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Title: Trigonometry for maths
Description: Complete notes of trigonometry

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TRIGONOMETRY NOTES

By
STEVEN SY

Copyright 2008

2

Contents

0
...

8

0
...

9

1 Review of Functions

15

1
...
15

1
...
23

1
...
29

1
...
35

1
...
42

1
...
47

1
...
51

1
...
54

1
...
59
3

1
...
62
1
...
67
1
...
73
1
...
75
1
...
78

2 Rational Functions

87

2
...
87

2
...
89

2
...
96

3 Elementary Trigonometry

111

3
...
111

3
...
118

3
...
4

The Wrapping Function At Multiples of
...
5

The Wrapping Function At Multiples of and
...
6

The Trigonometric Functions: Definitions
...
7

Domain and Range of the Trigonometric Functions
...
124

3
...
159

3
...
161

3
...
165

4 Graphing Trigonometric Functions

173

4
...
173

4
...
179

4
...
186

4
...
189

4
...
193

4
...
199

4
...
205

4
...
210

5 Trigonometric Identities

217

5
...
217

5
...
223

5
...
233

5
...
244
5

5
...
248

5
...
252

5
...
257

5
...
262

5
...
266

5
...
270
5
...
274

6 Advanced Trigonometric Concepts

279

6
...
279

6
...
285

6
...
289

6
...
298

6
...
307

6
...
319

6
...
329

6
...
332

6
...
346
6

6
...
355

7 Triangle Trigonometry

363

7
...
363

7
...
375

7
...
387

7
...
391

7
...
398

7
...
403

7
...
415

Selected Answers to the Exercises

421

7

0
...
DO NOT BLINDLY APPLY powers and roots across expressions that have
2
...
As in comment 1,

or

signs
...

The square formula applies:

...
This means when you
square you will have a term that looks like twice the product of the terms in parentheses
...

...
Note that you can
4
...

8

0
...
Formulas
Perfect Square Factoring:
Difference of Squares:

Difference and Sum of Cubes:

B
...
There is no “sum of squares” formula, i
...
no formula for

(over the real numbers)
...
With and in the same equation, you get one equation when you take the “top” signs,
and you get another when you take the “bottom” signs
...

3
...
Then the second factor looks
like you “square” the first factor, except rather than doubling the middle term, you take the
negative of the middle term
...
Examples
Example 1:

Factor

Solution

Now use the Perfect Square Formula (with minus):
Ans

Example 2:

Factor

Solution

Now use the Difference of Squares Formula:
Ans

10

Example 3:

Factor

Solution

Now use the Sum of Cubes Formula:
Ans

Example 4:

Factor

Solution

Now use the Difference of Cubes Formula:
Ans

11

Exercises

1
...
Expand
3
...
Factor
5
...
Factor

7
...

...

...

...

12

13

14

Chapter 1
Review of Functions

1
...
Definition of a Function

Every valid input, , produces exactly one output, ; no more, no less

B
...
Implicit Functions
1
...

2
...

15

C
...

Example 1:

Solution

Plug in some -values, see how many -values you get:

For each , we only get one y, so this a function of
...

Example 2:

Solution

...
So this is not a function of
...

16

Example 3:

Solution

...

For each , we only get one y, so this a function of
...

Note: If we have a graph, we may determine if we have a function of by using the
Vertical
Line Test (if any vertical line hits the graph more than once, it is not a function

of )
...
Notation and Comments

1
...

2
...

input, is the output ( -value)
...
In terms of ,

is a -value
...

18

to spit back

For instance, if 3 is an

E
...
Use formula for the output,

, so

, and plug in
...

21

Example 2:

Find

and simplify

Solution
We wantthe output when the input is

output where you see :
Now

, so

Then simplify:

Ans

...

Example 3:

Simplify the difference quotient

Solution
Now

so

Then

Ans

, if

20

...
Determine if the following equations define functions of ; if so, state whether they are explicit
or implicit
...

b
...

2
...

g
...

d
...
Find and simplify:
a
...

c
...

e
...

Note: This is different than part c
...
Let

a
...

c
...
Find and simplify:

d
...
Find the difference quotient

5
...
Find

and simplify for

and simplify for

and simplify for

...

22

...
2 Domain and Range of Functions

A
...
Range

all outputs

C
...

In particular, we don’t allow division by zero or complex numbers
...
Denominators: Throw away values making the denominator zero
...
Even Roots: Set inside

, and solve inequality
...
Logarithms: Set inside

, and solve inequality
...
Domain Finding Examples
Example 1:

Given

, find

...

Ans

Example 2:

Given

, find

...
Denominator: Throw away
2
...

Throw away

Ans

24

E
...

Methods

1
...
What
is the smallest -value? What is the largest -value? Are any -values missed?
Heuristic: Expressions that are raised to even powers or even roots of expressions have smallest -value equal to 0
...
Graph it, and read off the -values from the graph
...
See if you can apply “HSRV transformations” to a known base graph (reviewed
later in Section 1
...
For a quadratic function, find the vertex
...

5
...

There are other methods, such as the Back Door method, which will not be reviewed
here
...
Range Finding Examples

Example 1:

Given

, find

...

What is the largest -value possible? There is no upper limit!
(The -values go to
...

Ans

Example 2:

Given

, find

...
)

largest -value possible? no upper limit
no values larger than
Ans

are missed

26

Example 3:

Given

, find
...
The parabola opens down since the leading coefficient
is negative
...

Vertex Formula:

largest -value is

Ans

27

!

...
Find

2
...

b
...

for where

a
...

c
...

e
...

3
...
Every polynomial

satisfies

b
...
No quadratic function has
4
...
3 HSRV Transformations

A
...
Horizontal Translation: Add/Subtract Number INSIDE of (Left/Right Respectively)
a
...
-values change

2
...
-values fixed
b
...
Reflections:

sign:

a
...
Inside

-axis reflection, -values fixed, -values times

sign (next to

): -axis reflection, -values fixed, -values times

4
...
-values fixed
b
...

NOTE: When the output formula is not given, we identify “key points” on the graph, and
then move those according to the rules given
...

B
...
Also determine

30

and
...
H: Add 1 inside: move graph left by 1; -values fixed, -values move

2
...
R: Outside

sign:

-axis reflection; -values fixed, -values times

R

4
...
Let be given by the following graph:

a
...
Graph , where

c
...
Graph , where

e
...
Graph , where

33

2
...
Then determine

...
Graph , where
b
...
Suppose is a function with

Find
and , where

and

34

...

and
...

1
...
Symmetry of Functions
1
...

2
...

Note: A nonzero function may not have -axis symmetry
...
Even/Odd Tests
1
...

2
...

To use these tests, we compute and and compare to
...
If none of them are equal, the function is
neither even nor odd
...
For example, if
use generic x, not
When testing,

, then and , but is not even!

C
...

36

Example 2:

Solution

Ans

Since

Example 3:

,

is even
...

D
...

Examples of symmetric domains:

,

,

,

Examples of domains that are not symmetric:

,

,

,

E
...
Statement: Any function (even/odd/neither) with a symmetric domain can be decomposed
into the sum of an even function and an odd function
...
Formulas:
a
...

odd

3
...
Note, by definition,
b
...

odd

38

odd

is an odd function
...
Decomposition Examples
Example 1:

, decompose

Given

into even and odd parts
...

Now use the formulas:

even

odd

Ans

Note:

even

odd

even

odd

...

Given

Solution
Note:

, so the domain is symmetric
...
was already odd
...
To test a function, do the decomposition
...
If the odd part is 0, the function is even
...

40

Exercises
1
...

b
...

d
...

f
...

2
...

3
...

4
...

41

1
...
Definitions of

2
...

5
...

4
...
are functions; whereas,

is called composed with

etc
...

