## SpecialRightTriangles_LookingforCommonPythagoreanTriples_Narrative.docx - Section 2: Looking for Common Pythagorean Triples

# Special Right Triangles

Lesson 5 of 8

## Objective: Students will be able to become familiar with the common Pythagorean triples.

## Big Idea: Students use the results of the previous lesson to investigate common Pythagorean triples.

*45 minutes*

#### Check Homework

*5 min*

As their “Do Now” activity, students are asked to get out the previous day’s assignment, Pythagorean Theorem practice problems (which they were supposed to complete for homework) and to compare their answers with those of the other students in their group. I then ask if there are questions on any of the problems. If so, I ask for volunteers come to the board to answer questions or explain any issues.

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#### An Interesting Extension

*10 min*

For an Extension I introduce the students to the formula that generates whole numbered triples:

**{a,b,c} = {x^2 - y^2 , 2xy , x^2 + y^2}**

For example, if a student chose *x* = 6 and *y* = 1, he or she would generate a 35, 12, 37 right triangle.

I allow the students time to play with this formula (they may use calculators to aid in the calculations) and present several questions for them to consider as they play:

- Can you find any new Pythagorean Triples to add to our list?
- Do you think that ALL Pythagorean triples can be found in this way?
- Can x and y be any values? (Are there any restrictions on x and y?)

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#### Pythagorean Triples Problems

*18 min*

For whatever reason, I have found that students feel empowered when they know the common Pythagorean triples. Throughout the remainder of the course, I often hear students make remarks like, “Of course AB is 12. It’s just a 5,12,13 triangle.” To provide practice in recognizing the triples, therefore, I hand out the Pythagorean Triples problems worksheet and ask the groups to work together to fill in the missing sides of the diagrams. I remind them that they have created lists of triples to which they can refer, and tell them that no calculators or work are allowed. This last stipulation – *no work allowed?* – always produces puzzled looks from some of the students, but they tend to catch on quickly and gain confidence as they begin to recognize the triples.

In the Triples problems I incorporate a number of quadrilateral problems. I will do this throughout the remainder of the right triangles unit, as it provides variety (all the problems aren’t *just* right triangles!) and, more importantly, I think it really sets the stage for the upcoming unit on quadrilaterals. In doing so, I find that the quadrilateral unit requires very little time, relative to many of the other units, because the students have already become so familiar with a lot of the diagrams and problems.

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#### Closure

*2 min*

I wrap up the lesson by pulling the class together and asking the following questions:

- What did we learn today?
- Why did we learn it?
- What if we forget what we learned today, or what if we encounter a triangle we don’t recognize? Then what option do we have?

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*Responding to Beth Menzie*

Thanks Beth! I wanted to make sure I wasn't missing something important. I made the same adjustment in class today. Great lesson!

| 2 years ago | Reply*Responding to Jillian Hoyle*

It does seem to need one more dimension. For example, you could add the lengths of the two missing sides of the hexagon. If you make them 20, students should be able to finish up the rest. Or make one of the dotted lines 48; that should work, too.

| 2 years ago | Reply

How would a student approach problem #10 in the practice? Is it possible to solve without angle measures?

| 2 years ago | Reply*expand comments*

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- LESSON 1: Introduction to Similar Right Triangles
- LESSON 2: Prove It (Part 1)
- LESSON 3: Prove It (Part 2)
- LESSON 4: Using the Pythagorean Theorem
- LESSON 5: Special Right Triangles
- LESSON 6: 30, 60, 90 Triangles
- LESSON 7: Isosceles Right Triangles
- LESSON 8: Special Right Triangles Puzzle Activity