Presentation is loading. Please wait.

Presentation is loading. Please wait.

Sequences and Series College Algebra

Published byNickolas Conley Modified over 6 years ago

Similar presentations

Presentation on theme: "Sequences and Series College Algebra"β€” Presentation transcript:

1 Sequences and Series College Algebra
Title: Cape Canaveral Air Force Station, United States. Author: SpaceX Located at: All text in these slides is taken from where it is published under one or more open licenses. All images in these slides are attributed in the notes of the slide on which they appear and licensed as indicated.

2 Sequences A sequence is a function whose domain is the set of positive integers. A finite sequence is a sequence whose domain consists of only the first 𝑛 positive integers. The numbers in a sequence are called terms. The variable π‘Ž with a number subscript is used to represent the terms in a sequence and to indicate the position of the term in the sequence. π‘Ž 1 , π‘Ž 2 , π‘Ž 3 , β‹―, π‘Ž 𝑛 , β‹― The term π‘Ž 𝑛 is called the 𝑛th term of the sequence, or the general term of the sequence. An explicit formula defines the 𝑛th term of a sequence using the position of the term. A sequence that continues indefinitely is an infinite sequence. Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

3 Writing the Terms of a Sequence
Given an explicit formula, write the first 𝒏 terms of a sequence. Substitute each value of 𝑛 into the formula. Begin with 𝑛=1Β to find the first term,Β  π‘Ž 1 . To find the second term,Β  π‘Ž 2 , use 𝑛=2. Continue in the same manner until you have identified all 𝑛 terms. Example: Write the first five terms of the sequence defined by the explicit formula π‘Ž 𝑛 =βˆ’3𝑛+8. Solution: For 𝑛=1, π‘Ž 1 =βˆ’3 1 +8=5. Continue until π‘Ž 5 =βˆ’7. The sequence is 5, 2, βˆ’1, βˆ’4, βˆ’7 . Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

4 Writing the Terms of a Sequence
Given an explicit formula for a piecewise function, write the first 𝒏 terms of a sequence. Identify the formula to which 𝑛=1Β applies to find the first term,Β  π‘Ž 1 . Identify the formula to which 𝑛=2 applies to find the second term,Β  π‘Ž 2 . Continue in the same manner until you have identified all 𝑛 terms. Example: Write the first six terms of the sequence: π‘Ž 𝑛 = 2𝑛 2 if 𝑛 is odd 3𝑛 if 𝑛 is even Solution: 1, 6, 8, 12, 50, 18 Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

5 Finding an Explicit Formula
Given the first few terms of a sequence, find an explicit formula for the sequence. Look for a pattern among the terms. If the terms are fractions, look for a separate pattern among the numerators and denominators. Look for a pattern among the signs of the terms. Write a formula forΒ  π‘Ž 𝑛 Β in terms of 𝑛. Test your formula for 𝑛=1, 𝑛= 2,Β and 𝑛=3. Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

6 Alternating Terms Given an explicit formula with alternating terms, write the first 𝒏 terms of a sequence. Substitute each value of 𝑛 into the formula. Begin with 𝑛=1Β to find the first term, π‘Ž 1 . The sign of the term is given by theΒ  βˆ’1 𝑛 Β in the explicit formula. Use 𝑛=2 to find the second term, π‘Ž 2 . Continue in the same manner until you have identified all 𝑛 terms. Example: Write the first five terms of the sequence π‘Ž 𝑛 = βˆ’1 𝑛 𝑛 2 𝑛+1 . Solution: βˆ’ 1 2 , 4 3 , βˆ’ 9 4 , , βˆ’ 25 6 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

7 Sequences Defined by a Recursive Formula
A recursive formula is a formula that defines each term of a sequence using preceding term(s). Recursive formulas must always state the initial term, or terms, of the sequence. Given a recursive formula with only the first term provided, write the first 𝒏 terms of a sequence. Identify the initial term,Β  π‘Ž 1 , which is given as part of the formula. To find the second term,Β  π‘Ž 2 , substitute the initial term into the formula forΒ  π‘Ž π‘›βˆ’1 and solve. To find the third term,Β  π‘Ž 3 , substitute the second term into the formula and solve. Repeat until you have solved for the 𝑛thΒ term. 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

8 Writing the Terms of a Sequence Defined by a Recursive Formula
Example: Write the first five terms of the sequence defined by the recursive formula: π‘Ž 1 =5 π‘Ž 𝑛 =2 π‘Ž π‘›βˆ’1 βˆ’1, for 𝑛β‰₯2 Solution: π‘Ž 2 =2 5 βˆ’1=9 π‘Ž 3 =2 9 βˆ’1=17 π‘Ž 4 =2 17 βˆ’1=33 π‘Ž 5 =2 33 βˆ’1=65 The first five terms are 5, 9, 17, 33, 65 . 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

