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OXFORD UNIVERSITY PRESS
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Acknowledgments We are grateful to the following for permission to reprint copyright material: Guardian News and Media Ltd for '618 is the Magic Number' by Marcus Chown, The Guardian, 16.1.2003, copyright© Guardian News & Media Ltd 2003. Professor Alan Tennant from the Helmholtz Association of German Research Centres for extract from press release 'Golden ratio discovered in a quantum world', 7 January 2010. Internet Systems Consortium, hlc (!SC) for figure: 'The growth of internet domains on the world wide web since 1994' from www.isc.org. Although we have made every effort to trace and contact copyright holders before publication this has not been possible in all cases. If notified, the publisher will rectify any errors or omissions at the earliest opportunity. The publishers would like to thank the following for permission to reproduce photographs: P3: Mary Evans Picture Library/Alamy; P4: Professor Peter Goddard/Science Photo Library; P12: Photo Researchers, Inc./ Science Photo Library; P24: Science Photo Library; P46: Associated Sports Photography/Alamy; P46: Trinity Mirror/ Mirrorpix/Alamy; P46: Sheila Terry/Science Photo Libraiy; P47: Dvmsimages/Dreamstime.Com: P47: Science Photo Library; P19: Taily_Sindariel/Dreamstime; PS1: New York Public Library Picture Collection/Science Photo Library; P94: Af Archive/
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Course Companion definition The IB Diploma Programme Course Companions are resource materials designed to provide students with support through their two-year course of study. These books will help students gain an understanding of what is expected from the study of an IB Diploma Programme subject. The Course Companions reflect the philosophy and approach of the IB Diploma Programme and present content in a way that illustrates the purpose and aims of the IB. They encourage a deep understanding of each subject by making connections to wider issues and providing opportunities for critical thinking. The books mirror the IB philosophy of viewing the curriculum in terms of a whole-course approach; the
use of a wide range of resources; international mindedness; the IB learner profile and the IB Diploma Programme core requirements; theory of knowledge, the extended essay, and creativity, action, service (CAS). Each book can be used in conjunction with other materials and indeed, students of the IB are required and encouraged to draw conclusions from a variety of resources. Suggestions for additional and further reading are given in each book and suggestions for how to extend research are provided. In addition, the Course Companions provide advice and guidance on the specific course assessment requirements and also on academic honesty protocol.
1B mission statement The International Baccalaureate aims to develop inquiring, knowledgable and caring young people who help to create a better and more peaceful world through intercultural understanding and respect. To this end the IB works with schools, governments and international organizations to develop challenging
programmes of international education and rigorous assessment. These programmes encourage students across the world to become active, compassionate, and lifelong learners who understand that other people, with their differences, can also be right.
The 1B Learner Profile The aim of all IB programmes is to develop internationally minded people who, recognizing their common humanity and shared guardianship of the planet, help to create a better and more peaceful world. IB learners strive to be: Inquirers They develop their natural curiosity. They
acquire the skills necessary to conduct inquiry and research and show independence in learning. They actively enjoy learning and this love of learning will be sustained throughout their lives. Knowledgable They explore concepts, ideas, and
issues that have local and global significance. In so doing, they acquire in-depth knowledge and develop understanding across a broad and balanced range of disciplines.
dignity of the individual, groups, and communities. They take responsibility for their own actions and the consequences that accompany them. Open-minded They understand and appreciate their
own cultures and personal histories, and are open to the perspectives, values, and traditions of other individuals and communities. They are accustomed to seeking and evaluating a range of points of view, and are willing to grow from the experience. Caring They show empathy, compassion, and respect
towards the needs and feelings of others. They have a personal commitment to service, and act to make a positive difference to the lives of others and to the environment.
Risk-takers They approach unfamiliar situations and
Thinkers They exercise initiative in applying thinking skills critically and creatively to recognize and approach complex problems, and make reasoned, ethical decisions.
uncertainty with courage and forethought, and have the independence of spirit to explore new roles, ideas, and strategies. They are brave and articulate in defending their beliefs.
Communicators They understand and express ideas and information confidently and creatively in more than one language and in a variety of modes of communication. They work effectively and willingly in collaboration with others.
Balanced They understand the importance of intellectual, physical, and emotional balance to achieve personal well-being for themselves and others.
Principled They act with integrity and honesty, with a
strong sense of fairness, justice, and respect for the
Reflective They give thoughtful consideration to their
own learning and experience. They are able to assess and understand their strengths and limitations in order to support their learning and personal development.
A note on academic honesty It is of vital importance to acknowledge and appropriately credit the owners of information when that information is used in your work. After all, owners of ideas (intellectual property) have property rights. To have an authentic piece of work, it must be based on your individual and original ideas with the work of others fully acknowledged. Therefore, all assignments, written or oral, completed for assessment must use your own language and expression. Where sources are used or referred to, whether in the form of direct quotation or paraphrase, such sources must be appropriately acknowledged.
How do I acknowledge the work of others? The way that you acknowledge that you have used the ideas of other people is through the use of footnotes and bibliographies. Footnotes (placed at the bottom of a page) or endnotes (placed at the end of a document) are to be provided when you quote or paraphrase from another document, or closely summarize the information provided in another document. You do not need to provide a footnote for information that is part of a "body of knowledge". That is, definitions do not need to be footnoted as they are part of the assumed knowledge. Bibliographies should include a formal list of
the resources that you used in your work. "Formal" means that you should use one of the several accepted forms of presentation. This usually involves separating the resources that you use into different categories (e.g. books, magazines, newspaper articles, Internet-based resources, CDs and works of art) and providing full information as to how a reader or viewer of your work can find the same information. A bibliography is compulsory in the extended essay.
What constitutes malpractice? Malpractice is behavior that results in, or may result in, you or any student gaining an unfair advantage in one or more assessment component. Malpractice includes plagiarism and collusion. Plagiarism is defined as the representation of the
ideas or work of another person as your own. The following are some of the ways to avoid plagiarism: • Words and ideas of another person used to support one's arguments must be acknowledged. • Passages that are quoted verbatim must be enclosed within quotation marks and acknowledged. • CD-ROMs, email messages, web sites on the Internet, and any other electronic media must be treated in the same way as books and journals. • The sources of all photographs, maps, illustrations, computer programs, data, graphs, audio-visual, and similar material must be acknowledged if they are not your own work. • Works of art, whether music, film, dance, theatre arts, or visual arts, and where the creative use of a part of a work takes place, must be acknowledged. Collusion is defined as supporting malpractice by another student. This includes: • allowing your work to he copied or submitted for assessment by another student • duplicating work for different assessment components and/ or diploma requirements. Other forms of malpractice include any action that gives you an unfair advantage or affects the results of another student. Examples include, taking unauthorized material into an examination room, misconduct during an examination, and falsifying a CAS record.
About the book The new syllabus for Mathematics Higher Level is thoroughly covered in this book. Each chapter is divided into lesson-size sections with the following features: Investigations
Exploration suggestions
f Examiner's tip ._
[ _o id_yo_ _ u_k_no_ w_?__ ) __.
[ Theory of Knowledge ) Historical exploration
The Course Companion will guide you through 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 proficiency 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. Questions are designed to increase in difficulty, strengthen analytical skills and build confidence through
understanding. Internationalism, ethics and applications are clearly integrated into every section and there is a TOK application page that concludes each chapter. It is possible for the teacher and student to work through the book in sequence but there is also the flexibility to follow a different order. Where appropriate the solutions to examples using the TI-Nspire calculator are shown. Similar solutions using the TI-84 Plus and Casio fx-9860GII are included on the accompanying interactive CD which includes a complete ebook of the text, extension material, GDC support, a glossary, sample examination papers, and worked solution presentations. Mathematics education is a growing, ever changing entity. The contextual, technology integrated approach enables students to become adaptable, lifelong learners. Note: US spelling has been used, with IB style for mathematical terms.
About the authors Josip Harcet has been teaching the IB programme for 20 years. After teaching for 11 years at different international schools he returned to teach in Zagreb. He has served as a curriculum review member, deputy chief examiner for Further Mathematics, assistant and senior examiner, as well as a workshop leader. Lorraine Heinrichs has been teaching IB mathematics for the past 12 years at Bonn International School. She has been the IB DP coordinator since 2002. During this time she has also been senior moderator for HL Internal Assessment and workshop leader for the IB. She was also a member of the curriculum review team. Palmira Mariz Seiler has been teaching mathematics for 22 years. She joined the IB community 11 years ago and since then has worked as Internal Assessment moderator, in curriculum review working groups, and as a
workshop leader and deputy chief examiner for HL mathematics. Marlene Torres-Skoumal has been teaching IB mathematics for the past 30 years. She has enjoyed various roles with the IB over this time, including deputy chief examiner for HL, senior moderator for Internal Assessment, calculator forum moderator, and workshop leader. A special thanks to Jim Fensom for the GDC chapters and contribution to the Prior Learning chapter.
Contents Chapter 1 Mathematics as the science of patterns
1.1 1.2 1.3 1.4 1.5 1.6 1.7
2
Number patterns: sequences, series and sigma notation Arithmetic sequences and series Geometric sequences and series Conjectures and proofs Mathematical induction Counting methods The binomial theorem
Chapter 2 Mathematics as a language
2.1 2.2 2.3 2.4
Relations and functions Special functions and their graphs Operations with functions Transformations of graphs of functions
Chapter 3 The long journey of mathematics
3.1 3.2 3.3 3.4 3.5 3.6
Introduction to complex numbers Operations with complex numbers Polynomial functions: graphs and operations Polynomial functions: zeros, sum and product Polynomial equations and inequalities Solving systems of equations
5 10 15 24 25 31 38
5.7
48
6.1
50 54 70 79 96
97 109 118 131 140 153
Chapter 4 Modeling the real world
166
4.1 4.2 4.3 4.4
168 180 189
4.5 4.6 4.7 4.8 4.9
Limits, continuity and convergence The derivative of a function Differentiation rules Exploring relationships between JJ' andf" Applications of differential calculus: kinematics Applications of differential calculus: economics Optimization and modeling Differentiation of implicit functions Related rates
205 208 211 215 218 221
Chapter 5 Aesthetics in mathematics 232
5.1 5.2 5.3
Recursive functions Properties of exponents and logarithms Euler's number and exponential functions
5.4
234
5.5 5.6
5.8
Invariance and the exponential function - a different approach to Euler's number 248 Logarithms and bases 249 Logarithmic functions and their behavior 258 Derivatives of exponential and 261 logarithmic functions Angles, arcs and areas 267
Chapter 6 Exploring randomness
278
Classification and representation of statistical data 6.2 Measures of central tendency 6.3 Measures of dispersion 6.4 Theoretical probability 6.5 Probability properties 6.6 Experimental probability 6.7 Conditional probability 6.8 Independent events 6.9 Probability tree diagrams 6.10 Bayes' theorem
280 288 291 299 306 308 312 318 321 326
Chapter 7 The evolution of calculus
342
7.1 7.2 7.3
Integration as anti-differentiation 344 Definite integration 352 Geometric significance of the definite 355 integral
Chapter 8 Ancient mathematics and modern methods
8.1
The right-angled triangle and trigonometric ratios 8.2 The unit circle and trigonometric ratios 8.3 Compound angle identities 8.4 Double angle identities 8.5 Graphs of trigonometric functions 8.6 The inverse trigonometric functions 8.7 Solving trigonometric equations 8.8 The cosine rule 8.9 The sine rule 8.10 Area of a triangle Chapter 9 The power of calculus
238
9.1 9.2
243
9.3
382
384 389 398 401 403 409 412 415 418 423 434
Derivatives of trigonometric functions 436 Related rates of change with trigonometric expressions 450 Integration of trigonometric functions 455
Integration by substitution Integration by parts Special substitutions Applications and modeling
461 466 472 480
Chapter 10 Modeling randomness
494
9.4 9.5 9.6 9.7
10.1 Discrete random variables and distributions 10.2 Binomial distribution 10.3 Poisson distribution 10.4 Continuous random variables 10.5 Normal distribution 10.6 Modeling and problem solving
Chapter 12 Multiple perspectives in mathematics
496 503 513 520 532 544
556 563 571 583 592 596 599 613 628
630 12.1 Complex numbers as vectors 12.2 Complex plane and polar form 633 12.3 Operations with complex numbers in 638 modulus-argument form 12.4 Powers and roots of complex numbers: De Moivre's theorem and applications 643 12.5 Mathematical connections 650 Chapter 13 Exploration
13.1 13.2 13.3 13.4 13.5 13.6 13.7
About the exploration Internal assessment criteria How the exploration is marked Academic honesty Record keeping Choosing a topic Getting started
1 2 3 4
Number Algebra Geometry Statistics
Chapter 15 Practice Papers
Chapter 11 Inspiration and formalism 554
11.1 Geometric vectors and basic operations 11.2 Introduction to vector algebra 11.3 Vectors, points and equations of lines 11.4 Scalar product 11.5 Vector (cross) product and properties 11.6 Vectors and equations of planes 11.7 Angles, distances and intersections 11.8 Modeling and problem solving
Chapter 14 Prior learning
660
660 661 666 666 667 668 669
Practice paper 1 Practice paper 2
672
673 697 719 745 754
754 757
Answers
760
Index
811
The material on your CD-ROM includes the entire student book as an eBook, as well as a wealth of other resources specifically written to support your learning. On these two pages you can see what you will find and how it will help you to succeed in your Mathematics Higher course. The whole print text is presented as a user-friendly eBook for use in class and at home. Extra content can be found in the Contents
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3
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cases
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13 333
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along
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diagonals?
explain
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rule
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series
A
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of
term
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i
a
sets
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ii
3,
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has
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So
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9,
of
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are
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all
order,
numbers
following
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cer tain
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r ule,
called
a
star t
sequences:
with
2
reciprocals
12,
all
7
defined
and
add
5
to
previous
number
of
natural
numbers
4
…
the
fixed
+
a
Each
numbers
17,
star t
terms
number
sequence
2
in
notation
1
3
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numbers
,
2
iii
of
1
,
of
sigma
sequences,
sequence.
