Calculus: An Integrated Approach to Functions and their Rates of Change, Preliminary Edition Part 66 ppsx

To solve a triangle means to find measures for all three sides and all three angles from information given.. In the case of a right triangle, if we know the measure of one of the acute a

x p A

v

B = (1, 0)

(0, –1)

(0, 1)

O

(–1, 0)

1

sin x = length of CP cos x = length of OC tan x = length of AB sec x = length of OA

Figure 20.6

Trigonometry of Right Triangles

From times of antiquity, scientists and engineers have used triangle trigonometry to con-struct edifices and to estimate distances and heights—from estimating the height of the great Egyptian pyramids in Giza to estimating the sizes and distances of the sun and the moon

A triangle has three sides and three angles To solve a triangle means to find measures for

all three sides and all three angles from information given

In the case of a right triangle, if we know the measure of one of the acute angles, then

we know the measures of all the angles This, together with the length of any one side, enables us to solve the triangle If the lengths of any two particular sides of a right triangle are known, we can use the Pythagorean Theorem to determine the length of the third and trigonometry to determine the measure of the angles Knowing the measures of all three angles does not determine the triangle, but knowing the length of all three sides does.5 (Think about why this is so.)

Examples involving solving right triangles often include the terms “angle of elevation”

and “angle of depression.” Angle of elevation refers to the angle from the horizontal up to

an object; angle of depression refers to the angle from the horizontal down to an object.

EXAMPLE 20.1 A little girl flying a kite on a taut 350-foot string asks her father for the height of her kite

Her father estimates the angle of elevation of the kite to be 55◦ Give an estimate for the height of the kite Assume that the girl is holding the string 3 feet above the ground and her father is measuring the angle of elevation from this height

350 ft.

350 ft.

x

Figure 20.7

5

632 CHAPTER 20 Trigonometry—Circles and Triangles

SOLUTION Let x + 3 = the height of the kite

We’re looking for a trigonometric function that relates x and the known parts of the triangle x is the side opposite the 55◦angle and we know the length of the hypotenuse

sin 55◦= x

350 sin(55◦) = x

350

x = 350 · sin(55◦)

x ≈ 286.7 The kite is flying at a height of approximately 290 feet

EXAMPLE 20.2 When the sun is 38◦above the horizon, a totem pole casts a shadow of 25 feet How tall is

the totem pole?

SOLUTION Let T be the height of the totem pole

Totem

Shadow

38°

25

T

Figure 20.8

Using the diagram, we can write a trigonometric equation that relates the information

we know with the information we want to find

tan 38◦=25T Thus, T = 25 tan 38◦≈ 19.5 feet

EXAMPLE 20.3 A clock tower sits on top of a tall building From a point 300 feet from the base of the building

the angle of elevation to the base of the clock tower is 40◦and the angle of elevation to the top of the tower is 49◦ How tall is the clock tower?

SOLUTION Let x = the height (in feet) of the clock tower

Let y = the height (in feet) of the building up to the base of the tower

x y

x + y

40°

40°

9°

300

49°

Figure 20.9

We’ll use a trigonometric function that relates the lengths of the sides opposite and adjacent

to the known angle

Using the smaller triangle we can solve for y

tan 40◦= y

300

y = 300 tan 40◦ Using the larger triangle we have

tan 49◦=x + y300

x + y = 300 tan 49◦

x = 300 tan 49◦− y = 300 tan 49◦− 300 tan 40◦

x = 300(tan 49◦− tan 40◦)

x ≈ 93.4

The clock tower is approximately 93.4 feet tall

P R O B L E M S F O R S E C T I O N 2 0 1

1 Given each triangle below, write expressions for the six trigonometric functions

(a)

θ

4

3

(b)

θ

Q

1

(c)

θ

R

1

2 As illustrated on the following page, a tree casts a shadow of 20 feet when the sun’s rays make an angle of 0.7 radians with the ground How tall is the tree?

634 CHAPTER 20 Trigonometry—Circles and Triangles

ground 7

3 A 25-foot ladder is leaning against a straight wall If the base of the ladder is 7 feet from the wall, what angle is the ladder making with the ground and how high up the wall does it go?

4 You’re in an apartment looking across a 25-foot boulevard at a building across the way The angle of depression to the foot of the building is 15◦and the angle of elevation to the top of the building is 50◦ How tall is the building?

5 You are standing on an overpass, 35 feet above street level, waving to a friend who is

at the window of a high-rise dormitory The angle of depression to the bottom of the dormitory (on street level) is 15◦ The angle of elevation to your friend’s window is

45◦ What is your friend’s elevation?

6 We are standing on flat ground in Monument Valley trying to estimate the height of the edifices We have surveying equipment and take all of our measurements from a height

of 5 feet We find the angle of elevation to the top of one structure is 23◦ We move 500 feet closer to the structure and find that the angle of elevation is now 29◦ How tall is the structure?

