O X F O R D I B D I P L O M A P R O G R A M M E : MATHEMATICS HIGHER LEVEL C A LC U LU S Josip Harcet Lorraine Heinrichs Palmira Mariz Seiler Marlene Torres-Skoumal 3 Great Clarendon Street, Oxford OX2 6DP Oxford University Press is a department of the University of Oxford. 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Acknowledgements The publisher would like to thank the following for permission to reproduce photographs: p2: jupeart/Shutterstock; p2: mary416/Shutterstock; p3: freesoulproduction/Shutterstock; p17: Science Photo Library; p21: Science Photo Library; p39: Scott Camazine/PRI/Getty. Course Companion denition The IB Diploma Programme Course Companions are Diploma Programme core requirements, theory of resource materials designed to support students knowledge, the extended essay, and creativity, action, throughout their two-year Diploma Programme course service (CAS). of study in a particular subject. They will help students Each book can be used in conjunction with other gain an understanding of what is expected from the materials and indeed, students of the IB are required study of an IB Diploma Programme subject while and encouraged to draw conclusions from a variety of presenting content in a way that illustrates the purpose resources. Suggestions for additional and further and aims of the IB. They reect the philosophy and reading are given in each book and suggestions for how approach of the IB and encourage a deep understanding to extend research are provided. of each subject by making connections to wider issues In addition, the Course Companions provide advice and and providing opportunities for critical thinking. guidance on the specic course assessment requirements The books mirror the IB philosophy of viewing the and on academic honesty protocol. They are distinctive curriculum in terms of a whole-course approach; the and authoritative without being prescriptive. use of a wide range of resources, international mindedness, the IB learner prole and the IB IB mission statement The International Baccalaureate aims to develop programmes of international education and rigorous inquiring, knowledgable and caring young people who assessment. help to create a better and more peaceful world through These programmes encourage students across the intercultural understanding and respect. world to become active, compassionate, and lifelong To this end the IB works with schools, governments learners who understand that other people, with their and international organizations to develop challenging dierences, can also be right. The IB learner Prole The aim of all IB programmes is to develop They take responsibility for their own actions and the internationally minded people who, recognizing their consequences that accompany them. common humanity and shared guardianship of the Open-minded They understand and appreciate their planet, help to create a better and more peaceful world. own cultures and personal histories, and are open to IB learners strive to be: the perspectives, values, and traditions of other Inquirers They develop their natural curiosity. They individuals and communities. They are accustomed to acquire the skills necessary to conduct inquiry and seeking and evaluating a range of points of view, and research and show independence in learning. They are willing to grow from the experience. actively enjoy learning and this love of learning will be sustained throughout their lives. Caring They show empathy, compassion, and respect towards the needs and feelings of others. They have a Knowledgable They explore concepts, ideas, and personal commitment to service, and act to make a issues that have local and global signicance. In so positive dierence to the lives of others and to the doing, they acquire in-depth knowledge and develop environment. understanding across a broad and balanced range of disciplines. Risk-takers They approach unfamiliar situations and Thinkers They exercise initiative in applying thinking uncertainty with courage and forethought, and have skills critically and creatively to recognize and the independence of spirit to explore new roles, ideas, approach complex problems, and make reasoned, and strategies. They are brave and articulate in ethical decisions. defending their beliefs. Communicators They understand and express ideas Balanced They understand the importance of and information condently and creatively in more intellectual, physical, and emotional balance to achieve than one language and in a variety of modes of personal well-being for themselves and others. communication. They work eectively and willingly in collaboration with others. Reective They give thoughtful consideration to their own learning and experience. They are able to assess Principled They act with integrity and honesty, with a and understand their strengths and limitations in order strong sense of fairness, justice, and respect for the to support their learning and personal