12,
1
and
sequence.
the
7,
patterns:
+
in
of
+
17
+
3
and
sequence
terms
continues
12
a
with
then
gives
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indefinitely
22
is
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finite
add
is
3
to
a series.
series
series
If
series.
a fini te
the
previous
is
with
said
five
number
the
sequence
If
the
to
be infini te
terms.
sum
The
of
sum 1
1
1 +
1
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1
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+
+
…
is
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infinite
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+
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series. 2
2
1
1
1
3
4
4
3
is
known
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the
+
The
set
where
of
r
positive
represents
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can
general
be
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harmonic
series
can
be
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3,
4,
…,
r,
…} harmonic
series
The
value
term.
1
1
The
{1,
written
as
1
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1
+ 3
2
1
+…+ 4
+
…
r
1
where
is
the
general
term.
r
The
general
is
3r
is
finite.
The
is
but
how
( ∑)
you
2
of
only
the
take
notation
write
1
+
+
term
can
sigma
1
1
r
the
1
the
is
a
series
values
+
6
+
1
9
to
form
+
7
to
12
+
15
because
represent
+
the
a
18
+
21
series
series.
Here
series
1
+…+ 4
3
from
compact
1
+ 3
finite
+
…
+
using
sigma
notation:
largest
20
r
r
can
take
20
1
∑ r
=1
r
The
r
smallest
can
value
take
1
Read
this
as
‘The
summation
of
from
r
equals
1
to
20.’
r
∑
4
1
So
r
=1
1
1
=
∑
r
+
1
1
1
=
3
3
3
1
+
2
1
3
1
+
+
+ 27
9
3
3
the
capital
4
3
is
series
4
+
8
+
12
+
16
+
….
+
48
can
letter
sigma,
81
which
The
Greek
1
+
be
written
as
is
used
represent
‘the
to
sum
12
of ’.
4
×
1
+
4
×
2
+
4
×
3
+
4
×
4
+
…
+
4
×
12
=
∑
Leonhard
Euler
4r (1706–83)
was
the
r =1
rst
use
mathematician
this
to
notation.
Chapter
1
5
Example
Write
the
next
three
terms
and
1 a
2,
4,
8,
16,
…
,
b
the
1
,
12
1
1
,
6
term:
1
,
2
general
1
…
c
1,
,
4
2
20
1
,
,
…
8
Answers
a
For
the
sequence
the
next
are
32,
The
64,
2
,
2
in
3
,
2
2,
the
8,
in
16,
the
...
sequence
sequence
4
,
4,
terms
128.
terms
1
2
three
2
can
be
written
r
,
…
,
2 ,
…
r
General
where
term
r
can
is
2
take
the
values
1 b
For
the
1
,
sequence
1
terms
1
are
42
1
×
be
2
×
, ...
12
the
next
Look
for
three
20
written
1
1
,
2
...
56
can
1
,
ter m.
,
sequence
1
3,
general
1
,
30
The
,
6
2,
the
1
,
2
1,
1
Find
1
,
3
3
×
,
4
4
×
... ,
5
,
r
×
... the
patter ns
in
the
denominators.
+ 1)
(r
1
So
the
general
term
is
r
where
r
can
take
the
For
the
1
1 ,
sequence
1
1
are
1
,
1
32
1
,
1
2
,
,
1
1
next
three
1
1
...
64
1
1
,
2
1
,
3
2
,
32
,
1
2
the
8
,
16
,
0
2
…
written
1
,
1
,
=
, ...
4
be
1
8
3,
64
can
,
4
2,
,
sequence
1
1,
1
,
16
The
+ 1)
1
,
2
terms
(r
values
1 c
×
1
,
4
2
,
5
2
...
,
,
6
2
r
2
... 0
1
Since
the
sequence
has
general
term
the
is r
general
ter m
r
Example
Write
the
can
take
the
r
values
1,
2,
3,
(3r
first
three
terms
of
each
∞
series.
+
b
6)
∑
=1
r
(
1)
2
r
=1
Answers
7
a
∑ r
(3r
+
6)
=
9
+ 12
+ 15
+
...
Substitute
r
=
1
for
r
r
∑ r
(–1)
2
=
for
r
=1
2
=
(–1)
×
1
2
+
(–1)
2
×
2
4
–
3
+
(–1)
2
×
6
the
first
ter m,
=1
2
for
the
second
∞
b
3
+
1
r
r
ter m,
…
∞
∑
first
2
7
a
the
is
1
2
where
in
1
1
The
2
2
…
Mathematics
=
–1
as
+
the
9
+
science
…
of
patterns
the
third
ter m.
ter m,
and
r
=
3
represents
innity.
Example
F ind
Write
these
series
using
sigma
and a
2
+
b
–8
12
+
22
+
32
+
…
+
the
general
term
notation.
the
value
of
r
that
102
gives
the
last
term.
1
+
4
–
2
+
1
–
+
…
2
Answers
a
2
+
12
+
22
+
32
+
…
+
102
The
general
ter m
is
10r
–
8
11
For =
(10r
–
∑ r
the
ter m:
102
8)
10r
=1
8
=
102
10r
–
=
110
r
=
11
1 b
–8
+
4
–
2
+
1
–
+
…
Alter nating
signs
suggest
that
you
2 8
need
8
1
=
to
multiply
each
ter m
by
–1.
2
(–1)
×
+
(–1)
×
0
1
2
2
n
8 3
+
(–1)
8
is
positive
when
n
is
even
×
+
(–1)
×
2
3
2
negative
2
when
n
is
odd.
8
8 r
5
+
×
(–1)
and
4
(–1)
+
…
The
general
ter m
( −1)
is
×
4
r
2
1
2
∞
8 r
=
∑
(
1)
1
r
2
=1
r
Exercise
1
×
Write
1A
the
next
three
terms
for
each
1 a
–6,
–4.5,
–3,
–1.5,
…
3 ,
b
2
2
Write
the
general
term
for
1 a
2,
6,
12,
20,
…
1 ,
b
3
Given
terms
that
of
r
can
the
take
the
sequence
5
a
1 ,
6
...
c
3
4r
–
3
1 ,
1 ,
15
35
,
...
63
1 ,
,
17
1,
...
–1,
c
1,
3,
5,
…
26
2,
3,
general
…,
write
the
first
four
term:
r a
1 ,
8
1 ,
10
values
with
7 ,
sequence.
1 ,
2
5 ,
4
each
sequence.
1
b
c 2
2r
4
Expand
these
series
in
+1
r
full.
4
5
5
r a
∑ r
5
r (r
+ 1)
b
∑ r
=1
Write
these
a
–1
+
3
+
b
–1
+
1
–
c
6
–
12
+
series
7
1
+
+
24
using
11
1
–
–
48
+
1
r
c
=1
2r
∑
( − 1)
2
r
+1 r
sigma
=1
notation.
…
+
+
1
96
–
–
1
+
1
–
1
+
1
192
Chapter
1
7
Investigation
–
Use
at
your
GDC
to
look
quadratic
the
numbers
2
T
Enter
Use
this
3
+
data
table
second
by
2n
–
the
a
generated
by
+
n
=
sequences
in
to
n
where
the
list
.
GDC:
the
differences
quadratic
∈
rst
of
the
differences
numbers
and
the
generated
formula.
F irst
Second
difference
difference
2
n
–
2n
+
3
2 F irst
}
3
are
obtained
2
}
}
subtracting
2
}
consecutive
}
the
original
2
} 11
38
2
}
}
Second
differences
three
consecutive
integers
are
p
−
p
1,
and
p
+
values
to
to
calculate
justify
that
the
n
−
2n
second
+
3
for
each
difference
is
1.
the
one.
always
see
what
happens
if
you
repeat
the
task
rst
subtracting
terms
of
differences.
constant.
A
Now
by
consecutive
2
algebra
are
13
obtained
Use
sequence.
9
}
these
of
2
}
27
Use
terms
7
18
general
two
5
}
In
by
3
11
51
2
}
}
6
differences
1
general
form
for
any
using: quadratic
equation
2
T
=
2n
+
2n
+
1
2
is
T
=
an
+
bn
+
c
2
T
=
–n
+
3n
–
4 where
T ry
to
generalize
your
a,
b
and
c
are
results. constants.
Investigation
The
patterns
Enter
GDC
these
or
in
of
dots
triangular
represent
numbers
a
–
in
the
rst
numbers
ve
triangular
your
spreadsheet
and
then
T riangle work
out
the
rst
and
numbers.
numbers
F irst
difference
differences.
can
continue
consecutive
in
the
2
numbers
as
}
6
shown
ndings
sequences
from
the
}
a
investigation
formula
that
}
}
} }
to
6
the 21
triangular
8
numbers.
Mathematics
as
the
science
of
patterns
=
15
+
6
1
5
quadratic
generates
1
4
21
nd
1
3
}
10
table.
your
}
3
generating
15 Use
difference
1
} Y ou
Second
second
6
=
5
+
1
1
Investigation
The
the
diagrams
show
pentagonal,
lists
and
these
the
the
more
rst
method
of
terms
and
differences
of
the
to
patterns
the
square,
heptagonal
obtain
numbers.
formulae
that
Use
generate
numbers
Pentagonal
Hexagonal
your
numbers
numbers
Heptagonal
numbers
results
from
the
T erm
T riangular
Square
numbers
numbers
Pentagonal
Hexagonal
numbers
numbers
Heptagonal
Octagonal
Nonagonal
Use
ve
hexagonal
number
numbers.
Square
Use
the
–
the
investigations
to
complete
this
table.
1st
2nd
3rd
4th
5th
6th
1
3
6
10
15
21
1
4
9
16
25
1
5
12
1
6
15
7th
8th
nth
numbers
numbers
numbers
table
to
make
a
conjecture
about
the
nth
term
of
any
polygonal
number .
Chapter
1
9
.
The
Arithmetic
picture
arches
To
on
find
level
you
This
gives
Each
➔
will
If
5
common
you
write
count
arches
20
is
ari thmetic
If
to
of
a
series
building
with
5,
the
10,
more
will
arches
be
on
on
the
each
four th
level.
15.
than
between
constant
first
two
then
progression .
and
dierence
the
there
the
previous
one,
so
the
next
arches.
difference
sequence
front
arches
sequence
has
have
the
many
need
the
the
and
level.
how
first
floor
floor
represents
each
out
sequences
term
u
consecutive
this
We
is
an
call
denote
then
ari thmetic
this
it
the
numbers
constant
by
in
a
sequence
difference
or
an
the
d.
sequence
of
arches
is
1
This
u
=
5
=
5
is
recursive
1
u
+
5
=
u
2
+
d
Y ou
1
=
u
10
+
5
=
u
3
+
d
any
can
term
is
found
from
the
previous
one
by
adding
the
common
equation
know
difference
u
=
u
n
+
n
Look
–
again
=
5
=
5
d
1
at
the
terms:
1
+
5
=
u
2
u
=
10
+
5
=
u
=
15
+
5
=
u
d
+
d
=
u
+
d
=
u
2
4
This
+
1
3
u
3
leads
to
the
+
2d
+
3d
1
1
general
term
u
=
u
n
➔
An
arithmetic
sequence
+
(n
–
1)d
1
with
the
first
term u
and
common
1
difference
d
is
u
,
1
The
general
term
u
+
d,
u
1
is
Example
Three
Their
Find
sum
2d,
. . .