Warning: The above are definitions of new functions, having nothing to do with the “distributive”
property for variables
...
Examples
,

Example 1: Find the output formulas for
where

and

...
Find:

and

Solution
a)

b)

c)

2

43

-6

-8

Let and be given by the graphs below:

Example 3:

Find:
a)

b)

c)

Solution
a)

by graphs
of and
b)

graph
of

c)
d)

=

3

graph
of

-1

44

2

d)

C
...
The domains of
looking at their output formulas!

,

,

,

etc
...
Reason output formula gives the wrong domain:
Example:
If

and
, then

However,
Note that

...

is undefined:

, but and are undefined!

3
...

45

Exercises
,

1
...
Let

3
...

...

and
...

b
...

4
...

b
...

d
...
6 Domain of Combined Functions
A
...
We will

for the next two sections
...

B
...
Find

and

,

,

, and

:

...
Intersect them in AND, i
...
find where they overlap
...
In the

case, additionally throw out any ’s where
(since the denominator can’t be zero)

47

C
...
Find

and

...

Note: By the output formula, you would get the incorrect domain of
Now we’ll do it correctly
...

intersect

Ans

48

Throw away

Throw away

...
Find

and

...

Note: As we’ll see the domain is not
2
...

(root) and

(denominator)

(root) and

(denominator)

intersect

,

Since we have , here we need to also throw out where

i
...

Throw out

Ans

:

...

50

1
...
Introduction
In this section, we will discuss how to find

from output formulas
...
Motivation
Since

, the domain must consist of

1
...
also,

[

[

]

must be accepted by

; this occurs when

is defined

]

C
...
Find

...
Find

...
Intersect
Note:

with

(overlap with AND)
...

D
...

and

Solution

1
...
Now find

,

...
Intersect:

:

from the even root, we require
Thus

was never used!

52

...

Solution
1
...
Now find

We see that

, so

, so

intersect

53

...
Intersect:

1
...
Method

1
...
Draw

from the graph
...

3
...

4
...

B
...
From the graph,

...
Mark

on the -axis of the graph of :

include

Band determined by
Throw away everything outside

include

3
...
Now read off the domain:
Ans

Example 2:

Find

where

and are given by the following graphs:

55

Solution
1
...
Mark

...
“Mutilated” graph of :

4
...
Let

2
...
Let

4
...
Find

and

...
Find

and

and

...

...

...
Let and be given by the following graphs:

a
...
Find
c
...
Find

57

6
...
Find
b
...
Find
d
...
9 Inverses
A
...

2
...

Examples
Are and inverses, where

Example 1:

and
?

Solution
Check the two conditions!

Ans

1
...

YES, and are inverses

59

Are and inverses, where

Example 2:

and
?

Solution
Check the two conditions!
1
...

Both conditions are not met, so
...
Determine if and are inverses where
2
...
Determine if and are inverses where

and

and

61

and

...

...
10 One-to-One Functions
A
...
We might ask the following question:
Does there exist a function , so that and are inverses?

B
...
e
...

Let’s consider

,

for example
...
Notice what does to -3 and 3:
-3
9
3
Since sends both -3 and 3 to 9, if we had a that worked, would have to send 9 back to
-3 AND 3, but functions can’t do that!

Moral: We see that for a function to have an inverse, it can not send two or more ’s to the
same number
...
11)
...

Definition of a One-to-One Function
A function is called one-to-one if it is impossible for different inputs to get sent to the
same output
...

3
4

6

3
6

5

7

5

7
9

8
one-to-one

D
...
Definition: See if it is impossible for different ’s to go to the same
...
Graphical: Horizontal Line Test
(if any horizontal line hits the graph more than once, it is not one-to-one)

not one-to-one
3
...
Set

b
...
If

(only), then

is one-to-one; otherwise, it is not
63

E
...
Set

2
...
Set

:

LCD=

2
...
Set

2
...

2
...

...

...

...

6
...

7
...

8
...

66

1
...

Notation

1
...

2
...

B
...
Verify that is one-to-one
...
Set output

Note:

and solve, if possible, for

67

(the input)
...

Examples of the Algebraic Method

Example 1:

where

Find, if possible, the output formula for

Solution
1
...

2
...

68

Example 2:

Find, if possible, the output formula for

where

Solution
1
...
Let

and solve for :

...

D
...
Thus, if we have the graph of
, and we want to evaluate at a point, we put in the -value and take the corresponding
-value as the answer
...

An Example
Let be given by the following graph:

Evaluate:

a
...

Solution
Note: actually has an inverse, since it passes the Horizontal Line Test

a
...

: when

: when

,

, so

,

, so

70

Exercises

1
...

b
...

d
...

f
...

h
...
If is one-to-one, find the output formula for

71

, where

where

...
Let be given by the following graph:

Evaluate:

a
...

c
...
12 Inverse Functions II: Reflections
A
...

Thus, for

graphical
purposes,
we
can
get
a
“non-sideways”
version
of
the
graph
of
by
switching

the and coordinates
...

Note: When we want to consider this alternate version of the graph of , we indicate that
in our output formula as well
...

formula is
Now let’s see what this means geometrically
...

Graph of the Inverse Function

To get the graph of , we switch the coordinates of each point onthe
graph of
...

73

C
...
If

is on

, then

is on

...
Connecting these two points, we cut the line

3
...
Since the slope
of the line
to the line

...

...
To show that
same distance from as the point
is
...
Distance from

to

:

7
...

74

is the

, so the graph of

is the

1
...

Domain and Range of
1
...
To find

: find

This comes from the idea that

takes -values back to -values
...
The output formula
domain and range
...

will give the wrong

Examples
Example 1:

is invertible and

...

Solution
1
...

Note: The above output formula suggests that
the right answer
...

75

, but this is not

2
...

Thus

3
...

is invertible and

...

: Find

Now

Thus

Hence
2
...

...
Let
2
...
Let

...
Find

,

,

...

...

1
...

Motivation
If is useful, but not invertible (not one-to-one), we create an auxiliary function
similar to , but is invertible
...

that is

Capital Functions

Given , not invertible

, we define

invertible
...

[

2
...

is one-to-one

b
...

produces the same outputs as , so the output formula is the same]

is called a capital function or principal function

Method for Constructing Capital Functions

Given , we try to determine what to cut out of
the same range
...

Examples
Example 1:

...

Solution
To see what is going on, let’s look at the graph of :

Note:

...

Ans

One solution is

Another solution is

Note: Each such solution can be loosely referred to as a “branch”
...
Construct a capital function
...

]

...

Ans

One solution is

Another solution is

80

E
...
By construction, the capital functions are invertible
...
Since

, it retains the useful information from the original function
...
The inverse of the capital function,
of the original function one can get
...

, serves as the best approximation to an inverse

Inverses of the Capital Functions

Here given a function , we examine
Example 1: Let

Also, give

and

...

...

Using the left branch,

;

81

and find

...
In this case,
make smaller than -3
...

...
Using the right branch, determine

Solution
Let’s look at the graph of :

82

and find

...

Using the right branch,

Note 2:

;

and

Now find

:

Then

OR

OR

OR

...
In this case,
,
so
we
need
the
equation
giving
-values

that are 2 or bigger
...

Hence,

...
Let

...

Also, determine

2
...
Let

determine

...

...
Let

Also, determine

...

85

and find

and find

and find

...

...
Also,

and find

...
1 The Reciprocal Function

Let

...

We can plot this by making a table of values
...

undefined

87

undefined

, we pick a lot

For very large numbers
(like ) and very negative numbers (like ), the graph

approaches the -axis, but does not cross
...

These “imaginary” approaching lines are called asymptotes
...

88

or axes, as in this function, we often draw

2
...
Definition of a Rational Function

is said to be a rational function if
, where and are polynomial functions
...

B
...

Asymptote Types:
1
...
horizontal
3
...
curvilinear (asymptote is a curve!)
We will now discuss how to find all of these things
...
Finding Vertical Asymptotes and Holes
Factors in the denominator cause vertical asymptotes and/or holes
...
Factor the denominator (and numerator, if possible)
...
Cancel common factors
...
Denominator factors that cancel completely give rise to holes
...

