Transcript Chapter 8

Chapter 8
The Trigonometric Functions
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 1 of 39
Chapter Outline

Radian Measure of Angles

The Sine and the Cosine

Differentiation and Integration of sin t and cos t

The Tangent and Other Trigonometric Functions
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 2 of 39
§ 8.1
Radian Measure of Angles
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 3 of 39
Section Outline

Radians and Degrees

Positive and Negative Angles

Converting Degrees to Radians

Determining an Angle
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 4 of 39
Radians and Degrees
The central angle determined by an arc of length 1
along the circumference of a circle is said to have a
measure of one radian.
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 5 of 39
Radians and Degrees
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 6 of 39
Positive & Negative Angles
Definition
Example
Positive Angle: An
angle measured in the
counter-clockwise
direction
Definition
Example
Negative Angle: An
angle measured in the
clockwise direction
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 7 of 39
Converting Degrees to Radians
EXAMPLE
Convert the following to radian measure a 450 b  210.
SOLUTION
a  450   450  
180
radians 
b   210   210  
180
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5
2
radians  
7
6
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Determining an Angle
EXAMPLE
Give the radian measure of the angle described.
SOLUTION
The angle above consists of one full revolution (2π radians) plus one halfrevolutions (π radians). Also, the angle is clockwise and therefore negative.
That is,
t  2     3 .
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 9 of 39
§ 8.2
The Sine and the Cosine
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 10 of 39
Section Outline

Sine and Cosine

Sine and Cosine in a Right Triangle

Sine and Cosine in a Unit Circle

Properties of Sine and Cosine

Calculating Sine and Cosine

Using Sine and Cosine

Determining an Angle t

The Graphs of Sine and Cosine
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 11 of 39
Sine & Cosine
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 12 of 39
Sine & Cosine in a Right Triangle
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 13 of 39
Sine & Cosine in a Unit Circle
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 14 of 39
Properties of Sine & Cosine
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 15 of 39
Calculating Sine & Cosine
EXAMPLE
Give the values of sin t and cos t, where t is the radian measure of the angle
shown.
SOLUTION
Since we wish to know the sine and cosine of the angle that measures t radians,
and because we know the length of the side opposite the angle as well as the
hypotenuse, we can immediately determine sin t.
sin t 
1
4
Since sin2t + cos2t = 1, we have
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 16 of 39
Calculating Sine & Cosine
CONTINUED
2
1
2
   cos t  1
 4
Replace sin2t with (1/4)2.
1
 cos 2 t  1
16
cos 2 t 
cost 
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Simplify.
15
16
15
4
Subtract.
Take the square root of both
sides.
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Using Sine & Cosine
EXAMPLE
If t = 0.4 and a = 10, find c.
SOLUTION
Since cos(0.4) = 10/c, we get
cos 0.4  
10
c
ccos0.4  10
c
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10
 10.9.
cos0.4
Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 18 of 39
Determining an Angle t
EXAMPLE
Find t such that –π/2 ≤ t ≤ π/2 and t satisfies the stated condition.
sin t   sin3 / 8
SOLUTION
One of our properties of sine is sin(-t) = -sin(t). And since -sin(3π/8) =
sin(-3π/8) and –π/2 ≤ -3π/8 ≤ π/2, we have t = -3π/8.
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 19 of 39
The Graphs of Sine & Cosine
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 20 of 39
§ 8.3
Differentiation and Integration of sin t and
cos t
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 21 of 39
Section Outline

Derivatives of Sine and Cosine

Differentiating Sine and Cosine

Differentiating Cosine in Application

Application of Differentiating and Integrating Sine
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 22 of 39
Derivatives of Sine & Cosine
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 23 of 39
Differentiating Sine & Cosine
EXAMPLE
Differentiate the following.
a  ecos x b 3 sin πt
SOLUTION



sin πt 
a 
d cos x
d
e
 e cos x  cos x   e cos x  sin x 
dx
dx
b 
d
dt
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3