development. dignity of the individual, groups, and communities. iii A note on academic honesty It is of vital importance to acknowledge and What constitutes malpractice? appropriately credit the owners of information Malpractice is behaviour that results in, or may when that information is used in your work. After result in, you or any student gaining an unfair all, owners of ideas (intellectual property) have advantage in one or more assessment component. property rights. To have an authentic piece of Malpractice includes plagiarism and collusion. work, it must be based on your individual and Plagiarism is dened as the representation of the original ideas with the work of others fully ideas or work of another person as your own. acknowledged. Therefore, all assignments, written The following are some of the ways to avoid or oral, completed for assessment must use your plagiarism: own language and expression. Where sources are used or referred to, whether in the form of direct ● Words and ideas of another person used to quotation or paraphrase, such sources must be support one’s arguments must be appropriately acknowledged. acknowledged. ● Passages that are quoted verbatim must be How do I acknowledge the work enclosed within quotation marks and of others? acknowledged. The way that you acknowledge that you have ● CD-ROMs, email messages, web sites on the Internet, and any other electronic media must used the ideas of other people is through the use be treated in the same way as books and of footnotes and bibliographies. journals. Footnotes (placed at the bottom of a page) or ● The sources of all photographs, maps, endnotes (placed at the end of a document) are to illustrations, computer programs, data, graphs, be provided when you quote or paraphrase from audio-visual, and similar material must be another document, or closely summarize the acknowledged if they are not your own work. information provided in another document. You do not need to provide a footnote for information ● Words of art, whether music, lm, dance, theatre arts, or visual arts, and where the that is part of a ‘body of knowledge’. That is, creative use of a part of a work takes place, denitions do not need to be footnoted as they must be acknowledged. are part of the assumed knowledge. Collusion is dened as supporting malpractice by Bibliographies should include a formal list of another student. This includes: the resources that you used in your work. ‘Formal’ means that you should use one of the ● allowing your work to be copied or submitted several accepted forms of presentation. This for assessment by another student usually involves separating the resources that you ● duplicating work for dierent assessment use into dierent categories (e.g. books, components and/or diploma requirements. magazines, newspaper articles, Internet-based Other forms of malpractice include any action resources, CDs and works of art) and providing that gives you an unfair advantage or aects the full information as to how a reader or viewer results of another student. Examples include, of your work can nd the same information. taking unauthorized material into an examination A bibliography is compulsory in the extended room, misconduct during an examination, and essay. falsifying a CAS record. iv About the book The new syllabus for Mathematics Higher Level Questions are designed to increase in diculty, Option: Calculus is thoroughly covered in this strengthen analytical skills and build condence book. Each chapter is divided into lesson-size through understanding. sections with the following features: Where appropriate the solutions to examples are given in the style of a graphics display calculator. Did you know? History Mathematics education is a growing, ever changing entity. The contextual, technology integrated approach enables students to become Extension Advice adaptable, lifelong learners. Note: US spelling has been used, with IB style for The Course Companion will guide you through mathematical terms. the latest curriculum with full coverage of all topics and the new internal assessment. The emphasis is placed on the development and improved understanding of mathematical concepts and their real life application as well as prociency in problem solving and critical thinking. The Course Companion denotes questions that would be suitable for examination practice and those where a GDC may be used. About the authors Lorraine Heinrichs has been teaching Marlene Torres-Skoumal has taught IB mathematics for 30 years and IB mathematics for mathematics for over 30 years. During this time, the past 16 years at Bonn International School. she has enjoyed various roles with the IB, She has been the IB DP coordinator since 2002. including deputy chief examiner for HL, During this time she has also been senior senior moderator for Internal Assessment, moderator for HL Internal Assessment and calculator forum moderator, workshop leader, workshop leader of the