1. Math 112 Elementary Functions Section 4 Polar Coordinates and Graphs Chapter 7 – Applications of Trigonometry

2. Rectangular (aka: Cartesian) Coordinates positive x-axisnegative x-axis positive y-axis negative y-axis x y (x, y) origin For any point there is a unique ordered pair (x, y) that specifies the location of that point.

3. Polar Coordinates polar axis (r,  ) r  pole Is (r,  ) unique for every point? NO! All of the following refer to the same point: (5, 120º) (5, 480º) (-5, 300º) (-5, -60º) etc... The angle  may be expressed in degrees or radians.

4. Polar Graph Paper Locating and Graphing Points 00 30  60  90  180  120  150  210  240  270  300  330  (5, 150  ) (6, 75  ) (3, 300  ) (3, -60  )(-3, 120  ) (-4, 30  ) (7, 0  ) (-7, 180  )

5. Converting Coordinates Polar  Rectangular x y (r,  )  (x, y)  r Recommendation: Find (r,  ) where r > 0 and 0 ≤  < 2  or 0  ≤  < 360 . Relationships between r, , x, & y R  P P  R

6. Examples: Converting Coordinates Polar  Rectangular

7. Examples: Converting Coordinates Polar  Rectangular Quadrant I

8. Examples: Converting Coordinates Polar  Rectangular Quadrant II OR

9. Examples: Converting Coordinates Polar  Rectangular Quadrant III OR

10. Examples: Converting Coordinates Polar  Rectangular Quadrant IV OR

11. Converting Equations Polar  Rectangular Use the same identities:

12. Converting Equations Polar  Rectangular x Replace all occurrences of x with r cos . y Replace all occurrences of y with r sin . Simplify r Solve for r (if possible).

13. Converting Equations Polar  Rectangular Express the equation in terms of sine and cosine only. If possible, manipulate the equation so that all occurrences of cos  and sin  are multiplied by r. Replace all occurrences of … Simplify (solve for y if possible) r cos  with x r sin  with y r 2 with x 2 + y 2 Or, if all else fails, use:

14. Graphing Polar Equations Reminder: How do you graph rectangular equations? Method 1: Create a table of values. Plot ordered pairs. Connect the dots in order as x increases. Method 2: Recognize and graph various common forms. Examples: linear equations, quadratic equations, conics, … The same basic approach can be applied to polar equations.

15. Graphing Polar Equations Method 1: Plotting and Connecting Points 1. Create a table of values. 2. Plot ordered pairs. 3. Connect the dots in order as  increases. NOTE: Since most of these equations involve periodic functions (esp. sine and cosine), at some point the graph will start repeating itself (but not always).

16. Graphing Polar Equations Method 2: Recognizing Common Forms Circles Centered at the origin: r = a radius: a period = 360  Tangent to the x-axis at the origin: r = a sin  center: (a/2, 90  ) radius: a/2 period = 180  a > 0  above a < 0  below Tangent to the y-axis at the origin: r = a cos  center: (a/2, 90  ) radius: a/2 period = 180  a > 0  right a < 0  left r = 4 r = 4 sin  r = 4 cos 

17. Graphing Polar Equations Method 2: Recognizing Common Forms Flowers (centered at the origin) r = a cos n  or r = a sin n  radius: |a| n is even  2n petals petal every 180/n  period = 360  n is odd  n petals petal every 360/n  period = 180  cos  1 st petal @ 0  sin  1 st petal @ 90/n  r = 4 sin 2  r = 4 cos 3 

18. Graphing Polar Equations Method 2: Recognizing Common Forms Spirals Spiral of Archimedes: r = k  |k| large  loose |k| small  tight r =  r = ¼ 

19. Graphing Polar Equations Method 2: Recognizing Common Forms Heart (actually: cardioid if a = b … otherwise: limaçon) r = a ± b cos  or r = a ± b sin  r = 3 + 3 cos  r = 2 - 5 cos  r = 3 + 2 sin  r = 3 - 3 sin 

20. Graphing Polar Equations Method 2: Recognizing Common Forms Lines Horizontal: y = k  r sin  = k  r = k csc  Vertical: x = h  r cos  = h  r = h sec  Others: ax + by = c  y = mx + b 

21. Graphing Polar Equations Method 2: Recognizing Common Forms Parabolas (w/ vertex on an axis) NOTE: With these forms, the vertex will never be at the origin.