• Teacher observations during group activities should focus on requiring participation by all students, [IS.16 - All Students] challenging individual responses to each component of the activity, and making immediate corrections and remediation of errors of understanding and execution.

• By completing the Exit Ticket activity (M-A2-2-2_Lesson 2 Exit Ticket.doc and M-A2-2-2_Lesson 2 Exit Ticket KEY.doc), [IS.17 - All Students] students show their understanding and ability to represent vertex form and translate between vertex form and standard form.

[IS.15 - All Students]

After this lesson, students will be able to convert quadratic functions from standard form to vertex form using the “completing-the-square” technique. In the previous lessons, students learned how useful the vertex form can be, but not all quadratic functions are written in vertex form. Students will understand that quadratic relationships happen all around us and that the vertex is important to know, especially if the situation is talking about minimizing costs or maximizing revenue. Note that maximum and minimum value occurs at the vertex. The maximum or minimum value is the y-coordinate.

“Who likes putting puzzles together? Remember the first day of this unit when I asked you to find the vertex of y = x² + 6x + 8? Well we can find the vertex by putting together a little puzzle.”

Hand out a set of Algebra Tiles^TM to each student. [IS.5 - All Students] Students will be working with their tiles on their desk. You may also use the template provided (M-A2-2-1_Algebra Tiles Template.doc).

“We will be using Algebra Tiles^TM to make a square. We are going to say that x² is represented by a square with side length x. We are now going to say that x is represented by a rectangle with length x and width 1. Then we have a single unit with side length 1.”

“Each part of the quadratic equation tells us how many tiles to use. We need 1 x², 6 x rectangles, and 8 single units. Let’s count them out.”

“The goal now is to make a square with the tiles that we have. Begin by putting the x² square in the top left corner.”

“Then how would we split up 6 x rectangles evenly?” Students should say 3 and 3.

“Line up the rectangles: three rectangles along the right side of the x² square and three rectangles below the x² square.”

“Now begin filling in the bottom right-hand corner of the square with our single unit pieces.”

The two graphics provided are illustrations of the same equation; the only difference is that the one on the right has the outside dimensions labeled.

“What are the dimensions of this square we made?” Students should come up with x + 3 by x + 3. Students may also note that they were not able to make a whole square.

“How can we simplify x + 3 by x + 3?” Students should say (x + 3)².

“Now did we make a full square? We are missing one unit in the corner, so the equation can’t be (x + 3)². What do we need to do to the equation?” Students should say minus/subtract 1.

“Does anyone recognize (x + 3)² − 1? What form is the equation in? What is the vertex?” [IS.6 - All Students] The equation is now in vertex form and the vertex is at (−3, −1).

“So any time we are missing a piece, we need to subtract it. What would the equation be in vertex form if we had y = x² + 6x + 11?” Students should add 3 more units to their square. “Now the equation in vertex form is going to be y = (x + 3)² + 2, the same as before, except three was added to the k value: −1 + 3 = 2.”

The two graphics provided are illustrations of the same equation; the only difference is that the one on the right has the outside dimensions labeled.

“So if we have too many pieces, we have to add that extra amount to the equation. This technique we use to convert an equation from standard form to vertex form is called completing-the-square.”

Activity 1: Using Algebra Tiles^TM

Place the following equations on the board for students to practice using the Algebra Tiles^TM. They should use their tiles to find the vertex form of the parabola and to determine the vertex. [IS.7 - All Students] Tell students to do one at a time and that they cannot go on to the next one until you have approved their work.

1. y = x² + 8x + 2 [y = (x + 4)² − 14; vertex (−4, −14)] [IS.8 - Struggling Learners]

2. y = x² + 2x + 3 [y = (x + 1)² + 2; vertex (−1, 2)]

3. y = x² + 10x + 12 [y = (x + 5)² − 13; vertex (−5, −13)]

4. y = x² + 4x + 11 [y = (x + 2)² + 7; vertex (−2, 7)]

5. y = x² − 6x + 4 [y = (x − 3)² − 5; vertex (3, −5)]

“Has anyone noticed a pattern? [IS.9 - All Students] What would happen if I had an odd number of x tiles? We are not always going to have the tiles available, so we may have to draw a picture. We will practice this scenario in the next activity.”