D
...

Solution
Canceling common factors:

factor cancels completely

vertical asymptote with equation

Find the vertical asymptotes/holes for where

Solution
Factor:

hole at

factor not completely canceled

Example 2:

90

...
Finding Horizontal, Oblique, Curvilinear Asymptotes

Suppose

If
1
...
degree top
3
...
Examples
Example 1:

Find the horizontal, oblique, or curvilinear asymptote for where

Solution
degree top
Ans

degree bottom

horizontal asymptote with equation
91

Since

...

Example 2:

Find the horizontal, oblique, or curvilinear asymptote for where

Solution
degree top
Since
Ans

degree bottom

...
Thus

...

, we have an oblique or curvilinear asymptote
...

Example 4:

Find the horizontal, oblique, or curvilinear asymptote for where

Solution
degree top
Since

degree bottom

...
Now long divide:

Since

, we have that

Throw away

Ans

defines a curvilinear asymptote

93

G
...
As the graph of a function approaches a vertical asymptote, it shoots up or down toward
approach

approach

2
...

approach

or

approach

approach

approach

3
...

94

...
Find the vertical asymptotes and holes for where

a
...

c
...
Find the horizontal, oblique, or curvilinear asymptote for where
a
...

c
...

f
...

3
...

4
...
What is the domain of the
function?
5
...

95

2
...
Strategy
1
...

2
...

3
...

Note: The graph may not cross vertical asymptotes, but may cross others
...

B
...
Asymptotes:
Vertical:

Horizontal:

2
...

-intercept: set
:

Now graph an initial rough sketch:

Now
need to plot enough points to see what is going on
...
Then pick a few others to
see what is going on:

We plot these points on the grid we already made
...

97

Ans

Example 2:

Graph , where

Solution
1
...

Top:

Bottom:

Rational Root Theorem:
factors of
factors of
Rational Candidates:
98

Note:
Thus

Thus,

Simplifying,

0

...

Thus, we have vertical asymptotes with equations
Also, we have a hole at

and

, we have a

2
...

...

is a factor
...

Now graph an initial rough sketch:

y

x

hole on graph here

Now plot some more points using the output formula

:

Note: In fact, the point from thetable
above is the location of a hole, since

...
Then we connect the points using
the asymptote behavior
...
Asymptotes:
We first have to factor
...
However

the zeros are complex
...

101

Now find it by algebraic long division:

...

2
...

...
Divide it out using synthetic division:

102

...

Thus we have one -intercept,

-intercept: set
:

Now graph an initial rough sketch:

103

...

Now plot some more points using the output formula

:

We plot these points on the grid we already made
...

Ans

104

Example 4:

Graph , where

Solution
1
...

...

Now find it by algebraic long division:

Hence
Thus

...

105

2
...

...

:
-intercept: set

This intercept is not a point either, since we found it by setting
is where we said we had a hole
...

Note: Since this function
is even, we need only make our table with negative
values
...

We plot these points on the grid we already made, along with the -axis reflected
points (even function)
...

Ans

hole

107

Exercises
Graph the function , where
1
...

3
...

108

109

110

Chapter 3
Elementary Trigonometry

3
...
Circles
Standard Form:
1
...
radius:
3
...
Examples
Findthe
center, radius, circumference,

...

Example
1:

and intercepts of the circle, where

Solution
center:

radius:

circumference:

-intercepts: set

:

Thus there are no -intercepts
...

Graph:

circumference:

Example
2:

Find the center, radius, circumference,

...

Solution
center:

radius:

circumference:

:

-intercepts: set

Thus the -intercepts are

113

...

Graph:
y
circumference
x

Note: This special circle is called the unit circle
...
Revolutions on the Number Line
We put a unit circle on the number line at , and allow the circle to “roll” along the number
line:
circumference

Note: The circle will touch (at the point
the right one complete revolution
...
Examples
Where does the circle touch the number line if the circle rolls
...
Find the standard form of the equation of the specified circle:
a
...
center:

c
...
Find the center, radius, circumference,
a
...

and intercepts, and sketch the circle where

b
...
Why does

not define a circle?

4
...

a
...
Left Half a Revolution?
c
...
Right

a Revolution?

e
...
2 The Wrapping Function

A
...

circumference

Let (theta) be the number line variable
...

: wrapping function

: point on the unit circle where

on the number line wraps to

circumference

Note:

is an ordered pair in the plane and not a number
...
Strategy
To easily and semiaccurately locate

, we use the following guidelines:

1
...

wraps

2
...
For instance, if (in lowest terms), we want to find , then
we divide the semicircle into equal sized wedges and count to the correct wedge,
namely the th one
...
To locate
recognize that

when is an integer, we use the number line as a guide and

...

119

C
...

Solution
We divide up the upper semicircle into four equal wedges and count over to the
third wedge:

120

Example 2:

on the unit circle
...

We divide up the lower semicircle into six equal wedges and count clockwise to the
fifth wedge:

121

Example 3:

Locate and mark

on the unit circle
...

Note that

...
Then we need to go
more
...

122

Exercises
1
...
Locate and mark on

a
...

b
...

c
...

d
...

e
...

f
...

g
...

h
...

2
...
3 The Wrapping Function At Multiples of
A
...
Evaluation
Locate

and read off the coordinates
...
Examples
Example 1:

Evaluate

Solution

Ans

125

Example 2:

Evaluate

Solution

Ans

126

Example 3:

Evaluate

Solution

Ans

127

3
...
Introduction
Evaluating
evaluating

for
when

We will derive the

being a multiple of

is a multiple of
...
However, we need a rule for

rule in six easy steps
...
Derivation of the Rule
Step 1: Note that if is a multiple of

(lowest terms), then

128

is in one of 4 spots
...
By symmetry, we get the rule
...
Rule

By symmetry, the and coordinates of
with appropriate signs
...
Strategy
Locate the point on the unit circle, and then use the rule based on the picture
...
Examples
Example 1:

Evaluate

Solution
First locate

on the unit circle:

Since we see that to locate the point, we must have positive
have that
Ans

132

and negative , we

Example 2:

Evaluate

Solution
First locate

on the unit circle:

Since we see that to locate the point, we must have negative
have that

Ans

133

and positive , we

Example 3:

Evaluate

Solution
First locate

on the unit circle:

Since we see that to locate the point, we must have negative
have that
Ans

134

and negative , we

Exercises
Evaluate the following exactly:
1
...

3
...

5
...

7
...

9
...

11
...

135

3
...
Derivation of the , Rule
Step 1: Locate

and

Step 2: Form a central triangle, and label the inside angles
, , and

Notice that since the upper
semicircle has been cut into 3 equal pieces,
we have that

...

and

Step 4: Since
, the triangle is equiangular
...

137

Step 5: By symmetry, the axis bisects the triangle into two with top edge length

Step 6: We examine triangle

We can use the Pythagorean Theorem to find :

138

Step 7: We now have the following picture, from which we can read off

Thus

...

B
...
These give the and coordinates of for being a multiple of or with

appropriate signs
...
Strategy
Locate the point on the unit circle, and then use the rule based on the picture
...
Examples
Example 1:

Evaluate

Solution
First locate

on the unit circle:

Then we draw the triangle and label it:

Since we see that to locate the point, we must have negative
have that
140

and positive , we

Ans

Example 2:

Evaluate

Solution
First locate

on the unit circle:

Then we draw the triangle and label it:

141

Since we see that to locate the point, we must have positive
have that

Ans

Example 3:

Evaluate

Solution
First locate

on the unit circle:

142

and negative , we

Then we draw the triangle and label it:

Since we see that to locate the point, we must have positive
have that
Ans

143

and positive , we

Exercises
Evaluate the following exactly:
1
...

3
...

5
...

7
...

9
...

11
...