IB; she was also a and a member of several curriculum review member of the curriculum review team. teams. Palmira Mariz Seiler has been teaching Josip Harcet has been involved with and teaching mathematics for over 25 years. She joined the IB the IB programme since 1992. He has served as a community in 2001 as a teacher at the Vienna curriculum review member, deputy chief International School and since then has also examiner for Further Mathematics, assistant IA worked as Internal Assessment moderator in examiner and senior examiner for Mathematics curriculum review working groups and as a HL as well as a workshop leader since 1998. workshop leader and deputy chief examiner for HL mathematics. Currently she teaches at Colegio Anglo Colombiano in Bogota, Colombia. v Contents Chapter 1 Patterns to innity 2 Chapter 4 The nite in the innite 96 1.1 From limits of sequences to limits of 4.1 Series and convergence 98 functions 3 4.2 Introduction to convergence tests 1.2 Squeeze theorem and the algebra of for series 104 limits of convergent sequences 7 4.3 Improper Integrals 110 1.3 Divergent sequences: indeterminate 4.4 Integral test for convergence 112 forms and evaluation of limits 10 4.5 The p-series test 114 1.4 From limits of sequences to limits 4.6 Comparison test for convergence 115 of functions 13 4.7 Limit comparison test for convergence 118 4.8 Ratio test for convergence 119 Chapter 2 Smoothness in mathematics 22 4.9 Absolute convergence of series 120 2.1 Continuity and dierentiability 4.10 Conditional convergence of series 122 on an interval 24 2.2 Theorems about continuous functions 28 Chapter 5 Everything polynomic 130 2.3 Dierentiable functions: Rolle’s 5.1 Representing Functions by Theorem and Mean Value Theorem 33 Power Series 1 132 2.4 Limits at a point, indeterminate forms, 5.2 Representing Power Series as and L’Hopital’s rule 42 Functions 135 2.5 What are smooth graphs of functions? 49 5.3 Representing Functions by 2.6 Limits of functions and limits of Power Series 2 138 sequences 50 5.4 Taylor Polynomials 143 5.5 Taylor and Maclaurin Series 146 Chapter 3 Modeling dynamic 5.6 Using Taylor Series to approximate phenomena 54 functions 156 3.1 Classications of dierential 5.7 Useful applications of power series 161 equations and their solutions 56 3.2 Dierential Equations with separated Answers 168 variables 61 3.3 Separable variables, dierential Index 185 equations and graphs of their solutions 63 3.4 Modeling of growth and decay phenomena 69 3.5 First order exact equations and integrating factors 73 3.6 Homogeneous dierential equations and substitution methods 80 3.7 Euler Method for rst order dierential equations 85 vi 1 Patterns to innity CHAPTER OBJECTIVES: 9.1 Innite sequences of real numbers and their convergence or divergence. Informal treatment of limit of sum, difference, product, quotient, squeeze theorem. Before you start 1 Simplify algebraic fractions. 1 Simplify: 1 1 n+1−n 1 3 3 n 1 n e.g. − = = a − b − n n+1 n(n+1) n(n+1) 4n+1 4n−1 n+2 n+3 2 Solve inequalities that involve absolute value. 2 Solve: e.g. Solve |x – 3| < 2 a |3x – 1| < 1 b |2x – 3| ≥ 4 x − 3 <2 ⇒−2 < x − 3<2⇒1< x < 5 3 Rationalise denominators of fractions. 3 Rationalise the denominator: ( ) 2n n 1 3 3 n + n+2 a b e.g. = ( )( ) 1+ n n + n+1 n − n+2 n − n+2 n+ n+2 ( ) ( ) 3 n+ n+2 3 n+ n+2 = = n−(n+2) 2 4 Recognise arithmetic and geometric 4 Find the nth term of sequences and use knowledge about their 1 1 1 1 a ,− , ,− ,… general terms to determine the expression 2 4 8 16 of other sequences. 1 1 1 1 b , − , , − ,… e.g. Find the nth term of the sequence 2 3 4 5 1 2 4 8 16 ,− , ,− , ,… 1 3 5 7 3 5 7 9 11 c , , , ,… 2 4 6 8 Each term can be seen as the quotient of terms of a geometric sequence (numerator) 3 5 7 3 d , − , , − ,… and the quotient of terms of an arithmetic 2 4 8 16 sequence (denominator). The general term of this sequence is ( 2)n 1 u = , n∈Z+ n 2n+1 2 Patterns to innity 1.1 From limits of sequences to limits of functions Innity is a concept that has challenged mathematicians Intuitively we think of innity as and scientists for centuries. Throughout this time the something larger than any number. concept of innity was sometimes denied and sometimes This sounds simple, but in fact innity is accepted by mathematicians, to the point that it became anything but simple. In the late 1800s, one of the main issues in the history of Mathematics. In Georg Cantor discovered that there are the last 150 years, great advances were made: rst with the many different sizes of innity, in fact there are innitely many sizes! Cantor axiomatization of set theory; and then with the work showed that the smallest innity is the of philosopher Bertrand Russell and his collection of one you would get to if you could count paradoxes. At the climax of all discussions was the work forever (a ‘countable’ innity), and that of Georg Cantor on the classication of innities. innities which aren’t countable, such as But do innities really