9 Factorial Notation 𝒏 factorial is a mathematical operation that can be defined using a recursive formula. The factorial of 𝑛, denoted 𝑛!, is defined for a positive integer 𝑛 as: 0!=1 1!=1 𝑛!=𝑛(π‘›βˆ’1)(π‘›βˆ’2)β‹―(2)(1), for 𝑛β‰₯2 The factorial of any whole number 𝑛 is 𝑛 π‘›βˆ’1 ! 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

10 Arithmetic Sequences 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 π‘Ž 1 is the first term of an arithmetic sequence and 𝑑 is the common difference, the sequence will be: π‘Ž 1 , π‘Ž 1 +𝑑, π‘Ž 1 +2𝑑, π‘Ž 1 +3𝑑,β‹― The 𝑛th term of an arithmetic sequence is given by the explicit formula : π‘Ž 𝑛 = π‘Ž 1 + π‘›βˆ’1 𝑑 The recursive formula for an arithmetic sequence with common difference 𝑑 is: π‘Ž 𝑛 = π‘Ž π‘›βˆ’1 +𝑑 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

11 Geometric Sequences A geometric sequence is one in which any term divided by the previous term is a constant, which is called the common ratio of the sequence. If π‘Ž 1 is the initial term of a geometric sequence and π‘Ÿ is the common ratio, the sequence will be: π‘Ž 1 , π‘Ž 1 π‘Ÿ, π‘Ž 1 π‘Ÿ 2 , π‘Ž 1 π‘Ÿ 3 ,β‹― The 𝑛th term of a geometric sequence is given by the explicit formula: π‘Ž 𝑛 = π‘Ž 1 π‘Ÿ π‘›βˆ’1 The recursive formula for a geometric sequence with common ratio π‘Ÿ is: π‘Ž 𝑛 = π‘Ÿπ‘Ž π‘›βˆ’1 , 𝑛β‰₯2 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

12 Series and Summation Notation
The sum of the terms of a sequence is called a series. The 𝑛th partial sum of a series is the sum of a finite number of consecutive terms beginning with the first term. The partial sum 𝑆 𝑛 = π‘Ž 1 + π‘Ž 2 +β‹―+ π‘Ž 𝑛 . Summation notation is used to represent series. The Greek capital letter sigma is used to represent the sum. π‘˜=1 𝑛 π‘Ž π‘˜ where π‘˜ is the index of summation, 1 is the lower limit of summation, and 𝑛 is the upper limit of summation. 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

13 Arithmetic Series An arithmetic series is the sum of the terms of an arithmetic sequence. The formula for the partial sum of an arithmetic series is 𝑆 𝑛 = 𝑛 π‘Ž 1 + π‘Ž 𝑛 2 Example: Find the sum of the series π‘˜=1 12 3π‘˜βˆ’8 Solution: π‘Ž 1 =3 1 βˆ’8=βˆ’5 π‘Ž 12 =3 12 βˆ’8=28 𝑆 12 = 12(βˆ’5+28) 2 =138 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

14 Geometric Series A geometric series is the sum of the terms of a geometric sequence. The formula for the partial sum of a geometric series is 𝑆 𝑛 = π‘Ž 1 1βˆ’ π‘Ÿ 𝑛 1βˆ’π‘Ÿ , π‘Ÿβ‰ 1 Example: Find the sum of the series π‘˜=1 6 3βˆ™ 2 π‘˜ Solution: π‘Ž 1 =3βˆ™ 2 1 =6 π‘Ÿ=2 𝑆 6 = 6(1βˆ’ 2 6 ) 1βˆ’2 =378 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

15 Infinite Geometric Series
If the absolute value of the common ratio π‘Ÿ of an infinite geometric series is less than 1, the terms of the series will approach zero and the series will have a finite sum. The formula for the sum of an infinite geometric series is 𝑆 𝑛 = π‘Ž 1 1βˆ’π‘Ÿ , where βˆ’1<π‘Ÿ<1 Example: Find the sum of the infinite series 1, 1 2 , 1 4 , 1 8 , β‹― Solution: π‘Ž 1 =1 and π‘Ÿ= 1 2 , therefore 𝑆 𝑛 = 1 1βˆ’ 1 2 =2 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

16 Annuities AnΒ annuityΒ is an investment in which the purchaser makes a sequence of periodic, equal payments. Given an initial deposit and an interest rate, find the value of an annuity. DetermineΒ  π‘Ž 1 , the value of the initial deposit. Determine 𝑛, the number of deposits. DetermineΒ π‘Ÿ. Divide the annual interest rate by the number of times per year that interest is compounded, and add 1 to this amount to findΒ π‘Ÿ. Use the formula of the sum of a geometric series, 𝑆 𝑛 = π‘Ž 1 1βˆ’ π‘Ÿ 𝑛 1βˆ’π‘Ÿ , to find the value of the annuity after 𝑛 deposits. 5Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

17 Quick Review How do you find the explicit formula for the 𝑛th term of a sequence? What is a recursive formula? How do you compute the factorial of 𝑛? How can you tell if a sequence is an arithmetic sequence? What is the explicit formula of a geometric sequence? What is the difference between a sequence and a series? What is the formula for the partial sum of an arithmetic series? How can an infinite geometric series have a finite sum? When working with an annuity problem, how do you find the value of the common ratio when given an interest rate? Revision and Adaptation.Β Provided by: Lumen Learning.Β License:Β CC BY: Attribution

Download ppt "Sequences and Series College Algebra"

Similar presentations

Chapter 8 Vocabulary. Section 8.1 Vocabulary Sequences An infinite sequence is a function whose domain is the set of positive integers. The function.