144

3
...
Definitions
Let

...

and then use the definitions

Note: For some values of , we may get division by zero upon evaluating a trigonometric
function
...
We will discuss this issue later in the next
section
...
Examples
Example 1:

Find

Solution

:

We first find

...

, so

147

Example 3:

Find

Solution

:

We first find

Thus
Now
Ans

...

, so

149

Example 5:

Find

Solution

:

We first find

Thus
Now

Ans

...

, so

...

151

Exercises
1
...

b
...

j
...

l
...

e
...

g
...

c
...

o
...

m
...
Suppose

and

...
7 Domain and Range of the Trigonometric Functions
A
...
Domain:
Since is defined for any
restrictions
...

2
...

Hence we can see that

, namely -1; the

...

-coordinate

B
...
Domain:

, we have
Given
does this happen?

...

When

happens here

Thus

is undefined for

What is this in interval notation? To see it, let’s plot the allowed values on a number
line:

Thus

:

-

Note: Each interval has an endpoint being an “odd multiple of ”
...

2
...

C
...
Domain:

, we have

This is similar to tangent
...
When does this happen?

Thus

is undefined for

happens here

155

...

2
...

D
...
Domain:

Given
, we have
does this happen?

...

When

happens here

So similar to tangent,

...
Range:
On the right semicircle,
On the left semicircle,

ranges from down to , so

ranges from near to
156

, so

ranges from up to

ranges from

up to

...

Hence

...
Cosecant
1
...
Now

...

2
...

When

F
...
and are undefined at odd multiples of
...

and

are undefined at multiples of
...
8 Trigonometric Functions: Periodicity

A
...

B
...
The smallest
such value of that makes the function periodic is called the period
...
Periodicity of the Wrapping Function

, so the wrapping function is periodic
...

Section 3
...
Periodicity of the Trigonometric Functions
Since the trigonometric functions are defined in terms of , they are also periodic, and
repeat every
...

so, in particular, tangent and cotangent

E
...
9 Trigonometric Functions: Even/Odd Behavior

A
...

161

B
...
Even Functions:

even

even

2
...
Examples
Example 1:

Suppose

...

Solution

Ans

-

162

Example 2:

Suppose

...

Exercises
1
...
Use even/odd relationships to simplify

...
Use even/odd relationships to simplify
...
Find
and odd
...
Suppose
3
...
10 Elementary Trigonometric Relationships
A
...

B
...

2
...

and

and

and

165

C
...

2
...
The Pythagorean Identity

Note:

(because we have a unit circle)

Since we have that

Warning:

and

Shorthand:

, the

equation becomes

does not mean

;

166

means

E
...
Examples
Example 1:

If

, what are the possible values of

Solution

We use Pythagorean I:

Thus,

Ans

168

?

Example 2:

If

, what are the possible values of

Solution
We use Pythagorean II:
Thus,

Ans

169

?

Exercises
1
...
Know
3
...
If
5
...
If
7
...
If

...
Find

...

...

, what are the possible values of

, what are the possible values of

?
?

, what are the possible values of

?

, what are the possible values of

, what are the possible values of

?

170

?

171

172

Chapter 4
Graphing Trigonometric Functions

4
...
Graph of

Since
we are now familiar with the function, we may write
the and in the equation with the and coordinates in the output to

and not confuse

...
Since we know that is -periodic,
we only need to make a table from to
...

B
...
Sinusoidal Graphs
Oscillatory graphs like
take the form:

and

are called sinusoidal graphs
...
Features
1
...
graph bounces between

and
instead of and (stretching)

b
...
Period:

a
...
accounts for horizontal stretching
3
...
Examples
Example 1:

Let

...

Solution

Amplitude:

Period:

Example 2:

Let

...

Solution
Amplitude:
Period:

Phase Shift:

176

In the next section, we will look at how to graph sinusoids using a “modified” HSRV
strategy
...
Sketch the graph of

by plotting points between

and

2
...

b
...

3
...

b
...

d
...

178

...
2 Graphing Sinusoids
A
...
Set
2
...
This gives the start of one cycle
...
This gives the end of one cycle
...
Draw one cycle with amplitude

...
If
is negative, flip across the -axis
...
To get the final graph, perform the vertical shift using the parameter
...
Examples
Example 1:

Graph , where

...

2
...

4
...

5
...

Ans

180

Example 2:

Graph , where

Solution
1
...

3
...

4
...
Shift up 3 to get final answer

181

, is nega-

Ans

centerline

Example 3:

Graph , where

Solution

1
...

182

3
...
Reflect across the -axis:

183

5
...
Graph , where

2
...

b
...

d
...

f
...

h
...
Find

...
3 Sinusoidal Phenomena

A
...

Examples: tides, yearly precipitation, yearly temperature

B
...
Find
(amplitude): Let

2
...
Find :
a
...
then let

(since

time from max to min

)

4
...
first find the phase shift:
b
...
Example
(Tides)
The depth of water at the end of a dock varies with the tides
...
5

4
...
5

2
...
4

am pm
2
...
5

Solution
We model using
1
...
Find :

max

min

3
...
period,
b
...
Find :
a
...

Ans

, where

187

is time in hours past midnight
...
The water at the end of dock varies with the tides
...
Using the data below, construct a sinusoidal model for the water depth,
, in terms of the number of hours, , past midnight
...
5 m

4
...
4 m 4
...
5 m

am

am pm
2
...
5 m

2
...
Measurements of the water depth were taken
every 2 hours and recorded
...

Time

am

am

am

am

Depth

3
...
4 m 3
...
6 m 2
...
6 m

3
...
The table below gives the recorded high temperature as measured on the th of the indicated
month
...

Month
Temperature

JAN

FEB

F

F

MAR APR MAY
F

Month

JUL

AUG

SEP

Temperature

F

F

F

JUN

F

OCT

NOV DEC

F

188

F

F

F

F

4
...
Graph of
Since

, whenever

we get vertical asymptotes:

Thus the graph of

happens here

has vertical asymptotes at odd multiples of
...

undefined

189

to

,

B
...

happens here

This occurs at multiples of , and making a similar table of values, the graph looks like:

190

C
...

Also, since

Furthermore, since
functions
...
Graph

, as in

and

or

or

, we get vertical asymptotes at multiples of
...

2
...

Doing this for

and

yields:

191

192

4
...
General Tangent

Here
we
use
the
idea
that
has
vertical
asymptotes
at

and

-intercept halfway in between, and we use the fact that is -periodic
...
Set

and

to find the location of two vertical asymptotes
...
Put an -intercept halfway in between the two asymptotes
...
Draw in a “copy of
4
...

, flip about -axis
...
Shift centerline up

units
...
General Cotangent
This
except the asymptotes
strategy as general tangent,
forcotangent
are at
has the same

and
, so for
and
in the

, we set
above strategy
...
Examples

Graph , where

Example 1:

Solution

1
...
-intercept (one of): halfway in between

and

3
...
No reflections
5
...

2
...
Now draw in the “copy of

” and make periodic:

4
...
Move Up 2
...

2
...
Now draw in the “copy of

” and make periodic:

4
...

5
...
Comments
1
...

2
...
6 Graphing General Secant and Cosecant
A
...
Graph

2
...

3
...

B
...

,

we use the same strategy as above, except we first graph

C
...
First graph

a
...

:

199

2
...

3
...
First graph
a
...

201

centerline

2
...
Move Down 1

202

Ans

centerline

D
...
For general secant/cosecant, amplitude is undefined
...
Period:

203

Exercises
1
...

b
...

d
...
Graph , where
a
...

c
...

f
...

h
...

204

4
...
Introduction
Sometimes a trigonometric function gets multiplied by another function called a damping
factor

i
...

is the damping factor

here

Damped trigonometric functions involving sine and cosine are straightforward to graph
...

Considering
all possible in the same way, we see that the function oscillates between

(the damping factor)
...
e
...
However, in this section, we consider all viable
factors
...
Graphing Strategy
1
...

2
...

205

and

C
...

b
...

