College Algebra Fifth Edition James Stewart Lothar Redlin Saleem Watson.

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College Algebra Fifth Edition James Stewart Lothar Redlin Saleem Watson

Sequences and Series 9

Arithmetic Sequences 9.2

Arithmetic Sequences In this section, we study a special type of sequence, called an arithmetic sequence.

Arithmetic Sequences

Perhaps the simplest way to generate a sequence is: To start with a number a and add to it a fixed constant d, over and over again.

Arithmetic Sequence—Definition An arithmetic sequence is a sequence of the form a, a + d, a + 2d, a + 3d, a + 4d,... The number a is the first term. The number d is the common difference of the sequence. The nth term of an arithmetic sequence is given by: a n = a + (n – 1)d

Common Difference The number d is called the common difference because: Any two consecutive terms of an arithmetic sequence differ by d.

E.g. 1—Arithmetic Sequences If a = 2 and d = 3, we have the arithmetic sequence 2, 2 + 3, 2 + 6, 2 + 9,... or 2, 5, 8, 11,... Any two consecutive terms of this sequence differ by d = 3. The nth term is a n = 2 + 3(n – 1). Example (a)

E.g. 1—Arithmetic Sequences Consider the arithmetic sequence 9, 4, –1, –6, –11,... The common difference is d = –5. The terms of an arithmetic sequence decrease if the common difference is negative. The nth term is a n = 9 – 5(n – 1). Example (b)

E.g. 1—Arithmetic Sequences The graph of the arithmetic sequence a n = 1 + 2(n – 1) is shown. Notice that the points in the graph lie on a straight line with slope d = 2. Example (c)

Arithmetic Sequences An arithmetic sequence is determined completely by the first term a and the common difference d. Thus, if we know the first two terms of an arithmetic sequence, we can find a formula for the nth term—as the next example shows.

E.g. 2—Finding Terms of an Arithmetic Sequence Find the first six terms and the 300th term of the arithmetic sequence 13, 7,... Since the first term is 13, we have a = 13. The common difference is: d = 7 – 13 = –6 Thus, the nth term of the sequence is: a n = 13 – 6(n – 1)

E.g. 2—Finding Terms of an Arithmetic Sequence From that, we find the first six terms: 13, 7, 1, –5, –11, –17,... The 300th term is: a 300 = 13 – 6(299) = –1781

Arithmetic Sequences The next example shows that an arithmetic sequence is determined completely by any two of its terms.

E.g. 3—Finding Terms of an Arithmetic Sequence The 11th term of an arithmetic sequence is 52, and the 19 th term is 92. Find the 1000 th term.

E.g. 3—Finding Terms of an Arithmetic Sequence To find the nth term of the sequence, we need to find a and d in the formula a n = a + (n – 1)d From the formula, we get: a 11 = a + (11 – 1)d = a + 10d a 19 = a + (19 – 1)d = a + 18d

E.g. 3—Finding Terms of an Arithmetic Sequence Since a 11 = 52 and a 19 = 92, we get the two equations: Solving this for a and d, we get: a = 2, d = 5 The nth term is: a n = 2 + 5(n – 1) The 1000th term is: a 1000 = 2 + 5(999) = 4997

Partial Sums of Arithmetic Sequences

Suppose we want to find the sum of the numbers 1, 2, 3, 4,..., 100, that is,

Partial Sums of Arithmetic Sequences When the famous mathematician C. F. Gauss was a schoolboy, his teacher posed this problem to the class and expected that it would keep the students busy for a long time. Gauss, though, answered it almost immediately.

Partial Sums of Arithmetic Sequences His idea was this: Since we are adding numbers produced according to a fixed pattern, there must also be a pattern (or formula) for finding the sum. He started by writing the numbers from 1 to 100 and below them the same numbers in reverse order.

Partial Sums of Arithmetic Sequences Writing S for the sum and adding corresponding terms gives: It follows that 2S = 100(101) = 10,100 and so S = 5050.

Partial Sums of Arithmetic Sequences Of course, the sequence of natural numbers 1, 2, 3,... is an arithmetic sequence (with a = 1 and d = 1). The method for summing the first 100 terms of this sequence can be used to find a formula for the nth partial sum of any arithmetic sequence.

Partial Sums of Arithmetic Sequences We want to find the sum of the first n terms of the arithmetic sequence whose terms are a k = a + (k – 1)d. That is, we want to find:

Partial Sums of Arithmetic Sequences Using Gauss’s method, we write: There are n identical terms on the right side of this equation.

Partial Sums of Arithmetic Sequences Thus, Notice that a n = a + (n – 1)d is the nth term of this sequence.

Partial Sums of Arithmetic Sequences So, we can write: This last formula says that the sum of the first n terms of an arithmetic sequence is the average of the first and nth terms multiplied by n, the number of terms in the sum. We now summarize this result.

Partial Sums of an Arithmetic Sequence For the arithmetic sequence a n = a + (n – 1)d, the nth partial sum S n = a + (a + d) + (a + 2d) + (a + 3d) +... [a + (n – 1)d] is given by either of these formulas.

E.g. 4—Partial Sum of an Arithmetic Sequence Find the sum of the first 40 terms of the arithmetic sequence 3, 7, 11, 15,... Here, a = 3 and d = 4. Using Formula 1 for the partial sum of an arithmetic sequence, we get: S 40 = (40/2) [2(3) + (40 – 1)4] = 20( ) = 3240

E.g. 5—Partial Sum of an Arithmetic Sequence Find the sum of the first 50 odd numbers. The odd numbers form an arithmetic sequence with a = 1 and d = 2. The nth term is: a n = 1 + 2(n – 1) = 2n – 1 So, the 50th odd number is: a 50 = 2(50) – 1 = 99

E.g. 5—Partial Sum of an Arithmetic Sequence Substituting in Formula 2 for the partial sum of an arithmetic sequence, we get:

E.g. 6—Finding Seating Capacity of Amphitheater An amphitheater has 50 rows of seats with 30 seats in the first row, 32 in the second, 34 in the third, and so on. Find the total number of seats.

E.g. 6—Finding Seating Capacity of Amphitheater The numbers of seats in the rows form an arithmetic sequence with a = 30 and d = 2. Since there are 50 rows, the total number of seats is the sum The amphitheater has 3950 seats.

E.g. 7—Finding the Number of Terms in a Partial Sum How many terms of the arithmetic sequence 5, 7, 9,... must be added to get 572? We are asked to find n when S n = 572.

E.g. 7—Finding the Number of Terms in a Partial Sum Substituting a = 5, d = 2, and S n = 572 in Formula 1, we get: This gives n = 22 or n = –26. However, since n is the number of terms in this partial sum, we must have n = 22.