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Trigonometric Ratios of Any Angle © P. A. Hunt

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1 Trigonometric Ratios of Any Angle © P. A. Hunt http://teachfurthermaths.weebly.com

2 Lesson Objectives: 1. 1.To understand what is meant by: circular functions; quadrants; positive angles; negative angles. 2. 2.To recall the main characteristics of the graphs of y = sin x, y = cos x and y = tan x. 3. 3.To consider the main trigonometric ratios in all 4 quadrants. 4. 4.To introduce and use the CAST diagram for solving simple trig. ratio problems. 5. 5.To solve simple trig. ratio problems graphically. 6. 6.To solve simple trig. ratio problems by identifying a quicker method. © P. A. Hunt

3 60 ◦ Did you know…? 1 …that a positive angle is measured in an anticlockwise direction from the positive x-axis?

4 -60 ◦ Did you know…? 2 … that a negative angle is measured in a clockwise direction from the positive x-axis?

5 Did you know…? 3 … that there are 4 quadrants, named as shown below: 1 st quadrant2 nd quadrant 4 th quadrant3 rd quadrant

6 Did you know…? 4 … that the trigonometric ratios sin x, cos x and tan x are called circular functions.

7 Can you sketch the graph of y = sin x ? Main Characteristics 1 The graph has a period of 360 ◦. 2 Sin x has a minimum value of -1 and a maximum value of 1.

8 Can you sketch the graph of y = cos x ? Main Characteristics 1 The graph has a period of 360 ◦. 2 Cos x has a minimum value of -1 and a maximum value of 1. 3 The graph is a translation of the sine graph by 90 ◦ to the left.

9 Can you sketch the graph of y = tan x ? Main Characteristics 1 The graph has a period of 180 ◦. 2 Tan x has no maximum value and no minimum value. 3 Tan x is undefined at -270 ◦, -90 ◦, 90 ◦, 270 ◦ etc.

10 Circular Functions Consider a unit circle of centre O. Consider also the line OP (shown) where P is a point on the circle in the 1 st quadrant. O P (x,y) 1 Note: Any radius will suffice but, for the sake of simplicity, we will use the unit circle. We will choose the angle between OP and the positive x-axis to be θ.

11 Circular Functions – the 1 st Quadrant O 1 Now consider the triangle OPQ. Q We will now recall the trigonometric ratios with which we are already familiar: P (x,y)

12 Circular Functions – the 1 st Quadrant O 1 Now consider the triangle OPQ. Q We will now recall the trigonometric ratios with which we are already familiar: P (x,y)

13 Circular Functions – the 1 st Quadrant O 1 Now consider the triangle OPQ. Q We will now recall the trigonometric ratios with which we are already familiar: P (x,y)

14 Circular Functions – the 1 st Quadrant O 1 Q P (x,y) Note : In the 1 st Quadrant, (i.e. for an acute angle)

15 Circular Functions – the 1 st Quadrant O 1 Q P (x,y) We will now extend these definitions to angles that lie outside of the 1st quadrant.

16 Circular Functions – the 2 nd Quadrant O 1 P (x,y) This time our angle lies in the 2 nd Quadrant. Let Φ (phi) be the acute angle between our line and the x-axis.

17 Circular Functions – the 2 nd Quadrant O 1 Q P (x,y) Using our definitions above: because x is negative So just use the ‘associated acute’ angle Φ, and note the sign.

18 Circular Functions – the 2 nd Quadrant O 1 Q P (x,y) So just use the ‘associated acute’ angle Φ, and note the sign. Note : In the 2 nd Quadrant,

19 Circular Functions – the 3 rd Quadrant This time our angle lies in the 3 rd Quadrant. O 1 P (x,y)

20 Circular Functions – the 3 rd Quadrant O 1 P (x,y) Using our definitions above: because x is negative because x and y are both negative Q because y is negative

21 Circular Functions – the 3 rd Quadrant O 1 P (x,y) Q Note : In the 3 rd Quadrant,

22 Circular Functions – the 4 th Quadrant O 1 P (x,y) This time our angle lies in the 4 th Quadrant.

23 Circular Functions – the 4 th Quadrant O 1 P (x,y) Using our definitions above: because y is negative Q

24 Circular Functions – the 4 th Quadrant O 1 P (x,y) Q Note : In the 4 th Quadrant,

25 The CAST Diagram 1 st Quadrant 0 < θ < 90 All > 0 2 nd Quadrant 90 < θ < 180 Sin > 0 4 th Quadrant 270 < θ < 360 3 rd Quadrant 180 < θ < 270 Cos > 0Tan > 0