206

Now draw in the damping curves

and

, then modify:

Ans

Example 2:

Graph , where

Solution
First graph

a
...

:

207

c
...

2
...

4
...

209

4
...
Simple Harmonic Motion
An object that oscillates in time uniformly is said to undergo simple harmonic motion
...
Frequency
1
...
Frequency, :

“oscillation speed” (how many cycles per time)

Units: inverse units of time, typically s , also called Hertz (Hz)

210

3
...
Examples

Example 1: An object in simple harmonic motion is described by

...
Time is measured
in seconds and displacement is measured in meters
...

Example 2:

Find a model for simple harmonic motion satisfying the conditions:

Period: s
Maximum Displacement: m
Displacement at

: m

Solution
Since the object starts at maximum displacement, we use the cosine model:

Now

Ans

, and

...
Consider an object in simple harmonic motion
...
Find the period, frequency, angular frequency, and maximum displacement, when the
motion is described by:
a
...

c
...

2
...

b
...

d
...
Describe
the motion of a spring whose
displacement from equilibrium is described
physically

by

...
What physical condition might give rise to such a damping
factor?

214

215

216

Chapter 5
Trigonometric Identities

5
...
Review
1
...

b
...

and

and

and

2
...

b
...
Pythagorean Identities

Pythagorean I:
Pythagorean II:

Pythagorean III:

4
...
Even Functions:

even

even

b
...
Simplifying/Factoring
1
...

2
...

3
...

Common Theme: Look for opportunities to use the Pythagorean Identities by looking for
squared trigonometric functions
...
Examples
Example 1:

Simplify

Solution
Use Pythagorean I:
Thus

to replace

reciprocal

Ans

219

with

...
Simplify

2
...
Factor and simplify
4
...
Factor

8
...
Simplify

10
...
Simplify
12
...
Simplify
14
...
Factor

6
...
Factor and simplify
16
...

222

...
2 Verifying Trigonometric Identities

A
...
No matter what the input is,
the equation works (provided the expressions are defined)
...

Conditional equations are equations that only work for a few values of

(input)

Examples:

(only the solution
(only the solutions

works)

and

work)

We solve (conditional) equations, but we verify identities
...

However, when we verify identities, we have the answer already, in some sense
...
The method to do so is radically
different than the method for solving equations
...
Verifying Identities
Unlike solving equations, we are not allowed to work with both sides of an identity at the
same time to verify it
...

Example: “Prove/verify” that

If we square each side, we get
we’ve done something wrong
...

C
...
Pick one side of the equation (usually the more complicated side), and ignore the other
side
...
Manipulate it, by itself, using valid laws for expressions
...
is not allowed (you don’t have an equation to balance out
the operation!)
3
...

Hence, unlike equations (conditional) where the goal is to solve to get an “answer”, you
actually know the answer to an identity already! It is the other side of the equation! Here
you know the beginning and the end, and the goal is to fill in the middle–to show how to
get from the beginning to the end
...
Verifying Trigonometric Identities
1
...
Try to implement any trigonometric identities you can think of
...

2
...

3
...

4
...
Even if you can’t see immediately what to do, try something! Dead ends sometimes give
you ideas that help you see the correct approach
...
You are
trying to fill in the middle
...
Examples
Example 1:

Verify the identity:

Solution
Start with the left side:

(Now use Pythagorean I:

225

)

Thus we reached the right side, so we are done
...

226

Example 3:

Verify the identity:

Solution
Start with the left side:

(adding)

(multiply out bottom)

(use Pythagorean I)

(use reciprocal identity)

Thus we reached the right side, so we are done
...

Note: Sometimes multiplying top and bottom by something that causes a Pythagorean
identity is a good plan, as in the next example
...

229

)

Example 6:

Verify the identity:

Solution
Start with the left side:

(LCD)

(convert to sines and cosines)

(use Pythagorean I)

Thus we reached the right side, so we are done
...

2
...

4
...

10
...

15
...

12
...

11
...

5
...

231

16
...

18
...

20
...
3 Sum and Difference Formulas I

A
...
Thus as calculated in Step 2 is
the same as the distance between and
...

234

, and

Step 5: Set the two expressions for equal, and use algebra

Hence, we have that

B
...
”

C
...

Justification:

2
...
Derivation of

Using the cofunction identity for

Thus

E
...
Formula for
Writing

as

, and then expanding and simplifying (Exercise), we get

Comments:
1
...
If they are not defined, then you need to simplify the expression the long way,
using

238

G
...

2
...

4
...

Co-sine is short for complementary sine, that is cosine is -complementary to sine
...

239

H
...
Comments
1
...

2
...
Find
2
...
Find
4
...
Find

6
...
Find
8
...
Find

10
...
Find

12
...
Simplify

to obtain the formula

14
...

243

5
...
Summary
1
...

only works when

2
...

244

B
...
Simplify
2
...
Simplify
4
...
Simplify

6
...
Show that

and

8
...

b
...

d
...

f
...

5
...
Derivations
1
...

3
...
Alternate Cosine Form: Replacing

a
...

248

is defined;

B
...

The above formulas are called the double angle formulas
...

C
...
Simplify

2
...
Derive a “triple-angle” formula for

4
...
Simplify

251

5
...
Derivation for

1
...

, and

, so

Then

,

3
...
Summary

, so

252

C
...
with

253

)

Example 2:

Graph , where

Solution
Use the power reducing formula for sine!

Thus, we graph where

1
...

:

3
...
Reflect about the -axis:

5
...
Rewrite
2
...
Rewrite
4
...

without powers
...

5
...
Graph , where

without powers
...
7 Half-Angle Relationships and Formulas
A
...
The choice of root will depend on the
specific value of that is used in a problem
...
Half-Angle Formulas for tangent
Here we will be able to get an explicit formula for with no sign ambiguity
...
for sine)

Now we will obtain another formulation:

(Pythagorean I)

(diff
...
However,
provided these values are not used, the
second expression is often simpler to use
...
Evaluation Examples
Example 1:

Find

Solution
First locate

:

258

work

Use the half-angle relationships for sine and cosine:

Also

Ans

Example 2:

Then,

, and since

Find

, we have

Solution
Here we use the half-angle formula for tangent:
259

, we have

...

(We could have used the other half-angle formula here, and it would result in the
same answer, but it would involve slightly more work)

Ans

260

Exercises
1
...
Find
3
...
Find

5
...
Find

261

5
...
of squares)

Exercises
Verify the following trigonometric identities:
1
...

5
...

3
...

265

5
...
Derivations
Consider the sum and difference formulas for sine:

Adding these two equations, we get:

Dividing by 2, we get:

By similar methods, we also get:

B
...

C
...

Solution
Use

Then

Ans

268

Exercises
1
...
Evaluate

3
...
Evaluate

5
...

6
...
Express

as a sum or difference
...

8
...

5
...
Derivations
Consider the sum and difference formulas for sine:

Adding these two equations, we get:

Let

Since

and

Then
Thus

and

and

...

...

The derivations of the other sum to product formulas are similar
...
Summary

Note: Again, it is more useful to remember how to get the sum-to-product formulas than it
is to memorize them
...
Examples
Express

Example 1:

as a product

Solution
Use

Thus

Ans

:

(even identity for cosine)

271

Example 2:

Express

as a product

Solution
Use

Ans

:

Thus

272

Exercises
1
...
Express

as a product
...
Express
4
...

as a product
...

5
...

5
...

2
...

4
...
1 Capital Trigonometric Functions
A
...
The -plane is divided into 4 quadrants by the and axes
...
The Six Trigonometric Functions
To motivate what comes next, let us first review the graphs of the six trigonometric functions
...
Motivation
All six trigonometric functions fail the horizontal line test, so are not one-to-one/invertible
...

D
...
This is
not the only choice, but it is the most obvious choice
...
We call it
Thus

...

E
...

1
...

3
...

5
...

