1}{4},-\frac{1}{2},-\frac{5}{4},-2,-\frac{11}{4}, \ldots$$
11. $$0.8, 2, 3.2, 4.4, 5.6,…$$
12. $$4.4, 7.5, 10.6, 13.7, 16.8,…$$
13. Find the $$50^{th}$$ positive odd integer.
14. Find the $$50^{th}$$ positive even integer.
15. Find the $$40^{th}$$ term in the sequence that consists of every other positive odd integer: $$1, 5, 9, 13,…$$
16. Find the $$40^{th}$$ term in the sequence that consists of every other positive even integer: $$2, 6, 10, 14,…$$
17. What number is the term $$355$$ in the arithmetic sequence $$−15, −5, 5, 15, 25,…$$?
18. What number is the term $$−172$$ in the arithmetic sequence $$4, −4, −12, −20, −28,…$$?
19. Given the arithmetic sequence defined by the recurrence relation $$a_{n}=a_{n-1}+5$$ where $$a_{1} = 2$$ and $$n > 1$$, find an equation that gives the general term in terms of $$a_{1}$$ and the common difference $$d$$.
20. Given the arithmetic sequence defined by the recurrence relation $$a_{n}=a_{n-1}-9$$ where $$a_{1} = 4$$ and $$n > 1$$, find an equation that gives the general term in terms of $$a_{1}$$ and the common difference $$d$$.

1. $$a_{n}=6 n-3 ; a_{100}=597$$

3. $$a_{n}=1-4 n ; a_{100}=-399$$

5. $$a_{n}=-5 n ; a_{100}=-500$$

7. $$a_{n}=2 n-\frac{3}{2} ; a_{100}=\frac{397}{2}$$

9. $$a_{n}=\frac{2}{3}-\frac{1}{3} n; a_{100}=-\frac{98}{3}$$

11. $$a_{n}=1.2 n-0.4 ; a_{100}=119.6$$

13. $$99$$

15. $$157$$

17. $$38$$

19. $$a_{n}=5 n-3$$

Exercise $$\PageIndex{5}$$

Given the terms of an arithmetic sequence, find a formula for the general term.

1. $$a_{1}=6$$ and $$a_{7}=42$$
2. $$a_{1}=-\frac{1}{2}$$ and $$a_{12}=-6$$
3. $$a_{1}=-19$$ and $$a_{26}=56$$
4. $$a_{1}=-9$$ and $$a_{31}=141$$
5. $$a_{1}=\frac{1}{6}$$ and $$a_{10}=\frac{37}{6}$$
6. $$a_{1}=\frac{5}{4}$$ and $$a_{11}=\frac{65}{4}$$
7. $$a_{3}=6$$ and $$a_{26}=-40$$
8. $$a_{3}=16$$ and $$a_{15}=76$$
9. $$a_{4}=-8$$ and $$a_{23}=30$$
10. $$a_{5}=-7$$ and $$a_{37}=-135$$
11. $$a_{4}=-\frac{23}{10}$$ and $$a_{21}=-\frac{25}{2}$$
12. $$a_{3}=\frac{1}{8}$$ and $$a_{12}=-\frac{11}{2}$$
13. $$a_{5}=13.2$$ and $$a_{26}=61.5$$
14. $$a_{4}=-1.2$$ and $$a_{13}=12.3$$

1. $$a_{n}=6 n$$

3. $$a_{n}=3 n-22$$

5. $$a_{n}=\frac{2}{3} n-\frac{1}{2}$$

7. $$a_{n}=12-2 n$$

9. $$a_{n}=2 n-16$$

11. $$a_{n}=\frac{1}{10}-\frac{3}{5} n$$

13. $$a_{n}=2.3 n+1.7$$

Exercise $$\PageIndex{6}$$

Find all arithmetic means between the given terms.

1. $$a_{1}=-3$$ and $$a_{6}=17$$
2. $$a_{1}=5$$ and $$a_{5}=-7$$
3. $$a_{2}=4$$ and $$a_{8}=7$$
4. $$a_{5}=\frac{1}{2}$$ and $$a_{9}=-\frac{7}{2}$$
5. $$a_{5}=15$$ and $$a_{7}=21$$
6. $$a_{6}=4$$ and $$a_{11}=-1$$

1. $$1, 5, 9, 13$$

3. $$\frac{9}{2}, 5, \frac{11}{2}, 6, \frac{13}{2}$$

5. $$18$$

Exercise $$\PageIndex{7}$$

Calculate the indicated sum given the formula for the general term.