26 The CAST Diagram 1 st Quadrant 0 < θ < 90 A 2 nd Quadrant 90 < θ < 180 S 4 th Quadrant 270 < θ < 360 3 rd Quadrant 180 < θ < 270 CT

27 50 ◦ Example 1 Find all the values of θ, where 0 ≤ θ ≤ 360, for which sin θ ◦ = sin 50 ◦ 50 ◦ lies in the 1 st quadrant. (where sin > 0) sin > 0 in the 2 nd quadrant also (draw at same angle to x-axis) Read solutions from positive x-axis 50 ◦ θ = 50 ◦ is clearly a solution

28 50 ◦ Example 1 Find all the values of θ, where 0 ≤ θ ≤ 360, for which sin θ ◦ = sin 50 ◦ θ = 50 ◦ 50 ◦ 130 ◦ θ = 130 ◦ We can see that further solutions are θ = 410 ◦, θ = 490 ◦, θ = 770 ◦, θ = 850 ◦ etc, by adding (or subtracting) multiples of 360 ◦ but these are outside of the required interval for this question.

29 Graphical Method Find all the values of θ, where 0 ≤ θ ≤ 360, for which sin θ ◦ = sin 50 ◦ y = sin θ θ θ = 50 ◦ Use the symmetry of the graph to read the required values θ = 130 ◦

30 Graphical Method Find all the values of θ, where 0 ≤ θ ≤ 360, for which sin θ ◦ = sin 50 ◦ sin θ ◦ = sin 50 ◦ y = sin θ θ θ = 50 ◦ θ = 130 ◦ Note that: All other solutions can be found by

31 A Quicker Approach Find all the values of θ, where 0 ≤ θ ≤ 360, for which sin θ ◦ = sin 50 ◦ Note that: All other solutions can be found by No other solutions in required range. The required solutions are θ = 50 ◦, θ = 130 ◦

32 120 ◦ Example 2 Find all the values of θ, where -360 ≤ θ ≤ 360, for which cos θ ◦ = cos 120 ◦ 120 ◦ lies in the 2 nd quadrant. (where cos < 0) cos < 0 in the 3 rd quadrant also (draw at same angle to x-axis) Read solutions from positive x-axis 60 ◦ θ = 120 ◦ is clearly a solution

33 120 ◦ Example 2 Find all the values of θ, where -360 ≤ θ ≤ 360, for which cos θ ◦ = cos 120 ◦ 60 ◦ θ = 120 ◦ θ = 240 ◦ 240 ◦ Subtracting 360 ◦ from each solution, θ = -240 ◦ θ = -120 ◦ The required solutions are θ = -240 ◦, θ = -120 ◦, θ = 120 ◦, θ = 240 ◦

34 Graphical Method Find all the values of θ, where -360 ≤ θ ≤ 360, for which cos θ ◦ = cos 120 ◦ y = cos θ θ θ = 120 ◦ θ = 240 ◦ θ = -120 ◦ θ = -240 ◦

35 Graphical Method y = cos θ θ θ = 120 ◦ θ = 240 ◦ θ = -120 ◦ θ = -240 ◦ Note that: All other solutions can be found by Find all the values of θ, where -360 ≤ θ ≤ 360, for which cos θ ◦ = cos 120 ◦

36 A Quicker Approach Note that: All other solutions can be found by Find all the values of θ, where -360 ≤ θ ≤ 360, for which cos θ ◦ = cos 120 ◦ The required solutions are θ = -240 ◦, θ = -120 ◦, θ = 120 ◦, θ = 240 ◦

37 60 ◦ θ = 60 ◦ θ = 240 ◦ Subtracting 360 ◦ from each solution, θ = -300 ◦ θ = -120 ◦ The required solutions are θ = -300 ◦, θ = -120 ◦, θ = 60 ◦, θ = 240 ◦ 240 ◦ Example 3 Find all the values of θ, where -360 ≤ θ ≤ 360, for which tan θ ◦ = tan 240 ◦