exist? After all, how many types real numbers, are actually larger in size. of innity are there? Does it make sense to compare them and operate with them? Is there a ‘medium’ size of innity, In this chapter we will explore the concept of innity, bigger than the natural numbers starting with an intuitive approach and looking at but smaller than the real numbers? The familiar number patterns: sequences. We will then supposition that nothing is in between formalise the idea of ‘the pattern that goes on the two innities is called the ‘continuum forever’ and formally dene the limit of a sequence. hypothesis’. You may want to explore This may help you to better understand the theorems this topic further to learn about the about sequences, although formal treatment of limits powerful methods invented by Cantor of sequences will not be examined. For this reason, and the resulting problems which still puzzle mathematicians today. all proofs of results have been omitted. At the end of the chapter we will explore the connections between limits of sequences and limits of functions introduced in the core course. We will also establish criteria for the existence of the limit of a function at a point. Chapter 1 3 Consider the following numerical sequences: a :, 2, 4, 8, 6, …, 2n, … n 1 1 1 1 b :1, , , , , n 2 3 4 n c :–, , –, , –, , …, (–)n, … n What is happening to the terms of these sequences as n increases? Do they approach any real number as n → +∞? 1.1 Divergent innity 1.1 Convergent 1.1 Oscillating y y y 70 1.2 1.5 60 1.0 1 50 0.8 0.5 u1(n) = (–1)n 40 u1(n) = 2n 30 0.6 u1(n) = 1 –0.50 2 4 6 8 10 12 x 20 0.4 n –1 10 0.2 –1.5 0 1 2 3 4 5 6 7x 0 4 8 12 16 20 24 x –2 If we graph the sequences {a }, {b }, and {c }, we can observe their n n n behaviour as n increases, and notice that: lima =+∞ which means that {a } diverges;  n→∞ n n limb =0 which means that {b } converges to 0;  n→∞ n n limc does not exist (it oscillates from  to −) which means that {c } diverges.  n→∞ n n The following investigation will help you to better understand what ‘convergent’ means. Investigation 1 n+1 1 Use technology to graph the sequence dened by u = n 2n+1 1 2 Hence explain why limu = n→∞ n 2 1 3 Find the minimum value of m such that n ≥ m ⇒ u − <0 1 (i.e. nd the smallest n 2 1 integer n for which the dierence between the value u and is less than 0.1). n 2 4 Consider the positive small quantities ε = 0.01, 0.001, and 0.0001. In each case nd 1 the minimum value of m such that n ≥ m ⇒ u − <ε n 2 5 Decide whether or not it is possible to nd the order m such that n ≥ m⇒ |u – 0.4| < 0.1. Give reasons for your answer. n ⎛ 1⎞n Consider now the sequence dened by v = − ⎜ ⎟ n ⎝ 3⎠ 6 Explain why limv = 0 n n→∞ 7 Consider the positive small quantities ε = 0.01, 0.001, and 0.0001. In each case nd the minimum value of m such that n ≥ m⇒ |v | < ε n 8 Explain the meaning of limu = L in terms n You may want to use sequences dened by n→∞ of the value of |u L|. n expressions involving arithmetic and geometric 9 Explore further cases of your choice. sequences studied as part of the core course. 4 Patterns to innity Denition: Convergent sequences {u } is a convergent sequence with limu = L if and only if for n n The Greek letter n→∞ any ε > 0 there exists a least order m∈Z+ such that, for all epsilon, ε, is used n ≥ m⇒ |u – L| < ε among mathematicians n all over the world to This denition gives an algebraic criterion to test whether or not a represent a small given number L is the limit of a sequence. However, to apply this positive quantity. test, you must rst decide about the value of L. Example  3n 1 Show that the sequence dened by u = is convergent. n n+1 1.1 *Convergent y 4 3•n–1 u1(n) = n+1 3 Graph the sequence and observe its behavior as 2 n increases. 1 0 1 2 3 4 5 6 x –1 3n 1 3n−1−3n−3 4 Find a simplied expression for |u – 3| u 3 = −3 = = n n+1 n+1 n+1 n 4 4 4 The value of m is the least positive integer u −3 <ε⇒ <ε⇒n+1> ⇒n> −1 n n+1 ε ε 4 greater than −1 ε So, it is possible to nd m such that Use the denition to show that limu = 3 n ≥ m⇒ |u – L|< ε n→∞ n n ∴ lim u = 3 n n→+∞ Note that this denitions tells you that from the order m onwards, all the terms of the sequence lie within the interval ]L − ε, L + ε[ This means that the sequence can have exactly one limit, L. Useful theorems about subsequences of convergent and divergent sequences: It is usual to use set notation when describing sequences and If {b } ⊆ {a } is a subsequence of a convergent  n n their subsequences. For example sequence {a }, then {b } is also a convergent n n {b } ⊆ {a } means that the sequence and limb = lima n n n n sequence {b } can be obtained n→∞ n→∞ n If {b } ⊆ {a } and {c } ⊆ {a } are subsequences of from the sequence {a } by  n n n n n removing at least one of the a sequence {a } and limb ≠ limc then {a } is n n n n terms of {a }. In this way, {b } can n→∞ n→∞ n n not convergent (i.e. {a } is a divergent sequence). be seen as a part of {a }. n n Chapter 1 5