1. Warm-up: Find the six trig ratios for a –240˚ angle.

2. Unit 7: “A Little Triggier…” Chapter 6: Graphs of Trig Functions In this chapter we will answer… What exactly is a radian? How are radians related to degrees? How do I draw and use the graphs of trig functions and their inverses? What do I do to find the amplitude, period, phase shift and vertical shift for trig functions? When trig functions be used to model a given situation?

3. 7.1: find exact values of trigonometric functions (6-1) 7.2: find length of intercepted arcs and area of sectors (6-1) In this section we will answer… What exactly is a radian and why the pi? Can I switch between radians and degrees? If they both measure angles why do I need to learn radians at all? How can I determine the length of an arc and the area of a sector?

4. What exactly is a radian and why the pi? What is a degree? Radians are based on the circumference of the circle. Radian measurements are usually shown in terms of π. Radians are unitless. No unit or symbol is used.

5. Degree/Radian Conversions

6. Converting back and forth… Change 115º to a radian measure in terms of pi. Change radians to degree measure.

7. Learning the standard angles in radians:

8. 45º- 45º- 90º

9. 30º- 60º- 90º

10. The Unit Circle

11. Finding Trig Ratios with Radian Measures: Memorize the radian measures. Force yourself to think in and recognize radian measure without having to convert to degrees.

12. Evaluate each expression:

14. Arc Length(s): s = rθ θ must be a central angle measured in radians θ s r

15. Try one… The Swiss have long been highly regarded as the makers of fine watches. The central angle formed by the hands of a watch on “12” and “5” is 150º. The radius of the minute hand is cm. Find the distance traversed by the end of the minute hand to the nearest hundredth of a cm. 1.96 cm

16. Area of a Sector: s = ½ r 2 θ θ must be a central angle measured in radians θ s r

17. Find the area of the sector with the following central angle and radius:

18. A sector has an arc length of 15 feet and a central angle of radians. Find the radius of the circle. Find the area of the sector.

19. A Mechanics Problem: A single pulley is being used to pull up a weight. Suppose the diameter of the pulley is 2.5 feet. How far will the weight rise if the pulley turns 1.5 rotations? Find the number of degrees the pulley must be rotated to raise the weight 4.5 feet.

20. Homework: p 348 #17 – 55 odd and 59. Portfolio 6 due on Thursday Unit 7 Test probably next Tuesday

22. Homework:

23. 7.3: use the language of trigonometric graphing to describe a graph (6-3) 7.4: graph sine and cosine functions from equations (6-3) In this section we will answer… What does it mean for a function to be periodic? How do we determine the period of a function? How are sine and cosine functions alike? Different? How can I use a periodic graph to determine the value of the function for a particular domain value? How do I tell whether a graph is a sine or cosine function?

24. What does it mean for a function to be periodic?

25. Periodic Functions: If the values of a function are repeated over each given interval of the domain, the function is said to be PERIODIC.

26. What do we know about sine and cosine?

27. Sine and Cosine as Functions: Let’s graph sine!

28. Properties of the sine function: Period: Domain: Range: x-intercepts: y-intercept: Maximum value: Minimum value:

29. Using the graph to determine a function value: Find using the graph of the sine function.

30. Using the graph to determine a function value: Find all the values of θ for which.

31. Using the graph to determine a function value:

33. Now let’s graph cosine!

34. Properties of the cosine function: Period: Domain: Range: x-intercepts: y-intercept: Maximum value: Minimum value:

35. How are sine and cosine alike? Different?

36. Using the graph to determine a function value: Find

37. Using the graph to determine a function value:

38. How do I tell whether a graph is a sine or cosine function?

39. Using sine and cosine functions: p 365 #53

40. Partner Work: All work done on one piece of paper. 1 st person solves a problem. The 2 nd person coaches or encourages as needed. When the 2 nd person agrees with the solution they initial the problem. Now 2 nd person solves and 1 st coaches, encourages and initials. p 363 #1-12 all

41. Homework: P 363 #13 – 39 odd, 53 and 55 Portfolio 6 due Thursday. Unit 6 reassessments due on Friday. Unit 7 Test Tuesday.

