Algebra 2 Honors: Trigonometry Semester 2, Unit 6: Activity 31 Resources: SpringBoard- Algebra 2 Online Resources: Algebra 2 Springboard Text Unit 6 Vocabulary: Arc length Unit circle Radian Standard position Initial side Terminal side Coterminal angles Reference angle Trigonometric function Periodic function Period Amplitude Midline Phase shift Unit Overview In this unit, students build on their knowledge of trigonometry from geometry and extend it to radian measure and the unit circle. Students will apply trigonometric functions to understanding real-world periodic phenomena. Student Focus Main Ideas for success in lessons 31-1 & 31-2 Introduce students to radian measurement Use a real-world problem to develop understanding of radian measure and how it differs from degree measure Example: Lesson 31-1: Vocabulary: The arc length is the length of a portion of the circumference of a circle. The arc length is determined by the radius of the circle and by the angle measure that defines the corresponding arc, or portion, of the circumference. When you find the arc length generated by a radius on a circle with radius 1, it is called a unit circle. On a unit circle, the constant of proportionality is the measure of the angle of rotation written in radians, which equals the length of the corresponding arc on the unit circle. Page 1 of 36
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Algebra 2 Honors: Trigonometry Semester 2, Unit 6: Activity 31
Resources:
SpringBoard-
Algebra 2
Online
Resources:
Algebra 2
Springboard Text
Unit 6
Vocabulary:
Arc length
Unit circle
Radian
Standard position
Initial side
Terminal side
Coterminal angles
Reference angle
Trigonometric function
Periodic function
Period
Amplitude
Midline
Phase shift
Unit Overview
In this unit, students build on their knowledge of trigonometry from geometry and extend it to radian measure and the unit circle. Students will apply trigonometric functions to understanding real-world periodic phenomena.
Student Focus
Main Ideas for success in lessons 31-1 & 31-2
Introduce students to radian measurement
Use a real-world problem to develop understanding of radian measure and how it differs from degree measure
Example:
Lesson 31-1: Vocabulary:
The arc length is the length of a portion of the circumference of a circle. The arc length is determined by the radius of the circle and by the angle measure that defines the corresponding arc, or portion, of the circumference.
When you find the arc length generated by a radius on a circle with radius 1, it is called a unit circle. On a unit circle, the constant of proportionality is the measure of
the angle of rotation written in radians, which equals the length of the corresponding arc on the unit circle.
Example A: A toy train travels 30° around a circular track with a radius of 8 feet. What is the constant of proportionality that can be used to find the distance along the track that the train travels?
a)
b)
c)
d)
Convert radians to degrees multiply radians by the ratio
Convert degrees to radians multiply degree by the ratio
Lesson 31-2: Example A: A Ferris wheel makes one complete rotation every 4 minutes. How far, to the nearest tenth, will a rider who is seated 40 feet from the center travel in 10 minutes?
a) 15.7 feet b) 200 feet c) 251.3 feet
d) 628.3 feet
Example B: What is 150° in radians?
Page 2 of 36
Algebra 2 Honors: Trigonometry Semester 2, Unit 6: Activity 32
Resources:
SpringBoard-
Algebra 2
Online
Resources:
Algebra 2
Springboard Text
Unit 6
Vocabulary:
Arc length
Unit circle
Radian
Standard position
Initial side
Terminal side
Coterminal angles
Reference angle
Trigonometric function
Periodic function
Period
Amplitude
Midline
Phase shift
Unit Overview
In this unit, students build on their knowledge of trigonometry from geometry and extend it to radian measure and the unit circle. Students will apply trigonometric functions to understanding real-world periodic phenomena.
Student Focus
Main Ideas for success in lessons 32-1 & 32-2
Calculate trigonometric ratios for acute angles using the ratios of the sides of a right triangle
Use reference angles and the unit circle to find trigonometric ratios of any angle
Example:
Lesson 32-1: Vocabulary: An angle is in standard position when the vertex is placed at the origin and the initial side is on the positive x-axis. The other ray that forms the angle is the terminal side.