,
u
=
u
u
+
(n
–
1)d.
1
+
(n
–
1)d
in
an
1
numbers
the
+
1
n
is
are
48
three
consecutive
and
their
terms
product
is
arithmetic
sequence.
2800.
numbers.
Answer
Let
the
u
–
d,
u
–
d
three
u,
+
u
u
+
+
numbers
be
d
u
+
d
=
48
3u
=
48
u
=
16
Write
the
sum
{
10
out
using
or
only
can
if
this
you
generate
d.
the
u
equation.
work
term
a
2
Each
u
called
Mathematics
as
the
science
of
patterns
of
the
three
Continued
numbers.
on
next
page
previous
term.
(u
–
d) u(u
+
d)
2
=
Write
2800
u (u
–
d
)
2
=
2800
=
175
–
d
by =
±
d
=
±
The
7,
256
numbers
Find
the
a
50,
b
a,
47,
16
and
divide
two
values
of
d
give
two
possible
sequences:
7,
16,
25
or
25,
16,
7
number
3a,
are
25.
Example
=
16.
The
and
u
175
9
three
16
product.
Substitute
2
16
d
the
2
44,
5a,
of
...,
...,
terms
in
these
arithmetic
sequences:
14
21a
Answers
u
a
=
50,
=
53
d
=
−3
Using
u
1
=
u
n
u
−
+
(n
−
1)d
1
3n
n
53
−
3n
=
14
3n
=
39
n
=
13
Using
u
=
14
and
solving
for
n
n
u
b
=
a,
=
(2n
d
=
2a
1
u
−
1)a
n
(2n
−
1)a
=
21a
2an
=
22a
n
=
11
Example
The
second
Find
the
term
of
common
an
arithmetic
difference
and
sequence
the
first
is
15
term
and
of
the
the
fifth
term
is
21.
sequence.
Answer
u
=
2
u
+
d
=
15
Using
u
1
=
5
u
= n
+
4d
=
u
+
(n
−
1)d
1
21
1
3d
=
d
u
u
=
=
6
Solving
simultaneously
2
15
−
2
=
13
1
Exercise
1
2
Find
a
5,
c
a,
Find
a
2,
1B
the
11,
a
+
the
11,
nth
17,
2,
−1,
20,
c
3,
7,
+
of
these
sequences.
…
4,
a
10,
b
+
6,
3,
– 4,
–11
…
indicated
in
each
...
15th
term
...
12th
term
of
these
arithmetic
sequences:
3
, 4
23,
terms
1 b
a
term
, 2
11,
...
(n
+
1)th
term
Chapter
1
11
The
3
four th
common
The
4
four th
first
A
would
initial
per
is
arithmetic
–5.
an
40.
Find
sequence
the
arithmetic
Find
the
first
is
term
sequence
common
18
and
and
is
0
the
the nth
and
difference
term.
the
and
the
to
of
sum
be
hold
of
Here
S
=
S
=
an
was
Gauss
5050.
rising
salar y
have
Gauss
the
year
states
by
after
this
that
the
annual
15
carries
increments
years?
position
job
How
for
a
a
of
many
50%
salar y
€500.
years
salar y
of
How
much
would
increase
a
on
the
salar y?
sum
surprise
as
of
term
the
person
find
term
is
adver tisement
€48000
When
an
term.
job
The
of
difference
four teenth
5
term
1
11
the
years
the
how
+
+
old
numbers
gave
is
100
arithmetic
he
his
did
teacher
from
correct
series
1
to
challenged
100.
answer
2
+
3
+
4
+
...
99
+
+
98
+
97
+
...
2
+
101
+
101
+
...
101
+
=
101
+
101
2S
=
101
×
100
+
the
to
teacher’s
immediately
it:
99
2S
T o
almost
him
100
1
101
10 100 * 2
Carl
Friedrich
(1777–1855)
German
mathematician
The
numbers
1
to
100
are
an
arithmetic
series
with
1
and
method
common
for
calculating
Generalizing
term
u
difference
and
this
the
method
common
1.
sum
for
a
Gauss
of
a
finite
series
difference
d
had
found
is
queen
of
all
sciences”
a
arithmetic
containing n
“Mathematics
first the
term
Gauss
series.
terms,
with
first
gives
1
S
=
u
n
S
=
u
n
2S
u
+
(n
=
–
1)d
+
u
+
+
(n
–
1)d
+
+
(n
+
(n
–
–
2)d
+
(n
–
1)d
1)d]
n
[2u
n
+
(n
–
1)d]
1
2
12
+
Mathematics
as
the
science
u
+
of
+
2u 1
1
=
S
+
2d
+
…
+
1
1
n[2u
u
u
+
patterns
(n
–
2)d
+
1
(n
–
3)d
+
…
+
u
+
(n
+
d
+
(n
–
1)d
+
…
+
2u 1
1)d
u
1
+
–
1
u
1
2u
1
=
d
1
2u
n
+ 1
1
n
2S
+
1
+
(n
1
–
1)d
+
2u 1
+
(n
–
1)d
This
formula
can
also
be
written
as
n
S
=
[u
n
+
u
1
+
(n
–
1)d ]
1
u
2
+
(n
–
1)d
=
u
1
n
n
=
[u
+
u
1
]
n
2
➔
The
sum
of
a
finite
arithmetic
series
is
n
S
=
[
2u
n
+
(n
–
1)d ]
1
2
n
(u
=
+ u
1
)
n
2
where
n
is
the
number
of
terms
in
the
series, u
is
the
first
1
term,
is
u
the
last
term
and
d
is
the
common
difference.
n
Example
The
first
series
Find
term
has
the
9
of
an
arithmetic
series
is
2
and
the
last
term
is
26.
The
terms.
sum
of
the
series.
Answer
u
=
2,
u
1
=
26,
n
=
9
9
n
9
S
=
(2
+
26)
=
Using
126
S
=
(u
n
9
Example
The
first
The
sum
Find
+
u
1
) n
2
2
term
the
of
of
the
an
arithmetic
series
number
of
is
series
is
25
and
the
four th
term
is
13.
–119.
terms
in
the
series.
Answer
u
=
25
+
3d
1
u u
=
=
u
4
13
+
3d
1
1
Find 3d
=
13
d
=
–4
–
d.
25
n
S
=
[2u
n
+
(n
–
1)d]
1
2
n
–119
=
[50
–
4(n
–
1)]
Solve
for
n.
2
–238
=
n(54
–
4n)
2
4n
–
54n
–
238
=
0
2n
–
27n
–
119
=
0
(2n
+
=
0
Divide
by
2. The
natural
numbers
2
7)(n
–
17)
is
the
set
{0,
Factorize.
1,
2,
...}
It
+
differs
from
because
+ +
Since
n
∈
,
n
=
17
is
the
set
of
positive
integers. it
includes
zero.
Chapter
1
13
Example
10
Calculate
∑ r
(5r
− 7)
=1
Answer
u
=
2
1
d
=
u
5
=
43
10
10
S
=
(
2
+
43)
=
Use
205
the
for mula
for
the
sum
of
a
10
2
finite
arithmetic
series
or
Using
a
GDC:
10
∑ r
(5r
− 7)
Exercise
1
2
=
207
=1
1C
Evaluate
a
6
b
52
+
c
–78
these
19
+
+
41
–
32
+
82
series.
+
30
–
…
+
110
+
…
–
25
–
90
–
…
86
–
142
Calculate:
10 15
a
r
(5r
7)
b
∑ r
3
Find
first
the
sum
term
is
EXAM-STYLE
4
The
four th
The
sum
Find the
5
The
(5 − 3r )
1
sum
of
60
an
and
arithmetic
the
10th
series
term
is
with
16
terms,
given
that
–3.
QUESTIONS
term
the
first
of
of
=1
of
first
five
an
an
arithmetic
five
terms
is
series
is
8.
25.
terms.
arithmetic
series
is
given
by S
=
n(2n
+
3).
Find
n
the
14
common
Mathematics
difference
as
the
and
science
of
the
first
patterns
four
terms
of
the
series.
the
.
The
Geometric
diagram
named
shows
after
described
the
it
in
sequences
the
Polish
rst
three
steps
mathematician
in
and
series
constructing
Waclaw
Sierpinski’ s
Sierpinski
who
triangle,
Claudia
Zaslavsky
(1917–2006)
rst
Ethnomathematician
1915.
Researched
expressions
of
mathematics
African
1
If
you
2
count
sequence
the
the
1,
number
3,
of
white
9,
27
white
3
triangles
Figure
5
triangles
in
each
would
is
of
the
have
three
gures
81
times
white
the
1
to
4
you
triangles.
number
in
get
At
the
words
the
each
stage
previous
the
sides
of
the
original
triangle
are
1
unit
long ,
then
the
length
of
stage.
each
number
and
reckoning
games,
Africa If
culture,
including
4
and
green
triangle
will
time,
patterns.
Counts
published
the
signs,
of
was
side in
1973.
1
1
of
in
be
unit;
each
side
of
the
orange
triangles
will
be 4
2 1
unit
and
each
side
of
the
blue
triangles
is
unit. 8
2
If
the
area
of
the
rst
triangle
is
1
unit
,
then
the
area
of
the
green
triangle
1 2
is
unit
,
since
four
of
the
green
triangles
make
up
the
original
triangle.
The
4 1 2
area
of
each
orange
triangle
will
be
unit
and
of
each
blue
triangle
will
be
16 1 2
unit 64
Hidden
in
Sier pinski’s
triangle
are
the
sequences: The
1,
3,
9,
27,
...
To
get
next
term
multiply
previous
term
by
ratio
of
3 consecutive
1
1,
1 ,
2
,
4
multiply
previous
term
To
get
next
term
multiply
previous
term
4
ratio
this
call
the
is
of
a
this
two
consecutive
geometric
ratio
sequence
the
1,
3,
terms
9,
or
sequence
common
27,
ratio
=
…u
in
1,
a
a
geometric
and
r
sequence
=
denote
3
and
it
the
is
constant
progression .
by
r.
recursive A
For
u
equation
–
1
sequence:
=
1
=
1
one
in
which
the
r
n
this
u
recursive
is: is
=
n
each
by
1
u
for
by
1 , ...
equation
constant
sequences.
the
We
for
term
64
then
So
next
1 ,
If
get
8
16
➔
To
...
a
2
1 ,
1,
is
,
4
1
terms
1
1
next
term
as
function
a
is
dened
of
ear lier
terms.
1
u
×
3
=
u
2
×
r
×
r
1
2
u
=
3
×
3
=
u
3
=
u
2
×
r
×
r
1
3
u
=
9
×
3
=
u
4
×
r
=
u
3
1
n
This
leads
to
the
general
term
u
=
n
➔
In
a
geometric
sequence
u
×
–
1
r
1
with
first
term u
and
common
ratio
r
Why
have
these
values
1
n–1
the
general
term
is
given
by
u n
=
u
×
r
of
,
r
≠
–1,
0,
r
been
omitted?
1.
1
Chapter
1
15
Example
Find
two
a
the
common
terms
10,
of
25,
1
of
these
sequences
and
write
the
next
sequence.
...
18
3
2a
each
...
6
a,
of
1
,
2
c
each
62.5,
1
,
b
ratio
5
,
4a
,
...
Answers
25 a
r
=
= 2.5 10
The
next
two
1 b
r
=
terms
1
−
156.25
and
=
−
2
3
1
The
next
390.625
1
÷
6
are
two
terms
1
are
and
54
162
3
2a 2
c
=
r
=
2a
a
7
The
next
Example
Find
the
two
2,
4,
b
5,
10,
are
8a
9
and
16a
number
a
terms
8,
...,
of
terms
in
each
of
these
geometric
sequences.
256
k
20,
...,
5
×
2
=
2
×
128
=
5
×
2
Answers
a
u
=
2,
=
2
r
=
2
1
n−1
u
×
2
7
=
2
×
2
n
n
b
=
u
8
=
5,
r
=
2
1
n−1
u
=
5
×
2
k
n
n
=
k
+
Exercise
1
Write
1
1D
down
the
6th
term
and
the
nth
term
3
a
2
1,
Find
2,
4,
the
…
b
common
9,
ratio
3,
1
and
...
the
c
terms
sequences.
a
48,
24,
16
,
b
3
16
12,
8
−
...