Chapter 8 Vocabulary. Section 8.1 Vocabulary Sequences An infinite sequence is a function whose domain is the set of positive integers. The function.
Sequences and Mathematical Induction

Sequences and Mathematical Induction
Sequences, Induction and Probability

Sequences, Induction and Probability
Sequences, Series, and the Binomial Theorem

Sequences, Series, and the Binomial Theorem
ο‚³ This Slideshow was developed to accompany the textbook ο‚² Larson Algebra 2 ο‚² By Larson, R., Boswell, L., Kanold, T. D., & Stiff, L. ο‚² 2011 Holt McDougal.

ο‚³ This Slideshow was developed to accompany the textbook ο‚² Larson Algebra 2 ο‚² By Larson, R., Boswell, L., Kanold, T. D., & Stiff, L. ο‚² 2011 Holt McDougal.
Geometric Sequences and Series A sequence is geometric if the ratios of consecutive terms are the same. 2, 8, 32, 128, 512,... Definition of Geometric.

Geometric Sequences and Series A sequence is geometric if the ratios of consecutive terms are the same. 2, 8, 32, 128, 512,... Definition of Geometric.
13.3 Arithmetic & Geometric Series. A series is the sum of the terms of a sequence. A series can be finite or infinite. We often utilize sigma notation.

13.3 Arithmetic & Geometric Series. A series is the sum of the terms of a sequence. A series can be finite or infinite. We often utilize sigma notation.
11.4 Geometric Sequences. 11.4 Geometric Sequences and Series geometric sequence If we start with a number, a 1, and repeatedly multiply it by some constant,

11.4 Geometric Sequences Geometric Sequences and Series geometric sequence If we start with a number, a 1, and repeatedly multiply it by some constant,
Introduction to sequences and series A sequence is a listing of numbers. For example, 2, 4, 6, 8,... or 1, 3, 5,... are the sequences of even positive.

Introduction to sequences and series A sequence is a listing of numbers. For example, 2, 4, 6, 8,... or 1, 3, 5,... are the sequences of even positive.
1 Β© 2010 Pearson Education, Inc. All rights reserved 10.1 DEFINITION OF A SEQUENCE An infinite sequence is a function whose domain is the set of positive.

1 Β© 2010 Pearson Education, Inc. All rights reserved 10.1 DEFINITION OF A SEQUENCE An infinite sequence is a function whose domain is the set of positive.
Geometric Sequences and Series

Geometric Sequences and Series
Copyright Β© 2014, 2010 Pearson Education, Inc. Chapter 9 Further Topics in Algebra Copyright Β© 2014, 2010 Pearson Education, Inc.

Copyright Β© 2014, 2010 Pearson Education, Inc. Chapter 9 Further Topics in Algebra Copyright Β© 2014, 2010 Pearson Education, Inc.
Explicit, Summative, and Recursive

Explicit, Summative, and Recursive
Sequences Suppose that $5,000 is borrowed at 6%, compounded annually. The value of the loan at the start of the years 1, 2, 3, 4, and so on is $5000,

Sequences Suppose that $5,000 is borrowed at 6%, compounded annually. The value of the loan at the start of the years 1, 2, 3, 4, and so on is $5000,
Copyright Β© Cengage Learning. All rights reserved.

Copyright Β© Cengage Learning. All rights reserved.
Sequences & Summation Notation 8.1 JMerrill, 2007 Revised 2008.

Sequences & Summation Notation 8.1 JMerrill, 2007 Revised 2008.
1 Β© 2010 Pearson Education, Inc. All rights reserved Β© 2010 Pearson Education, Inc. All rights reserved Chapter 11 Further Topics in Algebra.

1 Β© 2010 Pearson Education, Inc. All rights reserved Β© 2010 Pearson Education, Inc. All rights reserved Chapter 11 Further Topics in Algebra.
Copyright Β© Cengage Learning. All rights reserved.

Copyright Β© Cengage Learning. All rights reserved.
1 Β© 2010 Pearson Education, Inc. All rights reserved Β© 2010 Pearson Education, Inc. All rights reserved Chapter 10 Further Topics in Algebra.

1 Β© 2010 Pearson Education, Inc. All rights reserved Β© 2010 Pearson Education, Inc. All rights reserved Chapter 10 Further Topics in Algebra.
Introduction to sequences and series

Introduction to sequences and series

Similar presentations

Ads by Google