Draw an angle in standard position with a measure of 120°.
Since 120° is 30° more than 90°, the terminal side is 30° counterclockwise from the positive y-axis.
Draw an angle in standard position with a measure of -200°.
Since -200° is negative, the terminal side of 200° clockwise from the positive x-axis.
Draw and angle in standard position with a measure of
radians.
Since
is greater than radians, the terminal side makes one full rotation, plus an
additional
radians.
Find one positive and one negative angle that are coterminal with each given angle.
If θ is an angle in standard position, its reference angle α is the acute angle formed by the terminal side of θ and the x-axis. The graphs show the reference angle α for four different angles that have their terminal sides in different quadrants.
Page 4 of 36
The relationship between θ and α is shown for each quadrant when 0° < θ < 360° or 0 < θ < 2π.
Quadrant I Quadrant II Quadrant III Quadrant IV
QUESTION: Find the reference angle for . ANSWER: The terminal side of θ lies in Quadrant III, therefore so .
QUESTION: Find the reference angle for
.
When an angle is not between 0 and 360° ( ), find a coterminal angle that is within that range. Then use the coterminal angle to find the reference angle.
ANSWER: The terminal side of θ lies in Quadrant II, therefore
so
.
QUESTION: Find the reference angle for . Since 435° is greater than 360°, subtract . Now determine the reference angle for 75°. ANSWER: Since 75° is in Quadrant I, the reference angle is 75°.
Page 5 of 36
QUESTION: Find the reference angle for
radians.
Since
is greater than , subtract
ANSWER: The terminal side of this angle is in Quadrant III so
,
so
.
QUESTION: Find the sine and cosine of 90°
QUESTION: Find the sine and cosine of 180°.
Page 6 of 36
Lesson 32-2:
QUESTION: What are the sine and cosine of θ when ?
The sine and cosine are the lengths of the legs of a triangle.
If θ is not in the first quadrant, use a reference angle. ANSWER:
length of shorter leg
length of longer leg
QUESTION: What are sinθ and cosθ when
radians?
Page 7 of 36
Unit Circle:
Page 8 of 36
Page 9 of 36
Algebra 2 Honors: Trigonometry Semester 2, Unit 6: Activity 33
Resources:
SpringBoard-
Algebra 2
Online
Resources:
Algebra 2
Springboard Text
Unit 6
Vocabulary:
Arc length
Unit circle
Radian
Standard position
Initial side
Terminal side
Coterminal angles
Reference angle
Trigonometric function
Periodic function
Period
Amplitude
Midline
Phase shift
Unit Overview
In this unit, students build on their knowledge of trigonometry from geometry and extend it to radian measure and the unit circle. Students will apply trigonometric functions to understanding real-world periodic phenomena.
Student Focus
Main Ideas for success in lessons 33-1 & 33-2:
Use Pythagorean Theorem to prove the Pythagorean Identity,
Use the Pythagorean Identity to find given the value of
one of those functions and the quadrant of θ.
Combine the Pythagorean Identity with the reciprocal identities to prove related Pythagorean identities.
Unit Overview In this unit, students build on their knowledge of trigonometry from geometry and extend it to radian measure and the unit circle. Students will apply trigonometric functions to understanding real-world periodic phenomena.
Student Focus
Main Ideas for success in lessons 34-1, 34-2, 34-3, 34-4, & 34-5:
Analyze, graph, and write equations for parent trigonometric functions and their transformations, including phase shifts
Identify period, midline, amplitude, and asymptotes
Main Idea for success in lesson 35-1:
Using knowledge of trigonometric functions and their graphs, model real-world periodic phenomena using functions of the form or
y = a sin b(x h) + k y = a cos b(x h) + k y = a tan b(x h) + k
a The coefficient changes the amplitude of the sine and cosine functions.
When a > 1, the amplitude increases and the graph is stretched vertically.
When 0 < a < 1, the amplitude decreases and the graph is compressed vertically.
When a < 0, the graph is reflected across the x-axis.
b The coefficient changes the period.
When b > 1, the period decreases and the graph is compressed horizontally.