5 ft 5 ft.

7 Graph each of the following Be sure to display at least one full period of the function For parts (a), (b), and (e), use what you know about graphingf (x)1 when given the graph

of f (x)

(a) y = 3 sec x (b) y = − cot x (c) y = tanx

2



(d) y = −3 tan x (e) y = 2 csc x

8 In several ancient civilizations trigonometry was a highly developed field This can in part be attributed to ancient astronomers How could an ancient astronomer who could measure angles of elevation use trigonometry to estimate the height of the moon?

9 Peter is measuring the height of a church steeple He stands on level ground 500 feet from the base of the church and determines that the angle of elevation from the ground

to the base of the steeple is 23◦ From the same spot he measures the angle of elevation

to the highest point of the steeple and finds it is 29◦

(a) How high is the church, from the base of the church at ground level to the tip of the steeple? Give an exact answer and then give a numerical approximation (b) How high is the steeple? Give an exact answer and then give a numerical approx-imation

INFORMATION THEY GIVE US

In Section 20.1 we used the ratios of the lengths of sides of a right triangle to define sin θ , cos θ , tan θ , and their reciprocals for any acute angle θ Generally these definitions aren’t computationally practical if our aim is very accurate computation of the values of trigonometric functions We don’t relish the thought of sitting down with a protractor and ruler, constructing some angle θ , drawing a right triangle, measuring the sides, and computing the ratio, do we? No! We’d much prefer to whip out a calculator and push some buttons.6In the absence of a calculator but in the presence of a calibrated unit circle we can use the circle to approximate the value of the trigonometric function, but the degree of accuracy we can expect is limited There are, however, two special triangles that are very useful to us in obtaining the exact values of the trigonometric functions of the angles they contain, as well as the exact values of trigonometric functions of their close relatives These two triangles are triangles all students of trigonometry come to know and love

The 45◦, 45◦Right Triangle7

Draw an isosceles right triangle.8 Its acute angles are equal; both are π/4 radians (or

45◦) Let’s label the legs We can call them anything Let’s use 1 for simplicity Using the Pythagorean Theorem we see that the hypotenuse has length√

2 From the triangle we see that9

sin(π/4) =√1

2, cos(π/4) =√1

2, tan(π/4) = 1

6 You may wonder “How does a calculator do it? How does it evaluate sin 0.1, for instance?” This is a very good and interesting question The short (and somewhat accurate) answer is that the calculator uses a polynomial to approximate sin x near x = 0 and evaluates that polynomial at x = 0.1 The concept is along the lines of what we do when we take tangent-line approximations, but

it is done with much more sophistication We will study this in Chapter 30.

7 These triangles tend to be identified by their degree-angle measurements; they are easier to say aloud, and the study of these triangles is traditionally first undertaken in a trigonometry class as opposed to a calculus class Radians show their advantage with calculus, as we will see in the next chapter.

8 An isosceles triangle has two sides of equal length.

9 In some places the dogma is that writing a fraction with a radical in the denominator, like 1/ √

2, is a mortal sin Relax.

636 CHAPTER 20 Trigonometry—Circles and Triangles

1

1

π

4

π

4

√2

Figure 20.10

This information could also be obtained from the unit circle P (π/4) is the point of intersection of the line u = v and the unit circle u2+ v2= 1 Substituting v = u into the equation of the circle we obtain

u2+ u2= 1 2u2= 1

u2=1 2

u = ±√1

2.

If u =√1

2then v = √1

2; if u = −√1

2then v = −√1

2

v

u

π

4

π

4

(a)

1

P( (

u2 + v2 = 1

v

u

(b)

π

4 (

5 π

4

P( (

√21 (

(–

√21

– ,

√2

1 (

( √21

, = P(

=

Figure 20.11

At no extra cost we obtain the coordinates of a second point on the unit circle Using the symmetry properties of the circle we can identify the coordinates of two more (See Figure 20.12.) This allows us to compute all the trigonometric functions for any x that takes us

to one of these four points Combined with the u- and v-intercepts, this gives us a total of eight points on the unit circle whose exact coordinates we can associate with P (x) From Figure 20.12, we can read off the following information

P (x) =



1

√

2,

1

√

2

 for x = π/4 + 2πn, P (x) = −1

√

2,

−1

√ 2

 for x = 5π/4 + 2πn,

P (x) = −1

√

2,

1

√

2

 for x = 3π/4 + 2πn, P (x) =

 1

√

2,

−1

√ 2

 for x = 7π/4 + 2πn, where n is any integer

π

4

7 π

4

P(

√2

1 (

( √21

,

P( ) =

√2

1 (

( √21

, ) =

3 π

2

P( ) = (0, –1)