d
sin t 1 3  1 sin t 2 3  d sin t 
dt
3
dt

1
sin t 2 3  cos t   d t 
3
dt

1
sin t 2 3  cos t  
3
Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 24 of 39
Differentiating Cosine in Application
EXAMPLE
Suppose that a person’s blood pressure P at time t (in seconds) is given by
P = 100 + 20cos 6t.
Find the maximum value of P (called the systolic pressure) and the minimum
value of P (called the diastolic pressure) and give one or two values of t where
these maximum and minimum values of P occur.
SOLUTION
The maximum value of P and the minimum value of P will occur where the
function has relative minima and maxima. These relative extrema occur where
the value of the first derivative is zero.
This is the given function.
P  100  20 cos 6t
P  20 sin 6t 6  120sin 6t
 120 sin 6t  0
sin 6t  0
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Differentiate.
Set P΄ equal to 0.
Divide by -120.
Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 25 of 39
Differentiating Cosine in Application
CONTINUED
Notice that sin6t = 0 when 6t = 0, π, 2π, 3π,... That is, when t = 0, π/6, π/3,
π/2,... Now we can evaluate the original function at these values for t.
t
100 + 20cos6t
0
120
π/6
80
π/3
120
π/2
80
Notice that the values of the function P cycle between 120 and 80. Therefore,
the maximum value of the function is 120 and the minimum value is 80.
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 26 of 39
Application of Differentiating & Integrating Sine
EXAMPLE
(Average Temperature) The average weekly temperature in Washington, D.C. t
weeks after the beginning of the year is
 2

f t   54  23sin  t  12.
 52

The graph of this function is sketched below.
(a) What is the average weekly temperature at week 18?
(b) At week 20, how fast is the temperature changing?
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 27 of 39
Application of Differentiating & Integrating Sine
CONTINUED
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 28 of 39
Application of Differentiating & Integrating Sine
CONTINUED
SOLUTION
(a) The time interval up to week 18 corresponds to t = 0 to t = 18. The average
value of f (t) over this interval is
1 18
1 18 
 2





f
t
dt

54

23
sin
t

12

dt




0
0
18  0
18 
 52

18
1 
52
 2

 54t  23
 cos t  12 
18 
2
 52
 0
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
1
598  3   1  598   6  
972

cos    0 
cos


18 

13
18

 
 13  


1
829 .521 1  22.944  47.359 .
18
18
Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 29 of 39
Application of Differentiating & Integrating Sine
CONTINUED
Therefore, the average value of f (t) is about 47.359 degrees.
(b) To determine how fast the temperature is changing at week 20, we need to
evaluate f ΄(20).
 2

This is the given function.
f t   54  23sin  t  12
 52

 2
 2
f t   23cos t  12 
 52
 52
f t  
f 20 
Differentiate.
23


cos t  12
26
 26

Simplify.
23


cos 20  12  1.579
26
 26

Evaluate f ΄(20).
Therefore, the temperature is changing at a rate of 1.579 degrees per week.
© 2010 Pearson Education Inc.
Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 30 of 39
§ 8.4
The Tangent and Other Trigonometric
Functions
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 31 of 39
Section Outline

Other Trigonometric Functions

Other Trigonometric Identities

Applications of Tangent

Derivative Rules for Tangent

Differentiating Tangent

The Graph of Tangent
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 32 of 39
Other Trigonometric Functions
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 33 of 39
Other Trigonometric Identities
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 34 of 39
Applications of Tangent
EXAMPLE
Find the width of a river at points A and B if the angle BAC is 90°, the angle
ACB is 40°, and the distance from A to C is 75 feet.
r
SOLUTION
Let r denote the width of the river. Then equation (3) implies that
tan 40  
r
75
75 tan 40   r.
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 35 of 39
Applications of Tangent
CONTINUED
We convert 40° into radians. We find that 40° = (π/180)40 radians ≈ 0.7
radians, and tan(0.7) ≈ 0.84229. Hence
75tan40  r  750.84229  63.17 meters.
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 36 of 39
Derivative Rules for Tangent
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 37 of 39
Differentiating Tangent
EXAMPLE
Differentiate.
y  2 tan x 2  4
SOLUTION
From equation (5) we find that

d
 y   dy  d 2 tan x 2  4
dx
dx dx

 x  4  dxd  x  4 
1
d
 2 sec  x  4  x  4  x
2
dx
1
 2 sec  x  4  x  4   2 x
2
2 x sec  x  4 

.
 2 sec 2
2
2
2
2
1 2
2
2
2
1 2
2
2
2
4

2
x2  4
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 38 of 39
The Graph of Tangent
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Goldstein/Schneider/Lay/Asmar, CALCULUS AND ITS APPLICATIONS, 12e– Slide 39 of 39