43. Homework:

44. 7.3: use the language of trigonometric graphing to describe a graph (6-4) 7.4: graph sine and cosine functions from equations (6-4) In this section we will answer… Can the period of a function change? How can I determine the period of a function from its equation? What is amplitude? What causes a change in amplitude? If I know the type of function, its period and amplitude, how do I find the equation? Can I find the equation for a function from just its graph?

45. Let’s sketch our functions…

46. Let’s graph y = sin x on our calculators…in radians!

47. Check y = cos x …in degrees!

48. Amplitude:

49. Let’s move the constant…

50. Period

51. Did you know? Frequency is related to period. Period is the amount of time to complete one cycle. Frequency is the number of cycles per unit of time.

52. State the amplitude, period and frequency for each function then sketch the graph. A = Period = or Frequency =

53. State the amplitude, period and frequency for each function then sketch the graph. A = Period = or Frequency =

54. State the amplitude, period and frequency for each function then sketch the graph. A = Period = or Frequency =

55. Okay, think about this… A negative multiplying the function will reflect the function about the x-axis.

56. Build your own function… Write the equation of the sine function with the given amplitude and period.

57. Build your own function… Write the equation of the cosine function with the given amplitude and period.

58. Now build the equation… from a graph! p 374

59. Group Work: You will receive cards with 3 different categories:  Type of graph: sine or cosine  Amplitude and Reflection about x-axis:  Period: Choose one card from each category. Build an equation that meets the specifications. Sketch the graph.

60. Homework: P 373 #17 – 53 odd, 57, 59 Quiz! Quiz!

61. Warm-up:

62. Homework:

63. 7.3: use the language of trigonometric graphing to describe a graph (6-5) 7.4: graph sine and cosine functions from equations (6-5) In this section we will answer… Can we shift our functions vertically? Horizontally? If I move a function horizontally how do I tell whether it is sine or cosine? What is a compound function? How do I sketch one?

64. Adding or Subtracting a Constant from the Function:

65. Let’s sketch a few…

66. What if we have a constant inside the function with θ?

67. Sketch some…

68. …then put it all together!

69. Build an equation:

70. Compound Functions: The sum or products of trig functions.

71. Homework: P383 #15 – 41 odd Quiz! Test! Tuesday

72. Warm-up: Graph 2 periods of each:

73. Homework:

74. 7.5: use sine and cosine graphs to model real-world data (6-6) In this section we will answer… Can trig functions be used to model real world situations? How would I translate data into a function? How accurate will my predictions be?

75. Can trig functions be used to model real world situations? Of course! Would have been a mighty short section if they couldn’t! When would I use them? Whenever data shows fairly strong periodic behavior of some kind, try to fit it to a Trig Function.

76. How would I translate data into a function?

77. How accurate will my predictions be?

78. Let’s Do It!!!

79. Homework: p 391 to 393 # 7, 9, 11, 15

81. Homework:

82. 7.6: graph secant, cosecant, tangent, and cotangent functions from equations (6-7) In this section we will answer… What about the other trig functions? How do they resemble sine and cosine? How do they differ? How do I write equations based on the other trig functions?

83. The Tangent Function Period: Domain: Range: X-intercepts (zeros): Y-intercept: Asymptotes:

84. Let’s graph a couple…

85. The Cotangent Function Period: Domain: Range: X-intercepts (zeros): Y-intercept: Asymptotes:

86. Graph one…

87. The Cosecant Function  Period:  Domain:  Range:  X-intercepts (zeros):  Y-intercept:  Asymptotes:  Maximum:  Minimum:

88. Try this…

89. The Secant Function  Period:  Domain:  Range:  X-intercepts (zeros):  Y-intercept:  Asymptotes:  Maximum:  Minimum:

90. Last one…

93. Homework: P 400 #13 – 41 odd and 47 Unit 7 Test Tuesday Portfolio 7 due on Friday