10th
,
5th
term
4
, 9
Mathematics
...
term
27
as
the
science
of
patterns
x
of
each
sequence.
2
,
x
,
x,
…
indicated
in
each
of
these
Find
3
the
number
of
terms
in
each
of
these
sequences.
1
0.03,
a
0.06,
0.12,
...,
1.92
81,
b
27,
9,
...., 81
The
4
third
term
Find two
term
5
6
in
first
is
What
term
is
of
of
geometric
The
sum
How
could
values
a
the
numbers
common
geometrical
of
the
sequence
common
is
2
and
ratio
the
and
fifth
the
is
18.
second
case.
The
a
a
possible
each
The
9.
of
a
geometric
value
−
4,
a
of
+
the
2
sequence
seventh
and
progression.
3a
+
Find
1
is
and
the
fifth
term
term?
are
the
16
three
two
consecutive
possible
values
terms
of
the
ratio.
of
a
you
geometric
find
the
sum
of
series
the
first
10
terms
of
the
series
n–1
1
+
3
+
9
+
…
+
+
3
…
?
Write
2
S
=
1
+
3
+
3
3
+
3
9
+
…
+
3
10
Multiply
the
whole
series
by
3
and
subtract
from S:
2
S
=
1
+
3
+
3
3
+
3
3
+
3
+
3
9
+
…
+
3
+
…
+
3
10
2
3S
=
3
9
10
+
3
–
3
10
10
(1
–
3)S
=
1
10
This
gives
10
1
3
1 10
S
=
=
(3
− 1)
10
1
To
by
3
find
2
the
sum
multiplying
of
by
the
the
first
n
terms
common
of
a
ratio r
geometric
and
series
2
S
=
+
u
n
1
r
+
use
the
same
process
subtracting:
3
+
r
r
n
+
…
+
1
u
3
rS
=
+
u
n
–
1
r
1
1
u
1
n
+
…
1
+
u
r
–
1
n
+
1
u
r
1
n
(1
–
r)S
=
➔
The
–
u
n
1
sum
of
a
u
r
1
geometric
series
is
given
by
n
u
(1
r
)
1
S
=
, r
≠ 1
n
1
where
n
r
is
the
number
of
terms,
u
is
the
first
term
and
r
is
the
1
common
ratio.
Chapter
1
17
Investigation
In
the
diagram,
The
string
half
is
AB
–
infinite
represents
a
sums
piece
of
string
11.28
cm
long.
is
cut
in
half
and
one
half,
CD,
is
placed
underneath.
again
cut
in
half
and
one
half,
DE,
is
placed
next
repeated
twice
more
and
the
total
length
of
the
pieces
A
to
CD.
placed
The
The
side
process
by
AB
=
11.28 cm
CD
=
5.64 cm
CD
+
D
E
DE
DE
=
2.82 cm
C
D
E
CD
CD
C
D
E
F
If
this
BUT
process
can
is
never
continued
exceed
indenitely,
11.28
cm,
the
+
DE
=
+
8.46 cm
the
=
EF
=
9.87 cm
+
+
FG
1.41 cm
DE
+
EF
=
total
original
length
length.
=
0.705 cm
will
continue
u
=
=
5.64
DE
u
=
1
=
5.64
×
2
2
3
2
⎛ 1 ⎞
⎛ 1 ⎞ EF
u
=
=
5.64
×
3
FG ⎜
u
=
5.64
× ⎜
4
⎟ 2
⎝
=
⎝
⎠
n
⎟ 2
⎠
1
⎛ 1 ⎞
u
=
5.64
× ⎜
n
⎟ 2
⎝
⎠
1
This
is
a
geometric
sequence,
rst
term
5.64
and
common
ratio
2
The
sum
of
n
terms
of
this
series
will
therefore
be
n
⎛
5.64
(1
r
⎞
⎛ 1 ⎞ 1
⎜
⎟
⎟
⎜
n
u
⎜
⎟ ⎝ 2 ⎠
)
⎝
⎠
1
S
=
=
n
1
r
1 ⎞
⎛ 1
⎜
⎟ 2
⎝
Enter
as
n
Note
ver y
this
on
gets
that
the
when
close
geometric
18
as
the
string,
to
⎠
see
what
happens
bigger .
to
you
and
series
is
number
the
series
geometric
Mathematics
sum
11.28,
Convergent
value
GDC
series
as
the
the
15
terms
original
of
terms
does
not
science
of
to
is
series
when
gets
converges
result
length.
divergent
convergent
the
the
bigger.
a
sum S
converge
patterns
it
sum
In
=
the
tends
to
a
finite
investigation
11.28
increasing
Mathematically:
1
CD
10.575 cm
G FG
a
noted.
F EF
If
is
is
D
C
the
side
B
C
A
remaining
cm.
is divergent
with
Investigation
In
at
order
the
to
–
understand
formula
for
the
convergent
the
condition
sum
of
n
for
series
convergence
now
look
terms:
n
u
(1
r
)
1
S
= n
(1
r )
n
Use
your
GDC
to
calculate
these
values
+
r
of
for
n
∈
1
,
≤
n
≤
10: What
happens
as
n
n
3
⎛ n
⎞
n
3
a
increases?
2
b
c
⎜
⎟ 2
n
n
1
⎛ d
⎜
e
⎟
values
your
f
⎞
⎜
⎟ 4
⎠
r
of
results
3
⎛
⎟ 5
⎝
other
Use
n
⎞
⎜
5
T ry
1
⎛
⎞
to
justify
these
statements:
n
●
r
>
⇒ r
1
increases
n
as
gets
larger .
The
larger
the
value
of
r,
the
n
faster
the
value
of
r
increases.
n
●
0
r
2)
7k
+
1
then
2
2k
∴
–
6
7(k
>
+
0
since
1)
+
1
k
+
>
+
(2k
–
6)
k
8
(2k
7k
–
6)
>
7(k
+
1)
+
+
+
2k
1
+
+
1
2k
>
+
1
1
2
It
∴
follows
P (k
Since
+
1)
P (8)
proved
is
the
by
(k
+
1)
>
7(k
+
1)
+
1
tr ue.
was
that
follows
that
that
if
the
shown
P (k)
is
to
tr ue,
principle
statement
is
be
of
true
tr ue,
P (k
+
and
1)
is
it
was
also
mathematical
for
all
positive
also
tr ue,
it
induction
integers
n
≥
8.
Chapter
1
27
Example
Use
the
principle
of
mathematical
induction
to
prove
that
n
2
∑
r ( 2r
+ 6)
=
n (n
+ 1)( n
+ 5)
3 r =1
Answer
n
2
P
=
r ( 2r
∑
n
+ 6)
=
n (n
+ 1)( n
+ 5)
3 r =1
P
:
1
LHS
=
1
×
8
=
8
2
RHS =
× 1 ×
2
×
6
=
8
3
LHS
=
RHS
⇒
P
is
tr ue.
1
Assume
P
is
tr ue,
i.e.,
Add
on
the
next
number
in
k
k
the
2
sequence
+
∑
r ( 2r
+ 6)
=
k (k
+ 1)( k
+ 5) ,
k
∈
3
(k
r =1
Show
P
is
tr ue,
+
1)(2(k
+
1)
+
6)
i.e.,
k+1
k +1
2
∑
r (r
+ 1)
=
(k
+ 1)(( k
+ 1) + 1)(( k
+ 1) + 5)
Using
the
assumption
from
3 r =1
step
2
=
(k (k
+ 1)( k
+ 2 )( k
2.
+
1)
is
a
common
factor.
+ 6)
3
LHS:
k +1
k
⎛
∑
r ( 2r
+ 6)
⎞
=
∑
⎜ ⎝
r =1
r
r ( 2r
+ 6)
Expand
+ u ⎟
and
simplify.
k +1
⎠
=1
2
=
k (k
+ 1)( k
+ 5) + ( k
+ 1)( 2( k
+ 1) + 6 )
3
using
the
assumption
2
=
k (k
+ 1)( k
+ 5) + ( k
+ 1)( 2k
+ 8)
This
is
the
expression
3
obtained ⎛ 2
= (k
k (k
+ 5) + ( 2k
+ 8)
⎜
substituted
⎟ 3
⎠
2
=
(k
+ 1)( k
+ 2 )( k
+ 6)
3
=
RHS:
Since
was
P (k
P
(1)
also
+
1)
the
28
was
shown
proved
is
principle
n
=
⎞
+ 1)
⎝
when
also
of
that
true,
if
it
to
is
Mathematics
true
as
for
the
tr ue,
is
follows
mathematical
statement
be
P (k)
all
and
by
the
induction
values
science
it
tr ue,
of
of
that
n
≥
1.
patterns
in
P(n).
k
+
1
is
Exercise
Use
1
1H
mathematical
series
with
first
induction
term
u
and
to
prove
common
that
for
ratio
r,
a
geometric
the
sum
of
the
1
first
n
terms
S
is
given
by
n
n
u
(1
r
)
1
S
n
1
Use
2
r
mathematical
induction
to
prove
these
statements.
n
n 2
a
r
∑
=
( n + 1)( 2 n + 1) 6
r =1
n
r
b
1
n
2
∑
=
2
−1
r =1
2
n 3
3
1
c
+
3
2
+
3
3
+
. . .
+
n
2
=
(n
+
1)
4
n
n d
r (r
∑
+ 2)
=
( n + 1)( 2n + 7 ) 6
r =1
Example
2n
2n
Use
by
mathematical
8
for
all
n
∈
induction
to
prove
that
3
+
7
is
This
divisible
is
a
means
that
multiple
of
3
+
7
8.
Answer
2n
P (n):
Step
3
+
7
=
8A
1
0
When
so
n
P (0)
Step
=
is
0,
LHS
=
+
7
=
8
tr ue.
Recall
2
value
that
include
Assume
k
that
≥
0,
P (k)
k
∈
is
tr ue
for
some
n
=
0
the
so
we
natural
must
numbers
star t
+
+
Step
7
=
8A,
A
∈
3
Prove
that
P (k
+
1)
is
2(k+1)
3
tr ue.
+
+
7
=
8B,
B
∈
Proof:
Using
2(k+1)
assumption
2k
3
+
7
=
9
=
9(8A
×
3
=
72A
=
8(9A
=
8B
+
–
–
7)
63
7
+
+
7
7
+
Since
tr ue,
P (k)
it
with
0.
2k
3
3
P (0)
and
is
it
was
statement
numbers
is
to
proved
+
the
mathematical
9A
B
P (k
by
7)
shown
was
tr ue,
follows
–
1)
is
also
principle
for
all
a
∈
,
positive
+
since
A
∈
integer.
be
that
induction
tr ue
is
7
if
tr ue,
of
that
the
natural
n
Chapter
1
29
Example
+
Prove
that
for
all
values
of
n
∈
3
,
n
+
5n
is
a
multiple
of
6.
Answer
3
Let
P (n)
=
n
+
5n
×
1
3
P (1)
=
1
+
Statement
Assume
5
is
tr ue
P (k)
is
+
k
∈
6
for
tr ue
n
=
for
1.
k
≥
1,
3
Use
=
then
k
+
assumption
5k
to
=
6A,
show
A
that
∈
P (k
3
(k
+
+
1)
+
1)
+
5(k
+
1)
=
6B,
B
∈
LHS
3
2
=
k
+
=
6A
3k
+
3k
+
1
+
5k
+
5
+
5k
3
2
–
5k
+
3k
+
3k
+
1
+
Using
5
k
=
6A
–
5k
from
step
2.