When 0 < b < 1, the period increases and the graph is stretched horizontally.
The period of sin bx and cos bx is 2πb.
The period of tan bx is πb.
h The constant shifts the graph horizontally.
When h > 0, the graph shifts to the right.
When h < 0, the graph shifts to the left.
k The constant shifts the graph vertically.
When k > 0, the graph shifts up.
When k < 0, the graph shifts down.
Page 27 of 36
Lesson 35-1:
Example 1: Hector’s skateboard wheels have a diameter of 80 millimeters. When he starts riding, a small chip in one wheel is visible at the top of the wheel. As he rides, the wheels make 6 revolutions per second. What is the function that gives the height h in millimeters of the chip in the wheel as a function of time t in seconds?
Example 2:
The tide at Lookout Point is modeled by
, giving
height h in feet as a function of time t in hours since low tide.
Which describes the heights of low and high tide and the time in between them?
LeSSon 31-1 1. Going around a circle you travel the length of an
arc formed by a 45° angle. If the distance you travel is 20 m, what is the radius of the circle?
2. Make sense of problems. Two people are sitting in different locations on a merry-go-round. The first person sits 4 m from the center of the ride and the second person sits 6 m from the center of the ride. How much farther has the second person traveled than the first person when they complete a turn?
3. Write the constant of proportionality for each of the following angles in a unit circle. Express your answers in terms of p.
a. 3°
b. 18°
c. 54°
d. 99°
4. Which of the following constants of proportionality in a unit circle is paired with its corresponding angle?
A. 119p , 20° B. 4
8p , 90°
C. 25p , 24° D. 14
9p , 280°
5. Reason quantitatively. A passenger sits 20 m from the center of a Ferris wheel and travels a quarter of a turn. What is an accurate estimate of the distance traveled in meters?
LeSSon 31-2 6. Convert the following angle measures from radians
to degrees.
a. 27p
b. 38p
c. 3.14159
d. 5
7. Make sense of problems. The measure of linear velocity is meters per second and the measure of angular velocity is radians per second. Angular velocity describes how fast an object in circular motion travels in terms of the angle measure of the arc (in radians) that the object travels in a second. If you are on a merry-go-round sitting 4 m from the center and you travel
9p
radians per second, what is your linear velocity? In other words, what is the length of the arc that you travel every second?
8. Model with mathematics. Come up with a general formula to convert angular velocity v to linear velocity v in terms of the radius r.
9. It takes a Ferris wheel 12 minutes to complete a turn. How many radians does it turn every minute?
A. 0.48 B. 0.52
C. 27p
D. 95p
10. A Frisbee rotates 40 times every two seconds. How many radians does it rotate every second?
A. 127p B. 20p
C. 40p D. 10p
LeSSon 32-1 11. Which of the following angle pairs are coterminal
angles?
A. p p
254
,54
B. 54
,4
p p2
C. 94
,34
p p2 D.
94
,74
p p2
12. Which of the following angle pairs are coterminal with 33°?
A. 213°, 22147° B. 7130
,4930
p p2
C. 393°, 2327° D. p p
27160
, 4960
13. Reason quantitatively. Are angles measuring
88° and 6845
p2 radians coterminal? Explain your
answer.
14. Make sense of problems. Imagine looking at a Ferris wheel from the side so that we can divide it into four quadrants. A passenger starts at the very bottom of the Ferris wheel, and the Ferris wheel makes a complete turn counterclockwise every 10 minutes. What quadrant will the passenger be in at 14 minutes? Explain.
15. What are the reference angles for the following angles?
a. 78°
b. 268°
c. 38p
LeSSon 32-2 16. Find the sine of each of the following angles.
a. 585°
b. 750°
c. 240°
17. Find the cosine of each of the following angles.
19. Reason abstractly. The sum of the internal angles of a triangle is 180°. If a right triangle has one angle that is 45°, what can be deduced about the length of the two shorter sides of the triangle?
20. express regularity in repeated reasoning. Complete the following table.