38 θ θ = 240 ◦ θ = 60 ◦ θ = -120 ◦ θ = -300 ◦ Example 3 Find all the values of θ, where -360 ≤ θ ≤ 360, for which tan θ ◦ = tan 240 ◦

39 θ θ = 240 ◦ θ = 60 ◦ θ = -120 ◦ θ = -300 ◦ Note that: All other solutions can be found by Example 3 Find all the values of θ, where -360 ≤ θ ≤ 360, for which tan θ ◦ = tan 240 ◦

40 A Quicker Approach Note that: All other solutions can be found by Find all the values of θ, where -360 ≤ θ ≤ 360, for which tan θ ◦ = tan 240 ◦ The required solutions are θ = -300 ◦, θ = -120 ◦, θ = 60 ◦, θ = 240 ◦

41 For each of the following, find all values of θ in the given range. Exercise All methods Quick Method All methods Quick Method All methods Quick Method All methods Quick Method All methods Quick Method

42 80 ◦ For each of the following, find all values of θ in the given range. θ = 80 ◦ θ = 100 ◦ 100 ◦ Back to questions

43 For each of the following, find all values of θ in the given range. θ θ = 100 ◦ θ = 80 ◦ Back to questions

44 A Quicker Approach Note that: All other solutions can be found by Find all the values of θ, where 0 ≤ θ ≤ 360, for which sin θ ◦ = sin 80 ◦ No other solutions in required range. The required solutions are θ = 80 ◦, θ = 100 ◦ (a) Back to questions

45 130 ◦ 50 ◦ For each of the following, find all values of θ in the given range. 50 ◦ θ = 130 ◦ θ = 230 ◦ 230 ◦ Back to questions

46 For each of the following, find all values of θ in the given range. θ θ = 130 ◦ θ = 230 ◦ Back to questions

47 A Quicker Approach Note that: All other solutions can be found by Find all the values of θ, where 0 ≤ θ ≤ 360, for which cos θ ◦ = cos 130 ◦ The required solutions are θ = 130 ◦, θ = 230 ◦ (b) Back to questions

48 60 ◦ For each of the following, find all values of θ in the given range. θ = 120 ◦ θ = 300 ◦ Subtracting 360 ◦ from the 2 nd solution, θ = -60 ◦ The required solutions are θ = -60 ◦, θ = 120 ◦, θ = 300 ◦ 300 ◦ 120 ◦ Back to questions

49 For each of the following, find all values of θ in the given range. θ θ = 300 ◦ θ = 120 ◦ θ = -60 ◦ Back to questions

50 A Quicker Approach Note that: All other solutions can be found by Find all the values of θ, where -180 ≤ θ ≤ 360, for which tan θ ◦ = tan 300 ◦ The required solutions are θ = -60, θ = 120, θ = 300 ◦ (c) Back to questions

51 80 ◦ For each of the following, find all values of θ in the given range. θ = -80 ◦ θ = -100 ◦ 80 ◦ 100 ◦ Back to questions

52 For each of the following, find all values of θ in the given range. θ θ = -80 ◦ θ = -100 ◦ Back to questions

53 A Quicker Approach Note that: All other solutions can be found by Find all the values of θ, where -180 ≤ θ ≤ 180, for which sin θ ◦ = sin (-100) ◦ The required solutions are θ = -100, θ = -80 ◦ (d) Back to questions

54 For each of the following, find all values of θ in the given range. 390 ◦ 30 ◦ 330 ◦ θ = 30 ◦ θ = 330 ◦ Adding 360 ◦ to each solution, θ = 390 ◦ θ = 690 ◦ The required solutions are θ = 30 ◦, θ = 330 ◦, θ = 390 ◦, θ = 690 ◦ Back to questions

55 For each of the following, find all values of θ in the given range. θ θ = 390 ◦ θ = 690 ◦ θ = 330 ◦ θ = 30 ◦ Back to questions

56 A Quicker Approach Note that: All other solutions can be found by Find all the values of θ, where 0 ≤ θ ≤ 720, for which cos θ ◦ = cos 390 ◦ The required solutions are θ = 30 ◦, θ = 330 ◦, θ = 390 ◦, θ = 690 ◦ (e) Back to questions

57 http://teachfurthermaths.weebly.com

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