Activity 2: Think-Pair-Share

“With your partner, convert the following standard form equations to vertex form by using the formula. When you are done, get together with another pair and check your work.”

Standard form: y = ax² + bx + c

Formula to convert to vertex form:

1. y = x² + 5x + 6 [y = (x + 2.5)² − .25; vertex (−2.5, −.25)]

Illustrate item 1 by showing steps to

[IS.10 - All Students]

 

2. y = x² + 7x − 4 [y = (x + 3.5)² − 16.25; vertex (−3.5, −16.25)]

3. y = x² − 9x + 25 [y = (x − 4.5)² + 4.75; vertex (4.5, 4.75)]

Some students may not like using the tiles, so show them the formula. Students should copy this formula in their notes. See other references in various texts on completing the square for examples.

Activity 3: Group Work

Separate the class into groups of four and distribute the Group Word Problems worksheet (M-A2-2-2_Group Word Problems.doc and M-A2-2-2_Group Word Problems KEY.doc). [IS.11 - All Students] Note that the maximum and minimum occurs at the vertex. The maximum and minimum value is the y-coordinate.

Activity 4: Think-Pair-Share

“What do you think we would need to do to convert a vertex form equation back into standard form? With a partner, brainstorm how you would convert the quadratic equation y = (x + 4)² – 5 into standard form.” Tell students that it does not entail a square or a formula. They already have the tools to change this equation. Tell them first to think about this on their own, partner with another student, and then share their ideas with the class.

“It is important to use the order of operations. What does it mean to square something? What does it mean to combine like terms and to simplify?”

Show students how easy it is to convert from vertex to standard form.

(x + 4)² − 5 = (x + 4)(x + 4) − 5 = x² + 4x + 4x + 16 − 5 = x² + 8x + 11

Give students the following equations to convert to standard form.

1. y = (x − 3)² − 17 [y = x² − 6x − 8]

2. y = (x + 7)² − 40 [y = x² + 14x + 9]

3. y = (x + 8)² − 65 [y = x² + 16x − 1]

4. y = (x − 6)² − 1 [y = x² − 12x + 35]

Activity 5: Pair Work

“Individually, you are going to write two equations in standard form and two equations in vertex form. [IS.12 - All Students] Convert your equations to the other form and keep your answers. You are then going to give the four equations you wrote to your partner. You and your partner will then convert the equations to the other form. When both of you are finished, check each other’s work.”

Hand out the Lesson 2 Exit Ticket (M-A2-2-2_Lesson 2 Exit Ticket.doc and M-A2-2-2_Lesson 2 Exit Ticket KEY.doc) to evaluate students’ understanding.

Use the following strategies to tailor the lesson to meet the needs of your students throughout the year.

Routine: Group and partner work is used throughout so that students can help each other. Emphasis should be placed on communicating mathematical ideas with the specific vocabulary words appropriate to the concepts. The lesson requires accurate note-taking skills to enhance the learning experience while creating a useful resource (notes). [IS.13 - All Students]

“How do we complete the square if there is a number in front of x²? We can either use the tiles or factoring.”

Example: y = 2x² + 4x + 6

“We will try to make 2 squares since 2 is the number in front of x².”

“Since we have 2 squares with dimensions x + 1 by x + 1, we can write that as 2(x + 1)² and then we have 4 single units. So the equation is y = 2(x + 1)² + 4. The vertex is at (−1, 4) and it has a stretch factor of 2.”

“Another way we could have changed the equation from standard to vertex form would have been to use factoring. [IS.14 - Struggling Learners] Factor out the number in front of x².”

Example: y = 2x² + 4x + 6

y = 2(x² + 2x + 3)

“Complete the square using only what’s in parentheses (x² + 2x + 3).”

(x + 1)² + 2

“Now distribute the 2 that we factored out.”

2(x + 1)² + 4

Extension:

• Students who need additional opportunity for learning can use the tiles or factoring to solve the following problems:

1. y = 3x² + 12x − 18 [y = 3(x + 2)² – 30]

2. y = −2x² − 10x + 8 [y = -2(x + 2.5)² + 20.5]

3. y = −x² + 6x − 3 [y = -(x – 3)² + 6]

4. y = 4x² − 16x − 12 [y = 4(x – 2)² – 28)]