2
=
6A
+
3(k
=
6A
+
3[k (k
=
6(A
=
6B
=
RHS
if
+
2)
1)
+
2]
k(k
C)
it
was
it
+
1)
is
was
also
tr ue,
integers
is
to
proved
P (k
follows
mathematical
statement
shown
by
+
is
for
is
=
of
2C,
any
even
numbers
C
and
is
∈
two
the
also
since
consecutive
sum
of
two
even.
also
principle
induction
tr ue
even
tr ue,
2
that
1)
the
be
+
product
integers
P (1)
P (k)
tr ue,
k
+
the
Since
and
+
+
all
that
of
the
positive
n
Exercise
1I
n
1
Use
mathematical
induction
to
prove
that
7
–
n
∈
1
is
divisible
+
by
2
6
for
Prove
all
by
n
∈
mathematical
induction
that
2
1
+
3
+
5
+
7
+
…
+
(2n
–
1)
=
+
n
for
n
3
Prove
by
mathematical
induction
that
9
induction
that n
−
1
is
a
multiple
–
n
is
a
multiple
+
of
8
for
n
∈
3
4
Prove
by
mathematical
of
+
for
n
∈
n
1
5
Show
using
mathematical
induction
that
r =1
30
Mathematics
as
the
science
of
patterns
n =
r
r
+ 1
n +1
6
Prove
6
by
mathematical
n+2
values
Find
7
of
n,
2
the
first
2u
1
induction
that
for
all
positive
integer
2n+1
+
five
3
is
terms
exactly
of
the
divisible
sequence
by
7.
given
by u
=
1,
1
r
u
=
r+1
3
n
⎛
Prove
using
mathematical
induction
that
u
=
− ⎜
n
⎝
.
Counting
Some
a
number
of
Look
⎧
at
the
u
problems
involve
large
counting
Factorial
1
⎟ 3
⎠
methods
mathematical
combinations
2 ⎞
3
about
numbers
arrangements
so
you
will
and
need
to
develop
techniques.
notation
first
four
terms
of
this
sequence.
= 1
0
:
u n
⎨ =
u ⎩
u
×
n
u
n
=
1
=
1
1
n
0
u
×
u
1
=
1
=
2
×
1
=
3
×
2
0
u
=
2
×
u
=
3
×
u
2
1
u 3
×
1
2
The
u
=
general
n
×
(n
term
–
1)
of
×
(n
this
–
2)
sequence
×
…
×
3
is:
×
2
×
1
n
This
A
simpler
way
to
denote
this
sequence
is
to
use
factorial
is
read
as
notation u
equals
n
factorial’.
n
where
u
=
n!
n
It
follows
that
u
=
0!
=
1
0
Working
with
Here
the
are
large
first
numbers
few
is
factorial
easier
using
factorial
notation.
numbers.
Christian
0!
=
1
1!
=
1
Kramp
(1760–1826),
=
1
×
French
2!
=
2
×
1
=
3!
=
3
×
2
×
a
0!
2
×
mathematician,
1!
introduced
1
=
3
×
factorial
2! notation.
4!
=
➔
4
n!
×
3
=
×
n
2
×
×
(n
1
–
=
1)
4
×
×
3!
(n
–
2)
×
…
×
3
×
2
×
1
=
n
×
(n
–
1)!
8!
Y ou
can
use
this
patter n
to
calculate
expressions
such
as 6!
8!
8 × 7 ×
6 × 5 × 4 × 3 × 2 ×1
= 8
=
6!
×
7
= 56
6 × 5 × 4 × 3 × 2 ×1
Chapter
1
31
Example
10 !
×
5!
Evaluate 7!
×
6!
Answer
10 !
×
5!
10
×
9 ×
8 ×
7! ×
5!
=
7!
×
6!
7!
10 ×
×
9 ×
6
×
5!
8
=
6
=
120
Example
Simplify
(n
+ 1) !
(n
a
+ 1) !
+
n !
b
(n
1) !
(n
1) !
Answers
(n
+ 1) !
(n
+ 1) × n
× (n
− 1) !
= a (n
1) !
(n
= n (n
(n
+ 1) !+
1) !
+ 1)
n !
Rewrite
(n
+
1)!
b (n
1) !
as
(n
+ 1) n ( n
− 1) ! +
n (n
(n
and
(n
+ 1) n
+
1)
×
n
×
(n
–
1)!
− 1) !
=
(n
+
n!
=
n
×
(n
–
1)!
1) !
n
= n (n
=
+ 2) )
1
Exercise
1
Copy
8!
and
–
10!
complete
–
4!
95!
–
94!
1)!
–
simplifying
the
expressions.
n!
Evaluate:
4 !
5!
a
×
8!
3!
b
×
6!
c
6!
3
table
9!
–
+
this
7!
5!
(n
2
1J
5!
6!
Simplify:
2
n !
+
( n − 1) !
n !
a
−
(n
2) !
QUESTION
2
( 2n + 2 ) !( n !) 4
Show
2( 2n
+ 1)
=
that 2
[ (n
32
Mathematics
as
+ 1) !]
the
!)
1!
c
( n + 1) !
EXAM-STYLE
(n
( n − 1) !
b
(n
( 2n ) !
science
of
+ 1)
patterns
n !
+ 1
Arrangements
Alma
lays
the
eggcup,
a
arrange
them
each
glass
person,
three
breakfast
Having
from,
Here
from
made
which
are
a
cup
she
the
left
her
different
person.
decides
that
is
can
her
Christmas
each
choice
leaves
on
she
Here
she
first
for
so
thinks
objects.
then
the
a
row ,
since
different
Starting
and
in
table
there
her
with
She
for
people
cannot
arrange
are
6
six
decide
them
ways
with
how
differently
of
an
to
for
arranging
reasoning:
choose
she
to
Day
is
the
left
one
eggcup,
with
way
two
to
the
glass
objects
choose
or
to
the
the
cup.
choose
third
object.
arrangements:
E
EGC
CEG
ECG
So
CGE
there
are
3
represents
eggcup
GEC
GCE
×
2
×
1
=
6
ways
of
arranging
three
distinct
objects
in
G
represents
glass
C
represents
cup
a
row .
Similarly
with
choosing
the
of
2
choosing
ways
object,
This
in
n
of
the
–
objects
object
a
n
1)
total
can
distinct
×
(n
the
–
The
number
row
is
of
be
×
of
arrange
for
each
Having
third
4
×
3
×
…
×
ways
can
3
of
×
2
of
1
=
a
row
these
the
and
×
to
be
2
in
chosen
object
extended
objects
2)
to
and
second.
choosing
reasoning
(n
➔
first
giving
which
×
four
deduce
1
=
two
way
that
in
of
the
a
are
4
there
ways
are
objects
3
of
ways
there
choosing
different
arranged
×
ways
first
one
24
there
the
are
last
arrangements.
number
row
of
ways
is
n!
arranging
n
distinct
objects
in
The
a
different
which
objects
arranges
angels,
ways.
a
some
snowman
She
reasons,
indistinguishable
this.
Here
AASB
AABS
can
is
a
list
AASB
Christmas
and
a
however,
the
of
all
of
possible
ASBA
decorations
She
that
number
ABSA
AABS
bell.
can
since
in
a
arrange
the
different
two
line:
them
two
in
angels
4!
identical
=
are
permutations
24
is
less
than
arrangements:
ABSA
ASBA
BSAA
BSAA
SABA
A
SABA
ABAS
BAAS
BAAS
SAAB
SAAB
ASAB
ASAB
BASA
BASA
SBAA
SBAA
–
angel
Fan
Rong
B
–
bell
Chung
S
–
snowman
(1949–)
K
Graham
Taiwanese
mathematician
many
The
arrangements
arrangements
differently .
in
on
Because
the
the
the
left-hand
right
angels
column
because
are
the
are
two
identical
only
different
angels
there
are
are
only
from
shown
12
ways
problems
combinatorics
easily
could
arranging
the
four
“...
from
were
explained,
get
quickly
of
be
called
are
arrangements
ABAS
the
in
n!
arranged
Alma
ways
into
but
you
them
getting
objects.
out
was
hand
often
ver y
... ”
Chapter
1
33
The
number
of
ways
of
arranging
4
objects,
two
of
which
are
the 2!
4 !
same,
is
is
ways
12
2!
No
The
of
number
of
arranging
the
2 1 two
➔
the
4 3 2 1
number
of
permutations
of
n
objects,
k
of
which
objects.
questions
will
be
are
asked
n!
identical
identical
in
your
exam
is: about
permutations
of
k !
identical
Alma
three
decides
arrange
or naments
choose
ways
to
her
so
Alma
first
there
to
choose
or nament
are
changes
only
3
her
×
2
=
mind
two
from
in
6
3
(snowman,
ways
and
different
again
or naments.
dierent
and
bell
her
and
second
She
angel).
has
She
or nament
can
in
2
arrangements.
decides
to
arrange
two
of
the The
objects:
snowman,
bell,
angel
and
candle.
Now
she
has
to
choose
from.
She
can
choose
her
first
candle
is
one
four distinct of
objects
objects.
or nament
in
the
four
distinct
four objects.
4 !
ways
and
her
second
in
three
4
giving
×
3 =
= (4
12
different
2) !
arrangements.
Using
and
the
same
wanted
to
reasoning
arrange
4
if
she
had n
or naments
different
in
a
line,
or naments
she
could
do
this
in
n !
n
×
(n
−
1)
×
(n
−
2)
×
(n
−
3)
=
ways.
n
➔
The
number
of
4
permutations
!
of
r
objects
out
of
n
distinct
n ! n
objects
P
is
r
n
The
number
of
ways
r
of
!
arranging
n
objects
in
a
row
is
simply
the We
numbers
of
permutations
n !
of
n
objects
out
of
n.
The
formula
is
dene
0!
as
1.
then
n !
n
P
n !
n
n
Alma
n
!
0 !
chooses
6
different
napkins
out
of
the
10
patterns
that
she
has.
⎛ n ⎞ n
If
she
wanted
to
arrange
6
napkins
out
of
10
in
a
line
she
could
do
it
⎜
⎟
and
C
are
two
r
⎝
r
⎠
10 !
in
ways,
10
6
but
this
includes
the
6!
ways
of
arranging
the
6
different
notations
combinations.
napkins
in
a
line.
Now
the
order
is
not
impor tant,
so
she
equivalent
arrangements
by
dividing
by
Both
excludes are
the
for
!
equally
correct
6! ⎛ n ⎞
but
10 !
So
Alma
has
ways
(10
6
of
choosing
the
six
napkins.
⎜
⎝
⎟
r
is
)! 6! throughout
When
the
order
combinations
34
Mathematics
of
and
as
used
⎠
arrangements
you
the
can
science
is
not
generalize
of
patterns
relevant
the
result.
they
are
called
this
book.
➔
The
number
of
ways
of
choosing
(order
is
not
impor tant)
n
r
objects
from
n
is
p n
C
r
= r
⎛ n ⎞
r
n !
p
n
⎜ ⎝
Y ou
⎟
r
is
a
r
= r
(n
⎠
can
letters
the
= C
also
from
same
think
A,
as
B,
BA.
different
r
)! r
of
C,
!
combinations
you
can
However,
arrangement
have
you
as
a
three
could
selection.
different
arrange
(permutation)
to
To
select
selections
them
in
six
two
as
AB
ways
as
is
AB
BA.
Note
Having
chosen
her
number
of
six
different
napkins
Alma
would
now
like
to
are
out
the
ways
of
arranging
them
round
the
table.
that
we
find interested
arrangements
realizes
that
the
number
of
ways
is
no
longer
6!
because
they
are
arranged
in
a
they
two
are
arrangements
in
However,
a
straight
arranged
arrangement
is
relative
are
round
just
different
other .
because
line.
a
rotated
table
by
the
one
same
Another
place.
way
reasoning
to
x
Then
of
the
fact
you
without
could
rotate
repeating
an
arrangement
positions.
So
the
six
number
times
of
round
distinct
the
you
ways
in
of
nishing
6!
arranging
6
distinct
objects
in
a
circle
will
be
of
can
the
number
of
ways
of
arranging n
is
(n
–
Example
a
In
b
In
at
objects
around
1)!
5
on
think
the
napkins
with
rst
each
either
end
side
napkin.
number
of
ways
a arranging
objects
in
a
5
distinct
line
is
5!
how
many
ways
can
the
letters
of
the
how
many
ways
can
the
letters
be
arranged
a
line
the
The
distinct
of
circle
a
be
napkin.
5! 6
Hence
would
arranging
table
of
rst
remaining
In
to
circle. each
These
of
to napkins
be
in
She
word
special
taking
be
arranged?
them
two
time?
Answer
a
There
can
be
are
7
different
arranged
in
7!
letters
in
the
word
special
which
ways.
b
Chapter
1
35
Example
How
many
four-digit
a
1,
2,
3
and
4
b
0,
1,
2
and
3?
Digits
may
be
used
numbers
more
than
can
be
made
using
the
digits
once.
Answers
There
a
are
choosing
giving
a
four
ways
each
total
of
of
the
Since
four
digits
we
distinct
of
more
are
only
concer ned
numbers,
than
digits
can
with
be
used
once.