F
...
The only difference between the behavior of the capital trigonometric functions and the
ordinary trigonometric functions is the restricted domain
...
Like all capital functions, the capital trigonometric functions are invertible
...
2 Capital Trigonometric Problems I
A
...
Rewrite the capital trigonometric functions as the ordinary trigonometric functions with
the appropriate domain restriction
...
Use ordinary trigonometric identities to solve the problem
...
Use the restricted domain to remove the ambiguity in sign
...
Examples
Example 1:

You know

...

Solution
1
...
To get

from , we use

285

:

3
...

Find
...

, so

286

2
...
Use the restricted domain to try to remove the sign ambiguity:

Since

, we are in the region marked:

Here
Ans

, so

287

Exercises
1
...
You know

3
...
You know
5
...

Find
...

...
Find

...

...

Find

6
...

...
3 Capital Trigonometric Problems II
We consider some more complicated examples
...

Find

Solution
1
...
We know that
To get

, we use

, so we need

289

...
Use the restricted domain to try to remove the sign ambiguity:

Since

, we are in the region marked:

Here

, so

...

Thus,

Ans

290

Example 2:

Know

Find

...

2
...

291

3
...

However, our original problem was to find
...

Find

Solution
1
...
To get , we use

3
...

However, we were originally given

, so in particular

...

Thus
Ans

and so we have that
...

Find

Solution
1
...
To get

, there are many different methods that can be used
...
One method:
First find

...
Another method:
Use

to find

Here let us arbitrarily use the first method
...

...

Then

3
...

Thus we have no initial help!
However, since we were originally given
Thus

...

This can not happen in quadrant I, so we must be in quadrant IV
...

Exercises
1
...
Know

3
...
Know

5
...
Know
9
...
Know

...

6
...
Know

...
Know
12
...

Find

...

Find
...

Find

...

...

Find

...
Find
...

...

...

...

and

...

6
...
Introduction
Even though the ordinary trigonometric functions are not invertible, the capital trigonometric functions are (by design)
...

B
...
Graphs of the Inverse Trigonometric Functions

299

300

D
...
Warnings:

a
...

b
...
Be careful of this in problems
...
Some authors are lazy and write

To avoid confusion, write
if that is what is intended
...

, ,
,
, ,
are sometimes written
2
...
In that context, inverse sine,

pronounced “arc-sine” when it is written as

...
Evaluation

We can evaluate inverse trigonometric functions if the output is a multiple
of , , , , or

...

Remember the range of the inverse trigonometric function!

301

F
...

coord

coord

, so we have coord

and coord

Thus
Ans

...

Example 4:

Evaluate

Solution

Note:

and are not inverses
...

Now

Thus we ask “which
Ans

has

with

as the -coordinate?”

Example 5:

Evaluate

Solution

Note:
Now

and

are not inverses
...

Thus we ask “which
Ans

has

304

with

as the -coordinate?”

Example 6:

Evaluate

Solution
Here we can’t evaluate
Thus, in this case,

Thus we have

directly, but we notice that

...

, since

and

are inverses!

Note: We couldn’t do this in the previous examples, since the numbers weren’t in
the domain of the capital function
...

2
...

4
...

6
...

8
...

10
...

12
...
5 Inverse Trigonometric Problems

A
...
Define the inverse trigonometric function output to be
...
Rewrite the definition with no inverse trigonometric function by applying the appropriate capital trigonometric function to each side
...
Recast the problem as a capital trigonometric function problem, and solve it
...
Examples
Example 1:

Find

Solution

1
...
Then

...

3
...

...

307

b
...
Since

,

Here

Ans

, so

308

Example 2:

Find

...
Let
2
...

3
...

...

Find

...
Since

,

Here

, so

Then,

Ans

310

Example 3:

Find

Solution
1
...
Then

...

3
...

b
...

However

Thus

...

...

...

Ans

Example 4:

Find

Solution

1
...
Then

...

3
...

...

312

b
...
Since

, so we need

,

Thus

, so

However we want , so

Ans

313

...

...
Let
2
...

...
Thus we have the capital trigonometric problem:

You know
a
...
)Find

:

...

Find

and

Thus we need

b
...

and

...
)Find

, so

:

315

...

Exercises

1
...
Find
3
...
Find
5
...
Find
7
...
Find

13
...
Find
15
...
Find
12
...
Find
9
...
Find

17
...
Find

318

6
...
Single Function Method
This method is used when each side only contains one inverse trigonometric function
...
Let

one side
...
Manipulate this equation to get rid of the inverse trigonometric function and reduce the
resulting capital trigonometric function to an ordinary trigonometric function with domain
restriction
...
Use regular trigonometric identities to simplify the resulting equation
...
Reverse the process to get

other side
...
Examples

Example 1:

Verify the identity:

Solution

1
...
Then

...

[odd identity for sine]
319

4
...
Let

2
...

Since

4
...

, so

is impossible anyway, so

320

C
...

Assuming that the sum is on the left hand side of the identity
...
Simplify sum as an inverse trigonometric problem to get an identity for sum
...
Use the domain restriction to get an appropriate identity for the original sum
...
instead of
...
Examples

Example 1:

Verify the identity:

Solution
1
...

...
Find

...

Find

:

Now use the domain restriction to eliminate sign ambiguity:
Since

,

Thus

323

, so
...
Now we need to use the domain restriction to get the original identity:

Now

and

Thus we have that

Since
only value of

Aside:

which is easier, as follows:
Let
Then

, so

...

(cofunction identity)

324

Then solving for , we have

Hence we verified that

...

Example 2:

Verify the identity:

Solution
Since is more natural here
...
Simplify
Let

Then

:

and
and

...

Hence we have the following capital trigonometric problem to solve:
Know

and

325

...

Now

and

Also

Hence we have the identity:

2
...

...

It only remains to determine which of the two identities is correct
...

Since
with
we must be in quadrant I
...

since

Exercises
Verify the following inverse trigonometric identities:

1
...

3
...

7
...

9
...

5
...

[Hint: Start with the right hand side]

328

6
...
Summary
1
...

b
...
Cofunction Inverse Identities

a
...

c
...
Reflection Identities

a
...

c
...

e
...

B
...

In particular,
1
...

3
...

In fact, using the identity,
inverse sine button only!

330

, we can reduce the need to that of an

Then
1
...

3
...

5
...
8 Solving Trigonometric Equations I

A
...

functions, i
...

332

B
...

Since

, we have that coord
...

However, more than that, by adding we get two more solutions
...
Strategy
1
...

2
...

3
...

Note: In situations where more than one type of trigonometric function occurs in an equations, we try to either
a
...
get rid of one of the trigonometric functions via trigonometric identities
...
Examples
Example 1:

Solve

for

Solution

coord

334

Ans

Solve

Example 2:

for

Solution

Let

, to make a standard quadratic equation
...

By the Zero Product Principle:

coord

or

or

or

coord

Ans

336

Example 3:

Solve

for

Solution

Use Pythagorean I to eliminate the trigonometric function

By the Zero Product Principle:

coord

or

or

or
or

coord

It is impossible for the -coordinate to be , so coord

337

...
Comments
1
...

For example, if we consider the answer to Example 1:

it can be written as

338

since

since

and

differ by

and

and

differ by
...

2
...

See the examples that follow
...
More Examples
Example 1:

Solve

for

Solution

(Diff
...
Consider

:

Thus

Hence,

II
...
Consider

:

Thus

Putting all of these solutions together, we get

Thus, we have (upon reducing),

Ans

, we don’t divide by 5 until the very end
Note: For
after we have all the solutions via adding
...

This motivates the following trick:
1
...

2
...

Now do it:
1
...

2
...

4
...

6
...

8
...

11
...

13
...

344

14
...

16
...

345

6
...
to solve
trigonometric equations
...
However, we can use the double angle formula
...

348

Thus,

Now
we need to do the check
...

Check:

?

Thus substituting into the original equation:
349

?

?

?

Thus substituting into the original equation:

?