0° 30° 45° 60° 90°
sine 02
12 2 2 2
cosine 42
32 2 2 2
tangent
LeSSon 33-1 21. Given that 0 , u ,
2,p find the value of cos u for
each of the given values of sin u.
a. sin u 5 58
b. sin u 5 14
c. sin u 5 37
22. Given that 0 , u , 2,p find the value of sin u for
each of the given values of cos u.
a. cos u 5 23
b. cos u 5 17
c. cos u 5 47
23. Given that sin u 5 38
, and 0 , u , 2,p what are
the values of cos u and tan u?
A. cos u 5 558
and tan u 5 3 55
55
B. cos u 5 2558
and tan u 5 23 55
55
C. cos u 5 2 58
and tan u 5 255 3
3
D. cos u 5 22 5
8 and tan u 5
55 33
24. Reason abstractly. Why can the value of the tangent function exceed 1 when the values of the sine and cosine functions cannot?
25. Make sense of problems. A right triangle has a hypotenuse of length 8 m. If one of the angles of the triangle is 30°, what are the lengths of the other two sides of the triangle?
LeSSon 33-2 26. Simplify the following expression.
27. Simplify the following expression. sin2 u 2 tan u cot u
28. Given that sin u 5 23
, 0 , u , 2
,p what are the
values of cos u and sec u?
A. cos u 5 5
3 and sec u 5
35
B. cos u 5 3 5
5 and sec u 5
53
C. cos u 5 3 5
52 and sec u 5
53
2
D. cos u 5 5
32 and sec u 5
3 55
2
29. Reason abstractly. The cosecant, secant, and tangent functions are the reciprocals of the sine, cosine, and tangent functions respectively. What is always the product of the multiplication of each of these functions by its reciprocal?
30. Make sense of problems. Does sin2 x 2 (cos x) (sec x) 5 sin2 x 2 1? Explain your answer.
LeSSon 34-1 31. Is this graph a periodic function? If so, find the
amplitude. The maximum value of the function is 7 and the minimum value is 27.
x
y
25210
210
25
5
10
5 10
32. Is this graph a periodic function? If so, find the amplitude. The maximum value of the function is 39 and the minimum value is 25.
LeSSon 34-5 51. List the amplitude and period and describe the
horizontal and vertical shifts relative to the parent
function of y 5 3 sin 4
x
6p
1 2 1.
52. List the amplitude and period and describe the horizontal and vertical shifts relative to the parent
function of y 5 35
cos 2
x 2
3p
2 1 4.
53. Which are the features of the graph of
y 5 52
tan 3
x 3
2p
2 1 4?
A. amplitude: 52
, period: 3
,p horizontal shift:
32p right, vertical shift: 4 up
B. period: 3
,p horizontal shift:
32p
right,
vertical shift: 4 up
C. amplitude: 52
, period: 3
,p horizontal shift:
32p
left, vertical shift: 4 up
D. period: 3
,p horizontal shift:
32p
right,
vertical shift: 4 down
54. Reason abstractly. The function y 5 cot x is the reciprocal of the function y 5 tan x. Describe how the graph of y 5 cot x compares to the graph of y 5 tan x.
LeSSon 35-1 56. Write a trigonometric function that describes the
height as a function of time of a car on a Ferris wheel that makes a complete rotation every 2 minutes. The radius of the Ferris wheel is 25 m and at its highest point the car is 60 m high.
57. Attend to precision. What is the height of the car in Item 56 after 7 minutes and 12 seconds?
58. Make sense of problems. What is the height of the car in Item 56 at its lowest point?
59. A car engine is running at 6000 revolutions (turns) per minute. Which of the following could describe the position of a point on a gear attached directly to the engine as a function of time t in seconds?
A. h(t) 5 0.3 sin
t
6000p
1 1
B. h(t) 5 0.3 sin (200pt)
C. h(t) 5 0.3 sin
t
606000
p 1 1
D. h(t) 5 0.3 sin
t
6000p
60. The distance of an object from the ground in meters can be expressed as a function of time in seconds
by the function h(t) 5 7 cos
t
27p
1 400. What is
the maximum height of this object, and when does the object reach that height for the first time?