4
4
=
256
There
b
are
choosing
there
are
3
a
of
digit
ways
each
giving
ways
first
four
choosing
digits
only
the
of
four-digit
with
number
cannot
star t
zero.
of
the
total
A
but
other
of
3
3
×
4
=
Example
In
8
a
Model
boys.
from
In
the
a
there
b
the
c
at
192
United
how
15
many
students
are
no
ways
three
is
of
(MUN)
can
a
club
at
school
delegation
of
10
there
are
students
7
be
girls
and
chosen
if:
gender
delegation
least
Nations
to
restrictions
be
each
made
gender
up
of
are
5
boys
included
and
in
5
girls
the
delegation?
Answers
⎛ 15 ⎞ a
⎜
⎝
⎟
10
Calculate
15!
=
=
⎠
combination,
the
order
of
impor tant.
Now ⎛ 7 ⎞ b
⎜
⎝
⎠
⎜
⎝
⎟ 5
=
The
out
number
⎛ 7 ⎞
⎜
It
is
2
⎠
⎝
1
⎝
36
only
of
having
two
girls
a
is:
choose
5
girls
of
8
a
7
and
5
boys
out
of
8.
GDC.
Cannot
0,
1
or
have
2
a
girls
other
delegation
OR
possible
0,
1,
2
with
boys.
delegations
21 allowed.
⎠
to
have
no
girls
or
are
only
7
girls
combinations
three
will
all
include
boys.
Subtract
the
unwanted
combinations
⎞
⎟ 10
to
GDC.
girl.
least
15
ways
All
=
⎟
there
possible
⎜
⎜
impossible
Since
⎛
of
with
⎛ 8 ⎞ ×
⎟
only
at
need
a
not
⎠
delegation
⎝
Use
is
1176
Use
c
we
choosing
⎛ 8 ⎞ ×
⎟ 5
as
3003
10!× 5!
21
=
3003
−
21
=
number ⎠
Mathematics
as
the
science
from
2982
of
patterns
of
ways.
the
total
are
Exercise
1
2
To
1K
open
your
three
distinct
How
many
Three
three
In
a
In
b
many
how
many
same
par t
times
r un.
a
of
A
In
If
of
a
ways
be
are
on
in
a
the
code
consisting
of
lock.
there?
books,
placed
ways
how
can
on
the
are
students
There
many
he
two
a
geography
books
and
bookshelf.
books
be
be
arranged
on
arranged
so
that
books
of
together?
to
ways
can
up
is
are
to
8
to
can
a
his
team
team
be
routes
next
12
be
least
a
10
along
to
r un
a
km
route
which
he
different
four
can
set
of
race.
Mark’s
selected
at
r uns
manage
boys and
include
a
just
before
be
Mark
different
will
there
ways
many
for
next
a
girls
race?
mathematics
to
choose
from.
chosen?
one
girl
and
one
boy ,
in
how
selected?
QUESTION
many
2,
books
training
eight
leading
is
1,
the
grouped
are
that
team
How
can
are
There
the
0,
to
punch
letters
codes
cross-countr y
week
4
EXAM-STYLE
5
26
science
different
weeks
competition.
b
must
different.
calculates
each
team
a
are
locker
are
you
QUESTION
his
How many
4
There
four
subject
week.
He
routes
all
locker,
shelf ?
EXAM-STYLE
As
books
are
how
the
3
books,
histor y
the
letters.
different
maths
The books
school
3,
4,
four-digit
5
and
even
numbers
can
be
made
using
the
digits
6?
b
How
many
of
these
four-digit
even
numbers
are
divisible
c
How
many
of
these
four-digit
even
numbers
have
no
by
5?
repeated
digits?
6
In
the
UK
contained
How
between
three
many
1932
letters
different
of
and
the
number
1945
car
alphabet
plates
in
registration
followed
this
by
format
numbers
three
were
digits.
possible?
Chapter
1
37
.
The
Repeated
binomial
algebraic
theorem
multiplication
gives These
are
called
0
(1
+
x)
=
1
binomial
expansions
=
1
+
x
because
the
=
1
+
2x
1
(1
+
x)
(1
+
x)
2
2
+
(1
+
x)
(1
+
x)
(1
+
x)
two
x
3
2
3
=
1
+
3x
+
3x
=
1
+
4x
+
6x
=
1
+
5x
+
10x
4
●
these
The
●
expressions
of
common
The
x
+
4x
3
highest
x
for
form
an
difference
index
of
x
4
10x
powers
+
●
of
(1
+
+ x)
arithmetic
you
can
sequence
see
of
with
first
term
0
the
same
as
the
power
to
which
(1
+ x) triangular
first
and
last
term
are
always
1.
is
of
called
T riangle
If
you
write
all
the
coefficients
like
this
you
will
recognize
a
numbers
Pascal’ s
after
the
number French
of
a
1.
is
the
as
that:
pattern
coefficients
terms
known
x
raised.
The
is
5
5x
This
is
x)
x
3
+
algebraic
+
of
binomial.
4
+
2
indices
and
+
2
5
In
(1
sum
mathematician
patter ns. Blaise
Pascal
(1623–62).
actually
row
0:
was
1
as
early
11th
row
It
recorded
2:
1
2
as
the
centur y
by
the
1
Persians
and
the
Chinese.
row
4:
There
1
is
a
obtained
can
4
ver tical
by
extend
Looking
adding
this
at
line
the
6
of
the
patter n
symmetr y .
two
by
numbers,
4
Each
numbers
counting
the
two
above
or
1’s
as
combinations:
in
⎝
In
fact
the
first
and
last
0
be
written
⎝
number,
which
which
(1
+
x)
is
is
0
⎟
⎜
⎠
⎝
the
at
the
= ⎜
⎠
⎝
same
⎟ n
the
second
side.
is
Y ou
row
can
be
of
1
⎟ 1
all
⎠
the
rows
as
where
n
is
the
row
⎠
the
power
to
raised.
second
row
2
2
1!(2
so
either
row
technology .
first
and
2!
Looking
a
⎛ n ⎞ and
as ⎜
1
⎟
coefficients
⎛ n ⎞ can
the
to
in
⎛ 1⎞ =
⎜
it
using
⎛ 1 ⎞ written
number
1
row
is
1) !
1
[
actually
This
illustration
book
⎛ 2 ⎞
⎛ 2 ⎞
⎝
0
⎟
⎜
⎠
⎝
1
⎟
⎜
⎠
⎝
written
is
from
a
Shih-Chieh.
China
in
It
1303,
more
than
300
years
before
⎠
in
Mathematics
in
⎟
2
Pascal.
38
Chu
⎛ 2 ⎞ was
⎜
by
as
the
science
of
patterns
It
shows
Chinese
the
triangle
numerals.
As
each
number
immediately
⎛ 2 ⎞
3 =
⎜
⎝
obtained
above
it,
then
by
in
adding
the
the
third
two
numbers
row
⎛ 2 ⎞
+
⎟
0
is
⎜
⎠
⎝
⎟
1
⎠
2!
2!
=
+ 0 !( 2 − 0 ) !
1!( 2 − 1) !
2!
2!
=
Remember ,
we
dene
+ 0 ! 2
×
( 2 − 1) !
2!
1
⎡ 1
×
0 !( 2 − 1) !
0!
as
1
1⎤
=
+ ⎢ 0 !( 2
1) !
3
⎥ 2
⎣
1
⎦
2!
×
= 1
0 ! 2
×
( 2 − 1) !
×
⎛ 2⎞ Show
that
3!
⎝
= 1!(3
that
⎜
⎝
To
can
⎠
2
2
0
3
1
3
2
⎝
0
⎠
the
be
third
row
written
of
Pascal’ s
triangle
as
⎛ 3 ⎞
⎛ 3 ⎞
⎛ 3 ⎞
⎜
⎟
⎜
⎟
⎜
⎟
⎜
⎠
⎝
⎠
⎝
⎠
⎝
0
1
2
⎟ 3
⎠
3
x
1
leads
⎛ n ⎞
x )
to
a
2
3 3
x
3
x
conjecture
⎛ n ⎞
⎝
0
⎛ n ⎞ x
+
= ⎜
for
the
binomial
theorem
which
⎟
⎜
⎠
⎝
1
⎛ n ⎞
2
x
+
⎟
⎜
⎠
⎝
2
+
x
⎟
⎜
⎠
⎝
r
Coefcient
⎛ n ⎞
r
+
...
+
...
+
formal
proof
of
the
binomial
⎟
⎜
⎠
⎝
theorem
is
of
general
n
x ⎛ n ⎞
⎟ n
term
⎠
is
⎜
⎝
A
and
⎟ 2
that
n
(1 +
patter n
states
⎜
⎠
x
2
This
2
2
x
3
x )
⎝
2
(1
⎠
⎟
⎛ 3 ⎞
⎝
2
x )
1
⎜
⎟
1
summarise
(1
⎛ 3 ⎞ =
⎟
1) !
⎛ 3⎞
=
⎛ 2⎞ +
⎜
beyond
the
scope
of
⎟
r
⎠
this
course.
n
(1
+
x)
When
=
(1
you
degree
n.
+
x)
×
(1
multiply
Y ou
considering
can
+
x)
these
work
different
×
n
(1
+
x)
factors
out
how
powers
of
. . .
you
to
(1
+
get
obtain
x)
a
polynomial
the
of
expansion
by
x:
Number
of
ways
of
⎛ n ⎞ n
0
x
:
multiplying
all
the
1’s
⇒
C
= 0
choosing
⎜
0
x ’s
out
of
⎟ 0 n
factors.
1
x
:
choose
one
x
from
the
n factors
(1
+
x)
and
multiply
it
by
the
1’s
⎛ n ⎞ n
in
all
the
other
factors
⇒ C
x 1
=
⎜
⎟
x
1
Chapter
1
39
2
x
:
choose
two
x’s
from
the
n
factors
and
multiply
them
together
⎛ n ⎞ n
and
by
the
1’s
in
all
the
factors ⇒ C
other
2
2
=
x 2
⎜ ⎝
⎟ 2
x
⎠
r
:
x
choose
r
of
and
the
the
x’s
from
the
n
factors,
multiply
them
together
⎛ n ⎞ n
by
1’s
in
all
the
other
factors
r
⇒ C
r
x
=
⎜
r
⎟
x
r
n
For
the
expansion
of
(a
+
x)
you
n
⎛
x )
=
x
⎛
n
(a +
a
⎜
a
⎝
x
⎛
n
=
⎟ ⎟
⎜
⎝
deduce
a
⎛ n ⎞
like
this:
⎞
⎜
⎠ ⎠
⎟ a
⎝
⎛ n ⎞
x
result
1 +
⎠
r
2
⎛ ⎛ n ⎞
the
n
⎞ ⎞
1 +
can
⎛ n ⎞
x
n
n
⎛ n ⎞
x
a
Distributing
⎞
x
over
the
n
=
a
⎜ ⎜
⎝ ⎝
+
⎟
0
⎜
⎠
⎝
+
⎟
1
⎜
a
⎠
⎝
⎟
2
...
+
+
⎜
2
a
⎠
⎝
+
⎟
r
...
+
⎜
r
a
⎠
⎝
⎟
n
n
⎟ expansion.
a
⎠
⎠
x
⎛ n ⎞
⎛ n ⎞
⎛ n ⎞
n
=
⎜
⎝
⎟
0
➔
a
+
⎠
⎜
⎝
The
⎟
1
a
n −2
x
+
⎜
⎠
⎝
binomial
2
n
0
...
+
+
⎜ ⎝
states
n
⎟
r
1
a
r
x
+
...
⎝
⎟
n
x
in
x the
expansion
above.
⎠
n n2
x
⎜
⎠
n a
+
for a
n
that:
n 1
a
n −r
⎠
n
x )
2
x
theorem
n
(a
a
⎟
Substituting
⎛ n ⎞
⎛ n ⎞
n −1
2
a
n
2
x
n r
...
r
a
r
x
n
...
n
x
n
⎛ n ⎞ n
=
∑⎜
⎟
r
a
r
x
r r =0
Example
Find
the
values
of
a,
b
+
ax
and
8
a
(1
+
2x)
c
in
these
2
≡
1
+
bx
3
+
cx
Use
identities.
8
+
a
…
+
x
⎛
⎞
= 1 + bx 2
⎝
+ cx
theorem
256x
–
⎜
⎠
⎝
ax)
to
write
down
b
–
64x
+
Then
⎞
⎟ 2
simplify
cx
and
compare
⎠
coefcients.