?

?

Thus substituting into the original equation:

?

350

?

X

?

Thus substituting into the original equation:

?

?

are

Thus the only initial solutions that work in the interval

Ans

Example 4:

Solve

and

for

Solution
Use the sum-to product formula:

351

is even

X

By the Zero-Product Principle:

or

Consider first

:

Here we have
Thus

352

Now consider

:

Here we have
Thus

Putting all solutions together, we get

Ans

353

Exercises

Solve the following equations for :
1
...

3
...

7
...

9
...

4
...
10 Harmonic Combination
A
...

We will “reduce” this as follows:

1
...
Since

Thus

,

:

is on the unit circle
...
Thus

355

4
...

B
...

C
...

, where

In fact, we can simplify

:

Thus

...

2
...

Ans

Solve

Example 3:

for

Solution
Compress the harmonic combination
...

...

Then we have
Ans

359

:

Exercises
1
...

b
...

d
...
Graph , where
a
...

3
...

b
...
1 General Angles
A
...

363

We have solutions at

:

and

:

:?

We need to find

:

chords are the same, so
the corresponding arcs
are congruent

364

length
of arc is

Thus

:

...
However, let us reconsider the original picture:

Note: If we consider the two triangles, we know that the legs of the two triangle are congruent, since both have length and the hypotenuse of the two triangles are congruent, since

both have length (unit circle)
...

Thus the inner angles of the triangles are the same
...

Goal: Connect arc length to angles
...
Radian Measure of Angles
On the unit circle, we define the radian measure of an angle to be the signed arc length on
the circle as a number (in the same fashion as the wrapping function)
...
Comments
1
...
Special Angle: radians

D
...

Hence, we have the arc length formula:

E
...

F
...

...
To convert degrees to radians: multiply by

...
To convert radians to degrees: multiply by
...
Radian measure for an angle is just a number!

G
...

b
...

Solution

b
...

c
...

b
...

b
...
Comments on Terminology
1
...

Coterminal angles differ by a multiple of (or by )

370

2
...
Complementary Angles: Angles that differ by

I
...
If an angle is
given in degrees, we need to convert to radians first before using the arc length formula
...

m

Solution
We first need to convert to radians:

Now use the arc length formula:
Since
Ans

, we have that

m

m

372

m

Example 2:
m

Find the central angle of a circle of radius
m

m

Solution

Ans

(in radians)

373

m that cuts off an arc length of

Exercises
1
...

b
...

d
...

f
...
Convert the following to degrees:
a
...

c
...

3
...

4
...

5
...

6
...

7
...

A
...

and

Then we have that

...

B
...
Examples
Example 1:

Given the right triangle:

Find ,

,

Solution
We first get the hypotenuse via the Pythagorean Theorem:

Now use the right triangle definitions:

opp
...

adj
...

opp
...

377

Example 2:

Given the right triangle:

Find ,

,

Solution
We first get the third side via the Pythagorean Theorem:

Now use the right triangle definitions:

adj
...

opp
...

hyp
...

378

D
...
e
...

We can solve a right triangle if we have at least the following information:
1
...
One side and one acute angle
...
Tools For Solving Right Triangles
1
...

2
...

Thus, if the two acute angles are and , we have that

or

...
Everything else can be found by using the trigonometric ratios
...
Typically
degree measure is used in triangle problems
...

379

F
...

We label the angles opposite the sides by ,
Note:

,

...

G
...
Some Terminology
1
...
Angle of Depression
Observer

Horizontal

Object

383

3
...
Find ,

, and

for the given right triangle:

a
...

b
...

2
...
Use a calculator and round to two decimal places
...

b
...

d
...

f
...
Consider a cube with edge length

...
Consider a cube with edge length

...
3 Lines and Angles
A
...

Now consider in relation to the slope of the line:

We have that

387

B
...
Picture:

2
...

...

To ensure that the smaller angle is chosen, no matter which line is “labeled” line 1,

388

Since

, we may write

3
...
Example:

Find the smallest
the
angle between
two lines

given by and

...

2
...

390

7
...
These are called oblique triangles
...
Law of Sines

1
...
Derivation:
Here we assume that we have an acute triangle, i
...
all angles in the triangle are
acute
...
e
...

Thus

, so

391

...

B
...
Law:

2
...

We will assume that the triangle is acute
...

We place the triangle on the , coordinate system as follows:

392

Now by the Pythagorean Theorem, we have that

(by above two equations)

(Pythagorean I)

393

C
...
Formulas:

2
...
The other can be derived similarly
...
Law of Tangents

1
...
Derivation:

(Mollweide’s Formulas)

396

(cofunction identities)

(quotient identities)

(reciprocal identity)

397

7
...
Introduction
We can solve oblique triangles using the Law of Sines and Law of Cosines if one side is
known, along with two other parts (sides or angles)
...
Cases
1
...
AAS : Two angles and a nonincluded side:

know
know

b
...
Two sides:
a
...
SAS : Two sides and an included angle:
know

know
know
3
...
Comments
1
...

2
...
SSA is called the ambiguous case
a
...
no triangle
II
...
two triangles
b
...

no triangle

II
...

, but

two triangles

IV
...
conditions for

obtuse:

I
...

one triangle

402

7
...
Strategy
1
...

2
...
If not sufficient, use Law of Cosines
...
Check your answers in one of Mollweide’s Formulas (it doesn’t matter which one)
...

B
...
If possible, try to find the largest angle first
...
This will tell you automatically that the other two angles are acute, and can help to
eliminate fake solutions
...
Remember that all three angles of a triangle add to

403

...
Examples
Example 1:

Solve the triangle:

,

,

Solution
Draw a Picture:

First find

:

Now find
:
Law of Sines:
Thus,

Then

...

Now we need to check the answer using one of Mollweide’s Formulas
...
)

Thus
Ans

,

,

405

Example 2:

Solve the triangle:

,

,

Solution
Draw a Picture:

First find

:

Law of Sines:
Thus,

Then

II

Now at
I,

so

I

, so we have

406

,

Now at II, the solution (as in the beginning
7
...
e
...

...

Case I:

Then find

:

Then find :
Law of Sines:

Case II:

Thus,
Then

...

Now we need to check the answers using one of Mollweide’s Formulas
...
)

Thus this triangle is valid
...
)

Thus this triangle is valid
...

Law of Cosines: Find

(largest angle)

Since

, we have

, so

Note: Since we found the largest angle, we know that
the other two angles are acute!
Find :
Now we can use the Law of Sines:
Thus

...

...

interval
in the

...

Use

:

Check:

?

?

Thus

,

?

(approx
...

Find c:
Law of Cosines:

Find B:
Law of Sines:
Then

...

b
...

Use

:

Check:
1st triangle:

?

?

? (approx
...

412

2nd triangle:

?

?

?

(approx
...

Ans

, ,

413

Exercises
Solve the following triangles
...

1
...

,

3
...

5
...

7
...

9
...

13
...

,

,

,

,

,

,

,

,

,

,

,

,

,
,

,

, ,

11
...

,

,

,

,

,

,

,
,

414

7
...
Oblique Triangle Formula

The area of the triangle,

, is given by

Using the same idea for other triangle heights, we have

The easy way to remember this is to take “one half the product of two sides and sine of the
included angle”
...
Heron’s Formula
Heron’s Formula for the area of a triangle is a formula that only involves the lengths of the
three sides of the triangle
...
Derivation of Heron’s Formula

(Mollweide’s Formula)

(cofunction identity)

(definition of )

416

(sum/diff formulas)

Hence

Then

Hence

(cofunction identity)

(sum formula for cosine)

...

, so

...
Examples
Example 1:

Find the area of the triangle

Solution
Use the oblique triangle formula!

Ans

(double angle identities)

Thus

Hence

418

,

,

Example 2:

Find the area of the triangle

,

,

Solution

Use Heron’s Formula:

Now
Then

Ans

, where

419

Exercises
Find the area of the triangle:
1
...

