## Exit Ticket 4-Column Data Tables.16.png - Section 4: Closing

# 4-Column Quadratic Data Tables

Lesson 6 of 17

## Objective: SWBAT describe patterns in data tables that show quadratic functions as the product of two linear factors. SWBAT find equations to fit these data tables.

## Big Idea: What is going on in these new data tables? Students develop understanding of quadratic functions by looking at 4-column data tables and finding patterns.

*85 minutes*

#### Warm-Up

*30 min*

My goal today, as usual, is to move from the concrete/real-world to the abstract/mathematical. In prior lessons, students developed three-column data tables based on the profit maximization problems and then used these tables to generate quadratic functions. The limitation in these cases was that all of the functions had an *x*-intercept of 0 because with a cost of $0 the profit would also be $0. Today, we will use four-column data tables to extend the same idea to a parabola that does not have 0 as an *x*-intercept.

My students will really want hints and instruction about the first data table—they ask, “What are we supposed to do?” I find that the open-endedness of this task actually makes students more willing to get started, because I answer all the questions this way:

- “
*Well, we haven’t learned this yet, so just see what you can figure out*.”

When they say something like, “Why does this data table have 4 columns?” I say, “That is a great observation when you compare this to last week’s problems. What do you think is going on here?”

In a typical class, students come up with a lot of different ways of looking at these tables. Eventually, I tell them to treat the first column as the *x*-column and to find rules for each of the other columns in terms of this column. When students enter this data into the computer, they will find that it generates two lines and a parabola, which is shown on the graph on the second page. (Note: this is not the same data, but the same type of data). It is interesting to talk with the class about *why* the data looks like this way. Leaving the conversation loosely structured and informal allows students to stay engaged without worrying about whether their answers are *right*.

**Teaching Note**: Throughout this warm-up I try to encourage students who want more confirmation to find a way to check their answers using the online graphing calculator.

*expand content*

#### Making Connections

*15 min*

The Making Connections task is pretty quick, but I like to take the time to highlight some of the key connections between the data table and the graph. These include:

- The left-hand column represents the
*x*-coordinates for each function, while the other columns represent the*y*-coordinates. - The middle two columns both increase at a constant rate, which is why the graph shows two linear functions.
- The fourth column is the product of the two middle columns, so it shows a parabola.
- The
*x*-intercepts of the lines correspond to the*x*-intercepts of the parabola because if one of the factors is 0 the product will be 0 as well.

With some prompting, students should be able to generate these statements, or at least explain them, so it is worth taking the time to facilitate this by asking students to come up with ideas and then share some of those ideas with the class.

**Teaching Notes:**

- Note that there are two problems here, one in which both the lines have a slope of 1 and one in which they do not. I ask most students to focus first on the problem in which the lines have the same slope and the extension is for students who tackle this problem easily. Either way, they are thinking about the same big ideas.
- Students who work on the next level will realize eventually that the coefficient
*a*in each form of the parabolic function rule is the product of the slopes of the two lines. It is interesting to discuss why this is true.

#### Resources

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#### Closing

*10 min*

I introduce today's Exit Ticket by writing it on the board. I ask them to write 1 or 2 sentences using the key words listed. I ask students to write their sentences on a whiteboard. I find that this makes it easier for them to take risks and try out new words.

I ask students to share with a partner to make sure that their sentences make sense. Then, I read them as students leave. Strangely, they often end up writing sentences that really clearly summarize the big idea of the lesson, even with a more open-ended prompt.

#### Resources

*expand content*

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- UNIT 1: Linear and Nonlinear Functions
- UNIT 2: Piecewise Functions
- UNIT 3: Absolute Value Functions and More Piecewise Functions
- UNIT 4: Introduction to Quadratic Functions through Applications
- UNIT 5: More Abstract Work with Quadratic Functions
- UNIT 6: Rational Functions
- UNIT 7: Polynomial Functions
- UNIT 8: Exponential Functions
- UNIT 9: Ferris Wheels
- UNIT 10: Circles
- UNIT 11: Radical Functions
- UNIT 12: Cubic Functions

- LESSON 1: Investigating Profit with Products
- LESSON 2: More Profit Maximization Investigations
- LESSON 3: Profit Maximization Problems Workshop: Multiple Methods
- LESSON 4: Multiple Methods to Solve Problems with Quadratic Functions
- LESSON 5: More Multiple Methods to Solve Problems involving Quadratic Functions
- LESSON 6: 4-Column Quadratic Data Tables
- LESSON 7: More 4-Column Data Tables
- LESSON 8: Applying Data Tables to Word Problems
- LESSON 9: Profit Maximization and 4-Column Data Tables Review
- LESSON 10: Profit Maximization and 4-Column Data Tables Summative Assessment
- LESSON 11: Different Forms of Quadratic Functions
- LESSON 12: Quadratic Data Tables
- LESSON 13: Finding Vertices of Parabolas
- LESSON 14: Heights of Falling Objects
- LESSON 15: Profit Maximization
- LESSON 16: Quadratic Functions Review and Portfolio
- LESSON 17: Quadratic Functions Summative Assessment