Lesson Plan 1: Miles of Tiles - The Pool Border Problem
Teachers will need the following:
Students will need the following:
- Transparencies with 1 cm grids
- Approximately 30 unit algebra tiles (click here for a set of printable algebra tiles)
- 1 large piece of poster board with a 1 cm grid
- 1 cm by 20 cm strips (click here for a set of printable 1 cm strips)
- Glue stick
- Grid paper
- Approximately 40 unit algebra tiles
1. Begin the day's lesson with a story, such as:
Last night, I saw the most wonderful pool. It had beautiful tiles all around it. So this morning, I asked my landlord if he would install a pool in the backyard of my apartment. At first, he thought I was crazy, but I told him I'd make him a deal. I told him that if he built my dream pool, I would install the tiles around the edges of the pool. So, he made a deal with me. He told me that he'd install a pool with an area of 36 square feet.
2. Ask the class, "If my pool has an area of 36 square feet, what are the possible dimensions of the pool?" Elicit from students all possible dimensions of the pool, using only whole numbers: 1 ft by 36 ft, 2 ft by 18 ft, 3 ft by 12 ft, 4 ft by 9 ft, and 6 ft by 6 ft.
3. Explain to students that you are on a budget, so you need their help in determining the least number of tiles that could be used around the outside edge of the pool. Using the overhead projector, display a 4 ft by 9 ft pool. Tell students that each algebra tile represents a 1 ft by 1 ft tile. Ask students to predict the number of tiles that would be needed to put a border of tiles around the entire pool.
4. On the board, record student guesses for the number of tiles needed. You may want to have the class reach a consensus regarding the number of tiles that will be necessary, or you may want them to discover this in their groups as part of the learning activities below. (For a 4 ft by 9 ft pool, the class should conclude that the border will consist of 30 tiles: the perimeter of the pool is 26 ft, and one tile is needed for each foot of perimeter; in addition, 4 tiles are needed at the corners, as shown below.)
1. Explain to the class that they will be working in groups of four to investigate the number of tiles needed for pools of various sizes. For the group exploration, provide the following directions:
You may want to have students devise their own way of working together or you may want to assign the following roles to members of the group: writer, responsible for filling in the group's chart; cutter, responsible for the scissors; sticker, responsible for the glue; and speaker, who will present the group's findings to the class.
- Sitting together, build pools and make borders around the pools.
- Record the number of tiles needed for each pool.
- Look for a pattern.
- Finally, come up with an algebraic expression that relates the length and width to the number of tiles needed.
2. Assign one of the various pool sizes (from the introductory activity) to each group. The students in each group are responsible for constructing a model of the pool they are assigned. In addition, the group should consider all of the various pool sizes and look for a pattern that relates the length and width to the number of tiles needed.
3. Allow students time to construct a model of the pool they have been assigned. Students should cut the 1 cm by 20 cm strips to the length needed to form a border around their pool. Students may also use the 1 cm by 20 cm strips to investigate pools of sizes other than the one they were assigned, or they can investigate using the grid paper. As students are working, circulate and use effective questions to help the groups identify the relationship between the length and width and the number of tiles.
4. After about 15-20 minutes, have each group present its findings. (Depending on the number of students in your class, this may mean that two speakers are presenting the same material, or it may mean that some sizes will not have been assigned.)
Students will invariably arrive at several different expressions for finding the number of tiles, including:
5. After all student groups have presented their findings, describe one of the expressions that they have not discovered, and ask them to consider whether or not this alternative method is equivalent to their expression. For instance, you might say, "I was thinking that I would add the length and the width, double that result, and then add 4."
- 2l + 2w + 4
- 2(l + w) + 4
- 2(l + w + 2)
- 2(l + 2) + 2(w + 2) - 4
- (l + 2)(w + 2) - lw
6. Select a student to translate your method into an algebraic expression. Be sure to discuss the order of operations.
7. Select another student to demonstrate how the equation found by their group is equivalent to the alternate expression that you suggested. (You may wish to repeat this step if several groups found different expressions. This discussion may allow for an explanation of the distributive property, the order of operations, the associative and commutative properties, and other topics.)
8. Ask again the question that was posed at the beginning of the lesson: "Which pool would require the fewest tiles?" Students should conclude that the 6 ft by 6 ft pool will only require 28 tiles, and that this is the fewest needed for any 36 sq ft pool.
Then, ask: "If I wanted a pool in which to swim laps, which would be the best one?" Students may suggest that the 1 ft by 36 ft pool is best, because it is the longest. Other students, however, will likely point out that such a pool would not be wide enough. Students may argue for the 2 ft by 18 ft and 3 ft by 12 ft pools as the best candidates. While 4 ft by 9 ft and 6 ft by 6 ft would be wide enough, they would not be long enough for swimming laps.
Explain to students that because the sizes are not ideal for the dream pool, you would like them to consider other patterns for pools. On the board or overhead, show them Design 1, which is a 1 ft by 2 ft ; Design 2, which is a 2 ft by 3 ft pool; Design 3, which is a 3 ft by 4 ft pool; and Design 4, which is a 4 ft by 5 ft pool. Ask them to use this pattern to predict what Design 5 would look like, and then use their drawing to determine the number of tiles needed for the border of the Design 5 pool. Similarly, have students determine the number of tiles needed for Design 11, as well as for Design n.
Allow students to present their findings to the class. In particular, encourage students to share their expression for the number of tiles. For Design n, the length of the pool is n + 1, and the width is n. Consequently, numerous expressions could represent the number of tiles needed for the border of Design n:
Have students use the expressions to confirm the number of border tiles for Design 6 and Design 11.
- 2(n + 1) + 2n + 4
- 4n + 6
- 2(2n + 3)
- 2(n + 1 + n + 2)
- (n + 3)(n + 2) - n(n - 1)
Ask students to express their ideas regarding what they learned about algebra and the power of algebra. Allow several students to share their thoughts.