If needed, remind students of the definition of “altitude”: An altitude of a triangle is a line segment that is drawn from a vertex to the opposite side and that is perpendicular to that side.

In a previous lesson, students proved that all equilateral triangles are similar. In this lesson, students convince themselves that equilateral triangles decomposed into two congruent halves are similar right triangles, and that the ratios of their side lengths will therefore be equal.

The first triangle students encounter in this activity is an equilateral triangle with side lengths of 2 units, which means that the shortest sides of the 30-60-90 triangles formed are 1 unit long. Monitor for students who:

• Use scale factors to determine the side lengths of the triangles they measure.
• Measure the sides and then compute all the ratios.

Students will need a set of equilateral triangles to measure. They could use isometric dot paper, construction tools, or the blackline master. As they find the lengths of sides of 30-60-90 triangles by both measuring and solving analytically, students reason abstractly and quantitatively (MP2).

Making dynamic geometry software available gives students an opportunity to choose appropriate tools strategically (MP5).

If students are struggling to organize their thinking, suggest that they make a table. Help students brainstorm categories that would be effective for organizing their measurements and calculations, for example, “short-leg length,” “altitude length,” and “hypotenuse divided by short leg.”

The goal of this discussion is to ensure that all students understand that the length of the altitude of any equilateral triangle is exactly  times the length of the short side of the right triangle that is formed.

Display the image:

Ask students what they found for the quotient. (length of the altitude, , divided by length of the short leg, ) Include students who approximated the lengths using a calculator and students who left the length of the altitude as .

Display 2–3 approaches from previously selected students for all to see. Use Compare and Connect to help students compare, contrast, and connect the different approaches. Here are some questions for discussion:

• “What do the approaches have in common? How are they different?”
• “Did anyone solve the problem the same way but would explain it differently?”

Ask students why the altitude in any equilateral triangle seems to be half the side length multiplied by about 1.7 each time. (The altitude is also the median in an equilateral triangle, so the short leg is half the side length. All equilateral triangles are similar to the first one we studied, in which the altitude was .)

Ask students if they agree that both of these things are true:

• The length  is about 1.7 times .
• The length is exactly times .

The purpose of this discussion is to review approaches students have taken to connect prior knowledge of the ratios of side lengths in 30-60-90 triangles to the triangles in this task, and therefore to find the unknown side lengths.

Make sure all students understand that each of the three triangles is a 30-60-90 right triangle and represents half of an equilateral triangle so that students are prepared to connect their reasoning from earlier activities to this activity.

Focus on the third figure. Ask students what was different about that figure that might have made the task a bit harder. (There's only one side given, and it has a square root in it.) Invite previously selected students to explain their strategies for calculating the lengths of the other two sides