## Notes - 10.8.docx - Section 2: Explore

# Polar Equations of Conics - Day 1 of 2

Lesson 8 of 12

## Objective: SWBAT graph conic sections that are in polar form.

*45 minutes*

#### Launch

*10 min*

The purpose of today's lesson is to think about how we can write the **equations for conic sections in polar form** instead of the rectangular form that they are used to. One change I establish right away is that the focus of the conic section will be located at the polar origin instead of the center.

**Eccentricity is an important part of this lesson** so I give students this notes worksheet and have them work on #1-3 with their table group. After a few minutes we share out to make sure that they recall this key concept. I also want them to realize that eccentricity is between 0 and 1 for an ellipse, equal to 1 for a parabola, and greater than 1 for a hyperbola. This will help us identify the type of conic section when it is written in polar form.

#### Resources

*expand content*

#### Explore

*25 min*

**Teacher Note:** Here is a teacher copy of the notes so you can see what my intents are for this exploration. This will be a whole-class discussion so that we can efficiently derive the polar form of a conic section.

After we review eccentricity, I explain to students that a parabola is not the only conic section that has a directrix and that all of them can be defined in this way. On page 2 and 3 I **sketch the focus and directrix of each conic section** and explain that PF/PQ in each case will equal the eccentricity of the conic.

Then, we can use that fact to **derive a general formula **for an ellipse in polar form. I outline the process in the video below.

After this, I explain that this general formula might change depending on whether the conic is horizontal or vertical and where the directrix is located. Then I show the different forms on page 4 and explain what each formula represents.

*expand content*

#### Extend

*10 min*

After we come up with this general form, I will have students give #1 and #2 on the last page a try as their homework. Before they get started, I will ask them how it looks different than the formula we just derived and they usually notice that there is a 3 in the denominator instead of a 1. Once they realize this I ask a student what we should do and they suggest dividing everything by 3 to make it a 1.

At this point I will turn them loose and let the students work on these problems for the rest of class. Here are **some hints I give if students get stuck**:

- If they are putting the center at the origin, I will remind them that for the polar equation the focus is at the origin.
- If they don't know what type of conic it is, I will ask what the eccentricity is and see if that will help them determine the type.
- If they don't know how to graph it, I will suggest that they plug in very easy points in order to get a rough sketch of the conic.

#### Resources

*expand content*

- UNIT 1: Functioning with Functions
- UNIT 2: Polynomial and Rational Functions
- UNIT 3: Exponential and Logarithmic Functions
- UNIT 4: Trigonometric Functions
- UNIT 5: Trigonometric Relationships
- UNIT 6: Additional Trigonometry Topics
- UNIT 7: Midterm Review and Exam
- UNIT 8: Matrices and Systems
- UNIT 9: Sequences and Series
- UNIT 10: Conic Sections
- UNIT 11: Parametric Equations and Polar Coordinates
- UNIT 12: Math in 3D
- UNIT 13: Limits and Derivatives

- LESSON 1: The Stolen Car and Keys: An Introduction to Parametric Equations
- LESSON 2: Converting Parametric Equations
- LESSON 3: A New Way to Locate Points
- LESSON 4: Polar Distance Formula
- LESSON 5: Graphing Polar Equations
- LESSON 6: Limaçons and Roses - Day 1 of 2
- LESSON 7: Limaçons and Roses - Day 2 of 2
- LESSON 8: Polar Equations of Conics - Day 1 of 2
- LESSON 9: Polar Equations of Conics - Day 2 of 2
- LESSON 10: Unit Review: Parametric Equations and Polar Coordinates
- LESSON 11: Unit Review Game: Trashball
- LESSON 12: Unit Assessment: Parametric Equations and Polar Coordinates