2
=
expansion.
+ ... +
⎟
6
(2
c
x
⎛
2
1 + ⎜
binomial
10
the
b
the
+
…
Answers
⎛ 8 ⎞
⎛ 8 ⎞
⎛ 8 ⎞
⎛ 8 ⎞
8
a
(1 + 2 x )
⎛ 8⎞
2
=
+
(2 x ) +
(2 x )
3
+
(2 x )
8
+ ... +
⎜
⎟
⎜
⎟
⎜
⎟
⎜
⎟
⎜
⎟
⎜
⎟
⎜
⎟
⎜
⎟
⎜
⎠
⎝
⎠
⎝
⎠
⎝
⎠
⎝
⎝
0
1
8!
2
8!
3
×
2x
1! 7 !
+
×
4x
+ 112 x
(2 x )
⎟ ⎠
3
+
2! 6!
8
× 8x
+ ... + 256 x
3! 5!
2
1 + 16 x
⎟
8
8! 2
1 +
⎜
3
+ 44 8 x
8
+ ... + 256 x
∴
∴ a
= 16,
b
= 112
and
c
=
448
{
40
Mathematics
as
the
science
of
patterns
Continued
on
next
page
means
‘therefore’.
a
x
⎛ b
10
⎞
= 1 + bx 2
⎝
+ cx
⎜
⎠
⎝
a
=
⎞
+ ... +
⎟
⇒
x
⎛
2
1 + ⎜
⎟ 2
⎠
10
10
x
⎛
2
⎛ 10 ⎞
⎞
1 +
= 1 +
⎜
⎟ 2
⎝
⎜
⎟
⎜
⎠
⎟
1
⎝
⎠
x
⎛
⎛ 10 ⎞
⎞
+ ⎜
⎜
⎟ 2
⎝
⎟
⎜
⎠
⎟
2
⎝
⎠
x
⎛
10
x
⎛
⎞
⎞
+ ... . + ⎜ 2
⎝
⎟
⎜
⎠
⎝
⎟ 2
⎠
2
10 !
x
⎛
10 !
⎞
= 1 +
⎛
x
10
⎞
⎛
1! 9 !
⎟ 2
⎝
x
⎞
+ ... +
+ ⎜
⎜ 2 ! 8!
⎠
⎝
⎟ 2
⎜
⎠
⎝
⎟ 2
⎠
10
45
⎛
2
= 1 + 5x
+
x
x
⎞
+ ... + ⎜
4
⎝
⎟ 2
⎠
45
∴
a
=
10,
b
=
5
and
c
= 4
n
⎛ 6 ⎞ 6
c
(2
−
⎛ 6 ⎞
6
ax )
=
5
2
+
⎜ ⎝
2
⎟ 1
− ax
(
+
)
⎜
⎠
⎟ 2
⎝
2
(a
2
4
×
×
(
− ax
+
)
−
b)
n
=
(a
+
(−
b))
...
⎠
2
=
64
+
6
×
32
×
(–ax)
+
2
=
∴
b
=
192a
64
–
192ax
+
240a
15
×
16
(–
ax)
+
…
2
x
+
…
64
= 64
1
⇒ a
= 3
240
80
2
c
= 240 a
=
=
9
Example
3
5
Use
the
binomial
theorem
to
expand
(a
+
3x)
.
5
Hence
find
the
value
of
(1.03)
correct
to
5
decimal
places.
Answer
5
(a
+
3x)
5
=
a
4
+
5a
3
(3x)
2
+
10a
a
10a
+
5a(3x)
4
+
15a
3
x
+
90a
4
+
405ax
+
(1
+
2
2
x
+
270a
3(10
1
+
15
×
5
(10
+
270
×
(10
+
243
×
(10
+
≈
+
0.15
+
(5
90
×
(10
2
)
Substituting
–2
+
405
×
(10
a
4
)
=
1,
2
x
=
0.01
=
10
5
)
0.009
0.000 004 05
1.159 27
+
3
)
–2
1
–2
)
–2
=
3
x
))
–2
=
(3x)
243x
–2
=
5
+
5
5
(1.03)
2
(3x)
4
(3x)
5
=
+
3
dp)
+
+
0.000 27
…
Only
ter ms
consider
to
cor rect
give
to
5
the
the
first
4
answer
decimal
places.
Chapter
1
41
Example
Find
the
term
that
is
independent
of
x
in
the
expansion
9
1
⎛
⎞
2
3x
of
⎜
⎟ 2x
⎝
⎠
Answer
The
general
term,
T
of
the
r
expansion
is
given
by:
r
⎛ 9 ⎞
9
r
2
T
=
r
⎜
(3 x
⎟ r
⎝
)
1
⎛
⎞
⎜
⎟ 2x
⎝
⎠
⎠
r
⎛ 9 ⎞ =
⎜
⎝
⎟ r
9 −r
×
x
=
3r
r
⎠
0
x
–
x
⎟ 2
⎝
r
18
× ⎜
×
−r
×
⎠
18–2r
x
1 ⎞
⎛
18 − 2 r
3
x
=
0
=
6
For
ter m
must
be
independent
of
x,
index
of
x
0.
6
⎛ 9 ⎞ 3
T
=
6
⎜
⎝
×
⎟ 6
3
2
2
n
Write
Give
answer
as
an
exact
fraction.
16
⎠
that
r
567
1L
n
⎟
⎝
Show
a
1 ⎞
⎜
=
⎠
Exercise
1
⎛
×
⎛ n
b
n
r
down
the
+ 1⎞
⎜
⎛ n ⎞ =
⎟
⎜
r
first
four
terms
in
⎟ r
binomial
⎞
⎜
r
the
n
⎛ +
⎟
− 1
expansion
of:
9
x
⎛ 11
a
(1
+
7
2x)
(1
b
–
(2
c
+
5x)
2 −
d
⎜ ⎝
3
Write
down
the
required
term
in
each
of
these
binomial
expansions.
20
x
⎛
⎞
7
a
4th
term
of
(1
–
4x)
3rd
b
term
of
1− ⎜
⎟ 2
⎝
⎠
8
c
4th
term
EXAM-STYLE
of
(2a
–
b)
QUESTION
12
1
⎛ 4
Find
the
term
independent
of
x
in
the
expansion
of
2x
⎞
+
⎜
2
⎟
x
5
x
⎛ 5
Use
the
binomial
theorem
to
expand
⎞
.
2 + ⎜
Hence
find
the
⎟ 5
⎝
⎠
5
value
of
(2.01)
correct
to
5
decimal
places.
4
6
a
Express
(
2
3
)
in
the
form
a +b
where
6
a,
b
∈
3
1
⎛ b
Express
2
⎞
+
⎜
in
⎟ 5
⎝
the
42
Express
Mathematics
1+
(
as
7
the
)
form
a
2 +b
5
where
a,
b
∈
⎠
5
c
5
−
1 −
(
science
of
7
)
⎞
5
3x)
in
the
patterns
form
a
7,
where
a
∈
⎟ 3
⎠
7
Let
a
=
x
+
y
and
2
Write
a
2
b
=
x
−
y
2
a
−
b
in
terms
of
x
and
y
and
hence
b
=
(a
−
b)
(a
+
x
the
and
3
y
binomial
and
use
theorem
your
3
−
a
to
results
2
b
=
(a
−
b)
write
to
3
a
and
show
b
in
the
(a
binomial
y
and
d
Use
your
e
Prove
use
of
that
+
ab
+
b
)
expansion
to
4
write a
and
b
4
and
terms
2
4
Use
c
that
b)
3
Use
b
show
2
−
a
your
results
to
factorize
a
in
terms
of
x
4
−
b
n
results
your
Review
to
make
conjecture
a
conjecture
using
for
the
mathematical
factors
of
a
n
−
b
induction.
exercise
✗ 1
2
Show
term
is
Find
the
1
3
that
+
3
16
+
Three
there
and
sum
4
+
6
are
the
of
+
The numbers
+
a,
c,
sum
the
7
numbers
two
a
b
geometric
of
the
first
sequences
three
such
terms
is
that
the
second
84.
series.
9
+
10
and
and
b
c
+
12
form
form
+
an
a
…
+
46
arithmetic
geometric
sequence.
sequence.
9
If the
sum
of
the
numbers
is
,
find
the
three
numbers.
2
4
Write
down
⎧u ⎪ 1
the
first
six
terms
of
the
sequence
given
by:
= 1
⎨ +
u ⎪ n +1 ⎩
=
2u
+ 1 ,
n ∈
n
n
Use
mathematical
induction
to
prove
that u
=
2
–
1.
n
2n
5
Prove
by
multiple
6
Write
mathematical
of
in
induction
that
3
+
–
8n
–
1,
n
∈
,
is
a
64.
factorial
notation:
4
a
the
coefficient
of
x
b
the
coefficient
of
x
n+1
in
the
expansion
of
(1
+
x)
in
the
expansion
of
(1
+
x)
2
n–1
4
Find
c
n
given
that
the
coefficient
of
x
in
n+1
(1
+
the
expansion
of
2
x)
is
six
times
the
coefficient
of
x
in
the
expansion
n–1
of
7
(1
+
Evaluate
x)
these
by
choosing
an
appropriate
value
n
for
x
in
the
⎛ n ⎞
a
⎜
⎝
⎟
0
⎠
expansion
⎛ n ⎞ +
⎜
⎝
⎟
1
⎛ n ⎞
⎜
⎟
⎜
⎠
⎝
(1
⎛ n ⎞ +
⎠
⎛ n ⎞
of
⎜
⎝
⎟
2
+
x)
⎛ n ⎞ +
...
+
⎠
⎜
⎝
⎟
r
⎛ n ⎞ +
...
+
⎠
⎜
⎝
⎛ n ⎞
⎟
n
⎠
⎛ n ⎞
n
n
b
⎝
0
⎟
1
⎠
+
⎜
⎝
⎟
2
⎠
−
...
+
( −1)
⎜
⎝
⎟
r
⎠
+
...
+
(
−1)
⎛ n ⎞
⎜
⎝
⎟
n
⎠
Chapter
1
43
Review
exercise
EXAM-STYLE
1
The
QUESTION
diagram
shows
largest
square,
square
of
a
If
the
the
spiral
lines
b
in
of
is
Use
of
midpoints
the
the
This
largest
second,
formed
the
sequence
sequence.
sides
lengths
A
the
a
by
of
are
squares.
joined
process
square
third
joining
and
to
can
have
form
be
with
the
1,
the
second
continued
length
four th
segments
Star ting
infinitely .
calculate
the
squares.
shown
as
red
diagram.
your
answers
to
par t
to
a
find
the
length
of
the
spiral
shown.
c
What
happens
process
A
to
the
length
of
the
spiral
if
we
continue
the
infinitely?
different
spiral
is
formed
by
shading
triangles
as
shown
in
the
diagram.
d
Find
e
What
of
the
is
total
the
forming
area
total
of
the
area
squares
of
and
shaded
the
triangles.
spiral
shading
formed
triangles
if
is
the
process
continued
infinitely?
2
a
In
how
many
characteristic
b
How
5
c
many
can
Four
be
person
In
how
from
and
formed
is
next
many
six
one
men
using
ways
to
ways
and
female
bigger
couples
different
ways
can
the
letters
of
the
word
arranged?
numbers
married
many
3
different
be
his
can
four
and
the
are
can
or
a
than
digits
to
be
they
her
20 000
0,
in
3,
divisible
5,
and
group
in
a
7
9?
photo.
line
so
by
In
that
how
each
spouse?
women,
are
a
stand
committee
there
1,
and
so
of
that
more
five
people
there
women
is
at
than
be
selected
least
men
one
on
male
the
committee?
4
Write
down
and
simplify
the
term
independent
of
x
in
the
8
3
expansion
3
of
x
EXAM-STYLE
x
QUESTION
r–1
5
Given
that
the
coefficients
of
x
r
,
x
r+1
,
x
in
the
expansion
n
of
(1
+
x)
2
n
are
in
arithmetic
sequence,
show
that
2
+
4r
–
Hence find
2
–
n(4r
three
+
1)
=
0
consecutive
coefficients
of
the
14
(1
44
+
x)
which
form
an
arithmetic
sequence.
expansion
of
CHAPTER
1
SUMMARY
Sequences
●
An
and
arithmetic
series
sequence,
or
arithmetic
progression,
with
the
first
term u 1
and
common
,
u
u
1
and
+
d,
difference
u
1
the
+
2d,
d
…
is
,
u
1
+
general
term
is
=
u
u
n
●
The
sum
of
n
=
terms
[ 2u
of
a
+ (n
− 1) d
1
n
1)d
+
(n
–
1)d
finite
arithmetic
series
is
n
n
where
–
1
n
S
(n
1
is
the
number
=
]
[u
+
u
1
of
]
n
terms
in
the
series, u
is
the
first
with
first
1
term
●
A
and
d
is
geometric
the
common
sequence
or
difference
geometric
progression
term u 1
and
common
ratio
2
,
u
u
1
r,
u
1
r
r
is
3
,
u
1
r
4
,
u
1
r
,
...