3
...

,

,

,
,

,
,

,

,

420

Selected Answers to the Exercises

0
...

3
...

1
...
no
1b
...
yes, explicit
1d
...
yes, explicit
1f
...
yes, implicit
2a
...

2f
...

4
...

1
...

1b
...

2b
...

2f
...
3
1a
...

1e
...

;

423

1
...
neither
1c
...
even
2
...

;

o

1
...
After you fully simplify:

;

;

3b
...

4b
...
8
2
...

5a
...

1
...
no
3
...
10
2
...
yes
1
...

1d
...

3b
...
13

1
...
14
2
...

;

;

2
...
vertical asymptote:
1c
...
horizontal asymptote:
2d
...
horizontal asymptote:

;

2
...

426

4
...
1
1a
...

2b
...

4d
...
2

a), c), e), g),
i), k), m), o)

,

3
...

3
...

7
...

11
...
5
1
...

6
...

9
...

1a
...

1e
...

1i
...

3
...
undefined
1o
...
9
1
...
10
1
...

5
...

4
...
period

;

3b
...
amplitude
3e
...
2
1a
...

1e
...

centerline

4
...

3
...

For instance, when

above, we get

(rather than )
...

4
...

1c
...

2b
...

centerline

2g
...
7
1
...

435

4
...
Period: s

Angular Frequency:
s

Frequency: Hz
Maximum Displacement:

1d
...

2c
...
1
1
...

3
...

5
...

7
...

9
...

11
...

13
...

5
...

3
...

6
...

9
...

5
...

3
...

2
...
5

437

3
...

2
...
6

5
...
7

1
...

5
...

5
...

5
...

5
...

4
...

6
...

4
...
3

1
...

5
...

9
...

439

12
...
4
1
...

4
...

8
...

6
...

4
...

7
...

9
...

14
...

440

16
...

6
...

3
...

8
...

13
...

16
...
9
1
...

5
...

8
...
10

1a
...

, where

, where

2b
...

442

7
...

1c
...

2a
...

3
...

6
...
2
1a
...

2a
...

2e
...

;

;

;

;

,
,

,

,
,

,

7
...

443

7
...

3
...

,

,
OR

,

,
,

7
...

,

13
...
7

1
...

444

Index

Symbols
, 210

, 20

,

42

, rule, 139

rule, 131

, 284

, 284

, 284
, 78
, 284

, 284

, 284

, 145, 376

, 145, 376

, 145, 376

, 47

, 47

, 47

, 51, 54

, 51

, 81

, 75

, 23

A
AAS Triangle, 398
acute angles, 379
acute triangle, 391
adjacent side, 376
ambiguous case, 400
amplitude, 175
angle between two lines, 389
angle of depression, 383
angle of elevation, 383
angular frequency, 210
arc length formula, 368
area, 415
ASA triangle, 398
asymptotes, 88

, 47

, 18
, 18
, 42
, 42
, 42

, 42
, 38
even

, 38
odd

, 75

, 23
, 145, 376

, 145, 376

, 145, 376
, 210
, 210
Hz, 210

, 118

, 298

, 298
, 298

, 81

, 81
, 298

, 298

, 298
, 67

, 73
, 67

, 81
445

domain of composition, 51, 54
domain of inverse trigonometric functions, 298
domain of trigonometric functions, 153
double angle formulas, 249

B
bands, 54
bearings, 384
branch, 79, 81
C
capital function, 78
capital trigonometric functions, 284
capital trigonometric problems, 285
center, 111
centerline, 182, 186
circles, 111
circumference, 111
cofunction identities, 236
cofunction inverse identities, 329
combinations, 42
combining functions, 42
complementary angles, 371
conditional equations, 223
converting degrees to radians, 369
converting radians to degrees, 369
cosecant, 145, 376
cosine, 145, 376
cotangent, 145, 376
coterminal angles, 370
crossing asymptotes, 94
cursive, 18
curvilinear asymptotes, 89, 91

E
equilibrium, 210
even and odd trig functions, 162
even functions, 35
even/odd decomposition test, 40
even/odd tests, 36
explicit functions, 15
F
factoring formulas, 9
factoring trigonometric expressions, 219
formal method, 63
frequency, 210
function composition, 42
function definition, 15
function notation, 18
function operator, 18
functions, 15
G
general cosecant, 199
general cotangent, 193
general secant, 199
general tangent,
193

graph of , 175, 280

graph of , 191, 281
graph of , 192, 282
graph of , 192, 282
graph of , 174, 280
graph of , 190, 281

graph of , 299

graph of , 300
graph of , 300
graph of , 300
graph of , 299
graph of
, 299
graphing rational functions, 96
graphing sinusoids, 179

D
damped trigonometric functions, 205
damping factor, 205
decomposition into even and odd parts,
38
degree measure, 368
degrees, 368
difference of cubes, 9
difference of squares, 9
difference quotient, 20
displacement, 210
domain, 23
domain finding, 23
domain of combined functions, 47
446

graphs of the inverse trigonometric functions, 299
graphs of the trigonometric functions,
174, 175, 190–192
H
half-angle formulas for tangent, 258
half-angle relationships for sine/cosine,
257
harmonic combination, 356
Heron’s formula, 415
Hertz, 210
holes, 89, 90
horizontal asymptotes, 89, 91
horizontal stretching, 176
horizontal translation, 29
HSRV transformations, 29
hypotenuse, 376

obtuse triangle, 391
odd functions, 35
one-to-one function, 63
one-to-one tests, 63
opposite side, 376
P
perfect square, 9
period, 159, 176, 210
periodic, 159
periodicity, 159
phase shift, 176
power reducing formulas, 252
principal function, 78
product to sum formulas, 266
Pythagorean I, 167
Pythagorean Identities, 167
Pythagorean II, 167
Pythagorean III, 167

I
identities, 223
implicit functions, 15
inverse function evaluation, 70
inverse function finding, 67
inverse functions, 67
inverse trigonometric functions, 298
inverse trigonometric problems, 307
inverses, 59

Q
quadrants in the -plane, 279
quotient identities, 166
R
radian measure, 366
radians, 366
radius, 111
range, 23
range finding, 25
range of inverse trigonometric functions, 298
range of trigonometric functions, 153
rational function, 89
reciprocal function, 87
reciprocal identities, 165
reciprocal inverse identities, 329
reciprocate, 199

reflecting across line
, 73
reflection identities, 330
reflections, 30
revolution, 115
right triangle trigonometry, 376

K
key points, 30
L
law of cosines, 392
law of sines, 391
law of tangents, 396
M
Mollweide’s Formulas, 394
mutilated graph, 54
O
oblique asymptotes, 89, 91
oblique triangle formula, 415
oblique triangles, 391
447

vertex formula, 27
vertical asymptotes, 89, 90
vertical line test, 17
vertical translation, 30

S
SAS triangle, 399
secant, 145, 376
shrinking, 29
simple harmonic motion, 210
simplifying trigonometric expressions,
219
sine, 145, 376
sinusoidal graphs, 175
sinusoidal phenomena, 186
slope of a line with trigonometry, 387
SOH-CAH-TOA, 376
solving right triangles, 379
solving trigonometric equations, 332
spring-mass system, 210
square formula, 8
SSA triangle, 399
SSS triangle, 399
stretching, 29
sum and difference formulas, 233
sum of cubes, 9
sum to product formulas, 271
supplementary angles, 371
symmetric domains, 38
symmetry, 35
symmetry of trig functions, 162

W
wrapping function, 118
Y
yearly precipitation, 186
yearly temperature, 186

T
tangent, 145, 376
tides, 186
trigonometric equations, 332
trigonometric functions, 145
trigonometric functions for right triangles, 376
U
unit circle, 114
V
verifying identities, 224
verifying inverse trigonometric identities, 319
verifying trigonometric identities, 225,
262
448

Title: Trigonometry for maths
Description: Complete notes of trigonometry

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