Modeling Prompt

On a Roll

Task Statement 1

Teacher Instructions

Consider the types of cups to make available to students and how they will be able to manipulate the cups. For example, paper cups can be cut apart and unrolled, but plastic cups can’t. If materials are limited and need to be reused in multiple class periods, consider providing an intact cup and a cup that has already been cut apart so that students can examine both of them.

After students have completed the task, either invite them to share how they knew what shape the cup would trace out, or have a gallery walk so that students can see and comment on each other’s arguments.

Then invite them to share their responses to the last question: how did they make a cup that would trace out the largest possible area? If no student mentions it, ask what would happen if the sides of the cup weren’t slanted at all. (In theory, the cup will roll forever and trace out an infinite area, but in reality, it will run into something eventually and stop.)

Technology can be helpful when students are experimenting with different possible cup shapes. If technology is available, here is an applet students can use: 

Student-Facing Statement

  1. What shape does a cup trace out when it is rolled on a flat surface? Use words and pictures to explain how you know.
  2. How can you locate the center and calculate the area of the shape that is traced out?
  3. Using one sheet of 8.5 inch by 11 inch paper, how could you make a cup that will trace out the largest possible area?

Lift Analysis

attribute DQ QI SD AD M avg
lift 0 1 2 2 2 1.4

Sample Student Response

For access, consult one of our IM Certified Partners.

Task Statement 2

Teacher Instructions

Consider the types of cups to make available to students and how they will be able to manipulate the cups. For example, paper cups can be cut apart and unrolled, but plastic cups can’t. If materials are limited and need to be reused in multiple class periods, consider providing an intact cup and a cup that has already been cut apart so that students can examine both of them.

If students see the questions in Part 2 before they have finished Part 1, it will give away the shape that the cup traces out, so hand out Part 2 after the discussion of Part 1. Part 1 can be discussed before all students have finished their explanations, as long as they all have some developed ideas about what the shape is. For the discussion, ask students to share what shape they think the cup traces out and why they think so. Students do not need to have fully developed proofs, but take the opportunity to press them to clarify their terminology and justify their assumptions.

After students have completed the task, invite them to share their responses to the last question: how did they make a cup that would trace out a larger area? (The bottom radius should be closer to the top radius so that the radius of the ring will be larger, or the cup should be taller so that the ring is thicker.) Then ask how they would make a shape that traces out the largest possible area. If no student mentions it, ask what would happen if the sides of the cup weren’t slanted at all. (In theory, the cup will roll forever and trace out an infinite area, but in reality, it will run into something eventually and stop.)

Technology can be helpful when students are experimenting with different possible cup shapes. If technology is available, here is an applet students can use: 

 

Student-Facing Statement

Part 1:

What shape does a cup trace out when it is rolled on a flat surface? Explain or show your reasoning.

Pause for discussion.

Part 2:

  1. The outside of this ring has a radius of 55 cm. The inside of the ring has a radius of 38 cm. Find the area of the ring.
    circle with a smaller circle inside of it. space between circles is shaded.
  2. Triangle \(ABC\) is isosceles. Find the length of side \(AC\) using the information given. The two vertical lines are parallel.

    triangle ABC. side AB = 4 centimeters. vertical line parallel to AB, to the right towards vertex C = 3 centimeters. 
  3. Here is the cross-section of a cup. It shows the width of the cup at the top and at the bottom, and the slant height of the cup. If we extend the sides of the cup down until they meet at a point, we will make a triangle. What would the slant height of that triangle be?

    quadrilateral. top = 8 centimeters. bottom = 6 point 5 centimeters. left side = 12 centimeters.
  4. Measure the widths of the top and bottom of your cup, and measure its slant height. If you drew the cross-section of the cup and then extended the sides to make a triangle, what would the slant height of the triangle be?

  5. If you rolled your cup in a circle to make a ring, what would the area of the ring be?

  6. Give an example of a cup that would trace out a larger area than your cup would.

Lift Analysis

attribute DQ QI SD AD M avg
lift 0 1 1 2 1 1.0

Sample Student Response

For access, consult one of our IM Certified Partners.