1
n–1
and
the
general
term
is
=
u
u
n
×
r
,
r
≠
–1,
0,
1
1 n
(1 − r
u
)
1
●
The
sum
of
n
terms
of
a
geometric
series
is
S
,
=
r
≠
1
n
(1
r ) u 1
●
When
–1
0 there
are
ii
Ιf
Δ
=
0
there
is
iii
Ιf
Δ
0
and
x 4
2
y
=
e
+ 1.
Find
the
area
of
the
shaded
region.
2
8 6
Consider
the
cur ves
y
x
=
and
y
=
.
2
4
a
Find
the
b
Write
down
enclosed
c
points
by
Calculate
the
the
the
of
+
4
x
intersection.
integral
that
represents
the
area
of
the
region
cur ves.
area
of
the
region.
Chapter
9
485
The
volume
V
of
a
solid
formed
by
a
cur ve
y
=
f
(x),
between
Y ou
x
=
a
and
x
=
b
rotated
2
through
radians
about
the
in
isgiven
met
this
formula
x-axis Section
7.
by
b
2
V
=
y
dx
a
Example
Find
the
y
sin
volume
of
a
solid
obtained
by
rotating
the
cur ve
y
x ,
0
x
through
2π
radians
about
the
x-axis. 2
1
Answer
b
π
2
sin x
π
=
Use
dx
the
for mula
V
=
y
x
0
2
V
1
dx
2
3
4
–1
a
0
–2
π
π
=
sin x dx
cos x
0
Simplify. 0
3
π (– cos π
=
The
volume
–
cos 0)
of
a
=
solid
2π
units
formed
Evaluate.
by
rotating
a
cur ve, y
=
f (x),
b
2
2π
through
radians
about
the
y-axis
is
given
by
V
=
π
x
dy.
a
1
To
use
this
Example
Find
y
=
the
formula
you
must
first
find x
=
f
(y).
volume
arccos
directly
x,
0
of
≤
x
a
≤
solid
1
that
through
is
obtained
2π
radians
by
rotating
about
the
the
cur ve
y-axis.
Answer
y
=
y
arccos x,
0
≤
x
≤
0
≤
y
≤
1
Express
x
in
ter ms
find
domain
of
y
r
and
2
⇒
x
=
cos y,
the
of
y
values.
2
1 2
V
=
π
(cos y)
dy
Use
the
volume
Use
the
half
for mula.
0
π
1
=
cos 2 y
π
dy
2
0
p
⎡ y
sin 2 y ⎤
= p ⎢
⎥
⎣ 2
4
⎦
0
2
⎛ p
= p
486
The
sin 2p
⎜ ⎝
x
0
2
⎞ ⎟
2
power
4
of
⎠
⎜
p
sin 0 ⎞
⎛
−
0 −
⎝
calculus
⎟ 4
⎠
3
=
units 2
Evaluate.
angle
for mula.
1
Y ou
can
subtract
Example
Find
the
volumes
of
two
of
that
different
cur ves.
volume
a
solid
is
obtained
by
rotating
the
finite
region
x
enclosed
by
the
cur ves
y
=
ln x
+
1
and
y
2π
through
tan
radians
2
about
the
x-axis.
Answer
y
Sketch
the
graph
to
identify
the
finite
3 x y
=
region
and
the
points
of
intersection.
tan 2
2
x y
=lnx
+1
The
1
equation
ln
x
=
tan
cannot
be
2
solved
algebraically
so
use
a
GDC.
x
0 1
2
3
x
Solve
the
equation
ln
x
=
tan
and 2
store
b.
the
Apply
rotating
solutions
the
as
for mula
region
the
for
between
variables
the
two
a
volume
and
of
cur ves.
3
Vol.
=
3.58
Exercise
1
Find
by
9X
the
the
units
volume
given
of
a
cur ves
solid
generated
through
2π
by
radians
rotating
about
the
the
region
bounded
x-axis.
a
y
cos x ,
x
0,
x
,
y
y
0
,
y
0
2
b
y
sec x ,
x
0,
x
, 4
c
y
cos x ,
x
5
,
x
6
d
y
sin x ,
x
Find
the
volume
by
the
given
a
y
=
arcsin x,
x
,
b
y
=
arcsin x,
of
=
y
0
3
cur ves
x
0
2
, 3
2
6
a
solid
generated
through
0,
x
=
0,
0,
x
y
x
=
=
2π
by
radians
rotating
about
the
the
region
bounded
y-axis.
1
1,
y
=
0
c
y
tan x ,
x
,
y
0
4
d
y
=
tan x,
x
=
0,
y
=
1
Chapter
9
487
3
Find
by
the
the
volume
of
a
solid
generated
rotating
the
region
enclosed
cur ves
y
a
by
sin x ,
y
5
cos x ,
x
through
4
2π
radians
about
the
4
x-axis.
y
b
=
sin 2x,
y
=
sin x,
0
≤
x
≤
π
2π
through
radians
about
the
x-axis.
x
3
y
c
= e
− 1
and
y
through
= arctan x
2π
radians
about
the
x-axis.
See
the x
3
y
d
= e
− 1
and
y
Investigation
F ind
by
the
volume
rotating
a
of
a
circle
through
= arctan x
–
volume
tor us
with
that
the
is
of
2π
a
radians
about
the
torus
y-axis.
y
obtained
centre
at
(h,
k) r
and
a
r,
radius
k,
r
>
0
Look
and
back
chapter
k
at
>
r,
about
x
the
(h
axis.
k)
the
introduction x 0
on
Exercise
1
Use
page
441.
9Y
volume
of
revolution
to
find
the
volume
2
by
rotating
about
2
Use
the
the
circle
(x
−
4)
(y
+
3)
volume
rotating
about
3
Use
the
of
the
revolution
to
find
the
4
Find
the
2
5
Find
circle
of
(x
−
4)
revolution
6
rotating
=
the
36
+
−
The
the
of
a
+
to
(y
find
circle
solid
through
volume
9y
=
the
36
of
a
2π
solid
x)
power
through
volume
2
488
obtained
radians
volume
of
a
tor us
obtained
+
3)
=
4
through
2π
radians
the
x
volume
of
a
sphere
2
+
y
=
9
through
2π
radians
obtained
by
rotating
the
ellipse
radians
about
obtained
by
the
x-axis.
rotating
the
ellipse
2
Find
(5
2π
x-axis.
volume
9y
2
4x
tor us
2
+
4x
by
the
a
through
2
2
obtained
4
y-axis.
volume
about
=
x-axis.
2
by
of
2
+
of
a
2π
solid
radians
about
obtained
by
the
y-axis.
rotating
the
ellipse
2
+
of
9y
=
36
calculus
through
2π
radians
about
the
x-axis.
further
CD.
questions
on
Review
exercise
✗ 1
Differentiate
a
f
(x)
=
with
(2x
+
3)
respect
to
x:
sinx
x
b
g(x)
c
h
=
e
cos3x
tan x
(x )
= 2
2x
2x
2
Find
the
equation
3
Find
the
value
of
of
m
a
tangent
that
to
satisfies
the
this
cur ve
sin y
+
e
=1
at
the
origin.
equation
m
⎛
2
sec
x dx
=
2
⎜
cos
⎞
− sin
⎟
p
6
⎝
6
⎠
4
4
Use
the
method
of
integration
by
par ts
to
solve:
2x
a
(2x
–
5) e
b
(x
c
e
The
diagonal
dx;
2
–
5x) cosx
dx;
x
cos 3x
dx
–1
5
Find
has
a
the
of
rate
length
of
of
a
square
change
5
is
of
increasing
the
area
at
of
a
the
rate
of
square
0.2
cm
when
s
the
.
side
cm.
2x–1
6
The
a
cur ve
Find
y
the
through
b
Find
the
c
=
e
the
rotating
of
the
tangent
to
the
cur ve
that
passes
origin.
area,
tangent
Find
given.
equation
the
the
is
in
and
the
volume
the
terms
e,
of
the
region
bounded
by
the
cur ve,
y-axis.
of
region
of
the
in
revolution,
par t
b
about
in
terms
the
of
,
obtained
by
x-axis.
2
7
Use
the
8
The
region
x
=
1
substitution
and
a
Sketch
b
Find
this
x
bounded
the
x-axis
the
the
by
is
region
exact
=
3
cos θ
the
cur ve
rotated
in
value
the
of
to
y
=
ln
volume
(2x),
2π
through
coordinate
the
9 −
find
x
dx
the
ver tical
radians
about
line
the
y-axis.
system.
of
revolution
obtained
by
rotation.
2t
3
9
The
velocity ,
v,
of
an
object,
at
a
time
t,
is
given
by
v
= 5e
k
>
,
–1
where
t
is
a
Find
b
What
in
the
is
seconds
distance
the
total
and
v
is
in
travelled
distance
m
in
.
s
the
first k
travelled
by
seconds,
the
object?
2
10
Find
point
the
(1,
equation
of
the
normal
to
the
0.
cur ve x
3
y
=
cos(x)
at
the
–1).
Chapter
9
489
Review
exercise
2
1
Find
the
2
Given
points
of
inflection
of
the
cur ve y
=
find
the
equation
x
sin 2x,
–1
≤
x
≤
1.
3
point
the
cur ve
where
x
=
y
=
cos x,
of
Find
the
value
of
a,
0
5)
Exercise
1
The
2
the
2
b
in
0.5
is
a
a
0.868
ml
of
the
of
modeled
in
25
≤
P(Y
P(Y
+
≤
≤
P(Y
4 )
0 )
=
+
3 )
P(Y
+
=
P(Y
1 )
=
+
P(Y
=
2 )
4 )
4)
of
is
by
a
two
per
millilitre
of
a
given
be
than
liquid
is
3.5
that
there
liquid
of
0.01.
there
flaws
If
Poisson
will
per
flaws
will
100
be
square
occur
variable
chosen
fewer
least
metre
the
2
of
randomly
find
square
at
7
bacteria
bacteria.
fabric
and
probability
metres
of
produced
their
fabric
number
that
there
will
be
flaws
square
one
bacteria
liquid
the
randomly
least
=
(3 sf)
number
machine
a
P(Y
number
ml
exactly
b
–
Use
is
Po(7.5)
=
mean
in
~
1
probability
in
on
Y
the
10H
a
The
by
arriving
=
mean
Find
inter val,
cars
metres
of
chosen
randomly
fabric
there
will
be
at
flaw .
Chapter
10
519
The
3
number
and
If
9:00
the
mean
the
a
the
X
~
number
8:15
in
and
Po
calls
weekday
of
a
given
8:10
a
of
by
modeled
calls
phone
a
by
per
school
a
hour
calls
between
Poisson
is
12,
received
8:00
distribution.
calculate
between
8:00
day
that
in
received
is
phone
number
probability
8:00
4
phone
any
expected
and
b
of
on
more
given
than
five
calls
are
received
between
day .
(3.5)
Calculate
a
P(X
i
Write
b
=
3)
P(X
ii
down
the
values
>
of
3)
P(X
iii
E(X)
and
3)
Var(X)
2
Hence
c
find
EXAM-STYLE
The
5
the
value
of
E(X
).
QUESTION
random
variable
X
is
Poisson
distributed
with
mean
m
and
satisfies
P(X
Find
b
Hence
Let
6
=
a
X
P(X
>
Find
0)
the
be
3)
The
=
Let
p
λ
be
>
1)
m
P(2
–
P(X
correct
≤
X
≤
variable
=
4)
to
=
four
0
decimal
places
4).
with
a
Poisson
distribution,
such
that
3)
QUESTION
variable
P
has
a
Poisson
distribution
with
0.
the
probability
a
Write
down
an
b
Show
that
=
c
Sketch
p
the
that
P
expression
p(λ)
graph
concavities
.
=
0.555
for
0,
u
some
and
scalar
v
have
k
the
same
Geometrically,
direction;
points
if
k