Students work in pairs on the Think About It problem. The key idea that I want to come out of our whole class discussion is that the figures have the same area, even though they've been re-arranged.
While sharing, some students might state that the area of the figures is 15 square units. If they think this, it signals a misunderstanding about the formula we've used to find the area of rectangles. If students apply A = l x w to the L-figure, they don't have a firm grasp on when to use the formula.
If this does happen, I'd ask the class to unpack why we cannot use A= l x w, and then have students share out how they got to 7 square units.
In this lesson, students are not introduced to a formula to use to find the area of a parallelogram. Instead, they are decomposing the parallelogram using triangles and using the triangle to compose a rectangle. Students then either count squares or apply the formula to find the area.
After the Think About It problem, I quickly fill in the notes. I then show the giant parallelogram from the Intro to New Material page on the document camera. I want to be sure that the triangle that we are using to compose a rectangle is clear, so I will use a dry-erase marker in a noticeable color to really make it 'pop.' See the model for students for a visual example.
For lower performing students, I print off the parallelogram and physically cut the triangle off of the parallelogram and move it to create the rectangle. I can then use this manipulative with individual students who might struggle during independent practice.
If students seem unsure about this method, I will keep the group as a whole class and we'll try the first partner practice problem together.
Students work in pairs on the Partner Practice problem set. As students are working, I circulate around the room. I am looking for:
I am asking:
After partner work time, the class goes over problems 4-7. I cold call on students to share where they 'cut' a triangle and what the area of 4a and 4b must be. We also quickly share out responses for the true/false probelms.
Teaching Note: When making copies of the resources in this lesson, set the copy machine to a dark setting, so that the grid lines are visible for students!
After independent work time, we discuss problem 2b. In this problem, the rectangle covers 15 square units, because of half units on one side. There will be students who do not pay close attention to this, and will think that the area is 16 square units because they've counted the half unites as whole square units (there might also be students who decide to 'ignore' the half units, and record 14 units squared as the area).
I also have students share strategies for problem 7. I expect there will be at least one student who chooses to draw a rectangle. I always display this, along with a regular parallelogram, on the document camera. I ask the student who used a rectangle to justify this shape. I'm looking for the student to explain that a rectangle is a parallelogram.