π

2

P( ) = (0, 1)

v

u

P(0) = (1, 0)

P(π) = (–1, 0)

–

3 π

4

P(

√2

1 (

( √21

, ) = –

5 π

4

P(

√2

1 (

( √21

, ) = – –

Figure 20.12

In general, if we know the coordinates of a point P on the unit circle, we can identify the coordinates of points Q, R, and S in the other three quadrants Quadrants are labeled

I, II, III, and IV, working counterclockwise from the first quadrant, where both coordinates are positive

The 30◦, 60◦Right Triangle

Draw an equilateral triangle All its sides are of equal length, so all of its angles are of equal measure; each angle is π/3 radians, or 60◦ This time let’s call the length of each side 2 (We’ll chop one side in half right away.) Drop a perpendicular to create a right triangle with acute angles of π/3 and π/6 The perpendicular cuts one of the sides of the original equilateral triangle in two We now have a right triangle in which the only missing piece

of information is the length of the side opposite π/3 We find this using the Pythagorean Theorem

12+ x2= 22

x2= 3

x = ±√3

x =√3 because x ≥ 0

638 CHAPTER 20 Trigonometry—Circles and Triangles

π

3

π

3

π

3

π

6

2

√3

Figure 20.13

Notice that the side opposite the smallest angle is smallest in length; the side opposite the largest angle is largest in length From the triangle we see that

sin(π/3) =

√ 3

2 cos(π/3) =1

2 tan(π/3) =√3 sin(π/6) =1

2 cos(π/6) =

√ 3

2 tan(π/6) =√1

3

π

3

π

3

π

6 2

1

1

1

√3

2

1

2 1

2

1

2 1

2

√3

2

√3

2

√3

v

v

π

3 2 1

2 1 (

( ,

P( ) =

2

√3

π

6

π

2

√3

P( ) =

Figure 20.14

We can transport all this information to the unit circle Scale down the triangle so its hypotenuse is 1 by cutting all sides in half We use the symmetry of the circle to obtain the coordinates of eight points on the circle, as shown in Figure 20.15 On the diagram we have listed only x-values between 0 and 2π , but infinitely many others can be obtained by adding multiples of 2π

√3

π

3 2 1

2 1

(

( ,

P( ) =

2

√3

π

6 ( , (

P( ) =

v

u

1

2 2

√3

2 π

3

1 (

( ,

P( ) = –

2 2

√3

5 π

3

1 (

( ,

2 2

√3

4 π

3

1 (

( ,

P( ) = – –

2 2

√3

5 π

6

1 (

( ,

P( ) = –

2 2

√3

7 π

6

1 (

( ,

√3

11 π

6

1 (

( ,

Figure 20.15

We can determine the coordinates of P (x) for x any integer multiple of π6, x =nπ6 where n is an integer Now we have a host of angles for which we can evaluate trigonometric functions exactly

EXAMPLE 20.4 (a) Evaluate cos(−5π/6) (b) Evaluate sin 3π/4

SOLUTIONS (a) First locate P (−5π/6) on the unit circle We want the coordinates of P = P (−5π/6)

Approach 1

Find the coordinates of P by using the symmetry of the circle to bounce into the first quadrant where we have an acute angle and can use the π/6 − π/3 right triangle Then return to P

π

6

π

6

1

2 1

2

√3

v

v

2 1 2

√3 ( ( ,

2 1 2

√3 ( ( ,

2 1 2

√3 (

v

u R

P

(a)

Figure 20.16

640 CHAPTER 20 Trigonometry—Circles and Triangles

Shortcut

We’re looking for the coordinates of P (x) where x is an integer multiple of π6 We know that a 30◦, 60◦right triangle is involved and, due to the position of P , that both coordinates are negative Therefore, the coordinates of P are either−1

2 ,−√3 2



or−23,−12  We see from the position of P that the magnitude of the v-coordinate

is less than that of the u-coordinate.10Therefore, the coordinates of P are−√3

2 ,−1 2

 cos−5π6 =−23

v

u

2 2

√3 –5 π

6

–5 π

6

1 (

( ,

Figure 20.17

(b) To evaluate sin(3π/4), first locate P (3π/4) on the unit circle, then find its coordinates Due to its position, we know the coordinates of P (3π/4) are (negative, positive)

We know that a 45◦, 45◦right triangle is involved, so the coordinates are−1√

2,√1 2

 Therefore, sin3π4=√1

2

v

u

3 π

4

3 π

4

P( )

Figure 20.18

EXERCISE 20.2 Evaluate, giving an exact answer Check your work by comparing your answer with the

numerical approximation provided by a calculator

(a) sin(3π/4) (b) sin(−3π/4) (c) tan(7π/6) (d) cos(−π/3) (e) tan(−π/4)