1. Trigonometric Functions of Any Angle & Polar Coordinates
MAT 205 SPRING 2009
Sections 8.1, 8.2, 8.3, 21.10
Trigonometric Functions of Any Angle & Polar Coordinates

2. Definitions of Trigonometric Functions of Any Angle
Definitions of Trig Functions of Any Angle
(Sect 8.1)
Definitions of Trigonometric Functions of Any Angle
Let  be an angle in standard position with (x, y) a point on the terminal side of  and y x 
(x, y) r

3. The Signs of the Trig Functions
Since the radius is always positive (r > 0), the signs of the trig functions are dependent upon the signs of x and y. Therefore, we can determine the sign of the functions by knowing the quadrant in which the terminal side of the angle lies.

4. The Signs of the Trig Functions

5. “All Students Take Calculus”
To determine where each trig function is POSITIVE:
“All Students Take Calculus” A C T S
Translation:
A = All 3 functions are positive in Quad 1
S= Sine function is positive in Quad 2
T= Tangent function is positive in Quad 3
C= Cosine function is positive in Quad 4
*In Quad 2, sine is positive, but cosine and tangent are negative; in Quad 3, tangent is positive, but sine and cosine are negative; in Quad 4, cosine is positive but sine and tangent are negative.
**Reciprocal functions have the same sign. So cosecant is positive wherever sine is positive, secant is positive wherever cosine is positive, and cotangent is positive wherever tangent is positive.

6. Example Determine if the following functions are positive or negative:
1) sin 210°
2) cos 320°
3) cot (-135°)
4) csc 500°
5) tan 315°

7. Examples
For the given values, determine the quadrant(s) in which the terminal side of θ lies.

8. Examples
Determine the quadrant in which the terminal side of θ lies, subject to both given conditions.

9. Examples
Find the exact value of the six trigonometric functions of θ if the terminal side of θ passes through point (3, -5).

10. Reference Angles (Sect 8.2)
The values of the trig functions for non-acute angles can be found using the values of the corresponding reference angles.
Definition of Reference Angle
Let  be an angle in standard position. Its reference angle is the acute angle formed by the terminal side of  and the horizontal axis.
Quadrant II
Quadrant III
Quadrant IV

11. Example Find the reference angle for Solution  y
MAT 205 SPRING 2009
Example
Find the reference angle for
Solution y x 
By sketching  in standard position, we see that it is a 3rd quadrant angle. To find , you would subtract 180° from 225 °.

12. So what’s so great about reference angles?
Well…to find the value of the trig function of any non-acute angle, we just need to find the trig function of the reference angle and then determine whether it is positive or negative, depending upon the quadrant in which the angle lies.
For example,
In Quad 3, sin is negative
45° is the ref angle

13. Example
Give the exact value of the trig function (without using a calculator).

14. Examples (Text p 239 #6)
Express the given trigonometric function in terms of the same function of a positive acute angle.

15. Examples (Text p 239 #8)
Express the given trigonometric function in terms of the same function of a positive acute angle.

16. Now, of course you can simply use the calculator to find the value of the trig function of any angle and it will correctly return the (approximate) answer with the correct sign.
Remember:
Make sure the Mode setting is set to the correct form of the angle: Radian or Degree
To find the trig functions of the reciprocal functions (csc, sec, and cot), use the  button or enter [original function] .

17. Evaluate . Round appropriately.
Example
Evaluate Round appropriately.
Set Mode to Degree
Enter:  OR 

18. HOWEVER, it is very important to know how to use the reference angle when we are using the inverse trig functions on the calculator to find the angle because the calculator may not directly give you the angle you want.
Example: Find the value of  to the nearest 0.01° r -5 y x 
(-12, -5)
-12

19. Examples

20. Examples

21. Examples

22. Examples

23. BONUS PROBLEM

24. SUPER DUPER BONUS PROBLEM

25. Trig functions of Quadrantal Angles
To find the sine, cosine, tangent, etc. of angles whose terminal side falls on one of the axes , we will use the circle.
(1, 0)
(-1, 0)
(0, -1) 0
(0, 1)
Unit Circle:
Center (0, 0)
radius = 1
x2 + y2 = 1

26. Now using the definitions of the trig functions with r = 1, we have:

27. Example Find the value of the six trig functions for (0, 1) (-1, 0)
(1, 0)
(0, 1)
(-1, 0)
(0, -1) 0 

28. Example Find the value of the six trig functions for
MAT 205 SPRING 2009
Example
Find the value of the six trig functions for

29. Example Find the value of the six trig functions for
MAT 205 SPRING 2009
Example
Find the value of the six trig functions for

30. Radian Measure (Sect 8.3) Definition of Radian:
A second way to measure angles is in radians.
Definition of Radian:
One radian is the measure of a central angle  that intercepts arc s equal in length to the radius r of the circle.
In general, for  in radians,

31. Radian Measure

32. Radian Measure

33. Conversions Between Degrees and Radians
To convert degrees to radians, multiply degrees by
To convert radians to degrees, multiply radians by
Example
Convert from degrees to radians: 210º

34. Conversions Between Degrees and Radians
Example
a) Convert from radians to degrees:
b) Convert from radians to degrees: (to nearest 0.1°)

35. Conversions Between Degrees and Radians
c) Convert from degrees to radians (exact):
d) Convert from radians to degrees (exact):

36. Conversions Between Degrees and Radians
Again!
e) Convert from degrees to radians (to 3 decimal places):
f) Convert from radians to degrees (to nearest tenth): 1 rad

37. Examples
Hint: There are two answers. Do you remember why?

39. Polar Coordinates (Sect 21.10)
A point P in the polar coordinate system is represented by an ordered pair
If , then r is the distance of the point from the pole.
 is an angle (in degrees or radians) formed by the polar axis and a ray from the pole through the point.

40. Polar Coordinates
If , then the point is located units on the ray that extends in the opposite direction of the terminal side of .

41. Example
Plot the point P with polar coordinates

42. MAT 205 SPRING 2009
Example
Plot the point with polar coordinates 4

43. Plotting Points Using Polar Coordinates
MAT 205 SPRING 2009
Plotting Points Using Polar Coordinates

44. Plotting Points Using Polar Coordinates

45. A) B) D) C)

46. MAT 205 SPRING 2009
To find the rectangular coordinates for a point given its polar coordinates, we can use the trig functions.
Example

48. MAT 205 SPRING 2009
Likewise, we can find the polar coordinates if we are given the rectangular coordinates using the trig functions.
Example:
Find the polar coordinates (r, θ) for the point for which the rectangular coordinates are (5, 4). Express r and θ (in radians) to three sig digits.
(5, 4)

49. Conversion from Rectangular Coordinates to Polar Coordinates
If P is a point with rectangular coordinates (x, y), the polar coordinates (r, ) of P are given by P
You need to consider the quadrant in
which P lies in order to find the value of .

50. Find polar coordinates of a point whose rectangular coordinates are given. Give exact answers with θ in degrees.

51. Find polar coordinates of a point whose rectangular coordinates are given. Give exact answers with θ in degrees.

52. 5: Returns value of r given rectangular coordinates (x, y)
MAT 205 SPRING 2009
The TI-84 calculator has handy conversion features built-in. Check out the ANGLE menu.
5: Returns value of r given rectangular coordinates (x, y)
6: Returns value of  given rectangular coordinates (x, y)
7: Returns value of x given polar coordinates (r, )
8: Returns value of y given polar coordinates (r, )
Check the MODE for the appropriate setting for angle measure (degrees vs. radians).

53. MAT 205 SPRING 2009
End of Section