1. $$a_{n}=3 n+5 ; S_{100}$$
2. $$a_{n}=5 n-11 ; S_{100}$$
3. $$a_{n}=\frac{1}{2}-n, S_{70}$$
4. $$a_{n}=1-\frac{3}{2} n; S_{120}$$
5. $$a_{n}=\frac{1}{2} n-\frac{3}{4}; S_{20}$$
6. $$a_{n}=n-\frac{3}{5}; S_{150}$$
7. $$a_{n}=45-5 n ; S_{65}$$
8. $$a_{n}=2 n-48 ; S_{95}$$
9. $$a_{n}=4.4-1.6 n ; S_{75}$$
10. $$a_{n}=6.5 n-3.3 ; S_{67}$$

1. $$15,650$$

3. $$−2,450$$

5. $$90$$

7. $$−7,800$$

9. $$−4,230$$

Exercise $$\PageIndex{8}$$

Evaluate.

1. $$\sum_{n=1}^{160}(3 n)$$
2. $$\sum_{n=1}^{121}(-2 n)$$
3. $$\sum_{n=1}^{250}(4 n-3)$$
4. $$\sum_{n=1}^{120}(2 n+12)$$
5. $$\sum_{n=1}^{70}(19-8 n)$$
6. $$\sum_{n=1}^{220}(5-n)$$
7. $$\sum_{n=1}^{60}\left(\frac{5}{2}-\frac{1}{2} n\right)$$
8. $$\sum_{n=1}^{51}\left(\frac{3}{8} n+\frac{1}{4}\right)$$
9. $$\sum_{n=1}^{120}(1.5 n-2.6)$$
10. $$\sum_{n=1}^{175}(-0.2 n-1.6)$$
11. Find the sum of the first $$200$$ positive integers.
12. Find the sum of the first $$400$$ positive integers.

1. $$38,640$$

3. $$124,750$$

5. $$−18,550$$

7. $$−765$$

9. $$10,578$$

11. $$20,100$$

Exercise $$\PageIndex{9}$$

The general term for the sequence of positive odd integers is given by $$a_{n} = 2n − 1$$ and the general term for the sequence of positive even integers is given by $$a_{n} = 2n$$. Find the following.

1. The sum of the first $$50$$ positive odd integers.
2. The sum of the first $$200$$ positive odd integers.
3. The sum of the first $$50$$ positive even integers.
4. The sum of the first $$200$$ positive even integers.
5. The sum of the first $$k$$ positive odd integers.
6. The sum of the first $$k$$ positive even integers.
7. The first row of seating in a small theater consists of $$8$$ seats. Each row thereafter consists of $$3$$ more seats than the previous row. If there are $$12$$ rows, how many total seats are in the theater?
8. The first row of seating in an outdoor amphitheater contains $$42$$ seats, the second row contains $$44$$ seats, the third row contains $$46$$ seats, and so on. If there are $$22$$ rows, what is the total seating capacity of the theater?
9. If a triangular stack of bricks has $$37$$ bricks on the bottom row, $$34$$ bricks on the second row and so on with one brick on top. How many bricks are in the stack?
10. Each successive row of a triangular stack of bricks has one less brick until there is only one brick on top. How many rows does the stack have if there are $$210$$ total bricks?
11. A $$10$$-year salary contract offers $$$65,000$$ for the first year with a$$$3,200$$ increase each additional year. Determine the total salary obligation over the $$10$$ year period.
12. A clock tower strikes its bell the number of times indicated by the hour. At one o’clock it strikes once, at two o’clock it strikes twice and so on. How many times does the clock tower strike its bell in a day?

1. $$2,500$$

3. $$2,550$$

5. $$k^{2}$$

7. $$294$$ seats

9. $$247$$ bricks

11. \$$$794,000$$

Exercise $$\PageIndex{10}$$

1. Is the Fibonacci sequence an arithmetic sequence? Explain.
2. Use the formula for the $$n$$th partial sum of an arithmetic sequence $$S_{n}=\frac{n\left(a_{1}+a_{n}\right)}{2}$$ and the formula for the general term $$a_{n}=a_{1}+(n-1) d$$ to derive a new formula for the nth partial sum $$S_{n}=\frac{n}{2}\left[2 a_{1}+(n-1) d\right]$$. Under what circumstances would this formula be useful? Explain using an example of your own making.
3. Discuss methods for calculating sums where the index does not start at $$1$$. For example, $$\sum_{n=1}^{35}(3 n+4)=1,659$$.
4. A famous story involves Carl Friedrich Gauss misbehaving at school. As punishment, his teacher assigned him the task of adding the first $$100$$ integers. The legend is that young Gauss answered correctly within seconds. What is the answer and how do you think he was able to find the sum so quickly?

## Footnotes

12A sequence of numbers where each successive number is the sum of the previous number and some constant $$d$$.

13Used when referring to an arithmetic sequence.

14The constant $$d$$ that is obtained from subtracting any two successive terms of an arithmetic sequence; $$a_{n}-a_{n-1}=d$$.

15The terms between given terms of an arithmetic sequence.

16The sum of the terms of an arithmetic sequence.

17The sum of the first $$n$$ terms of an arithmetic sequence given by the formula: $$S_{n}=\frac{n\left(a_{1}+a_{n}\right)}{2}$$.