IM: 6.9.3: Rectangle Madness (Lesson)

Suppose segment AF were 5 units long and segment FD were 2 units long. How long would segment AD be?

Suppose segment BC were 10 units long and segment BE were 6 units long. How long would segment EC be?

Suppose segment AF were 12 units long and segment FD were 5 units long. How long would segment FE be?

Suppose segment AD were 9 units long and segment AB were 5 units long. How long would segment FD be?

The diagram shows that rectangle VWYZ has been decomposed into three squares. What could the side lengths of this rectangle be?

How many different side lengths can you find for rectangle VWYZ?

What are some rules for possible side lengths of rectangle VWYZ?

Draw a rectangle that is 21 units by 6 units.

In your rectangle, draw a line segment that decomposes the rectangle into a new rectangle and a square that is as large as possible. Continue until the diagram shows that your original rectangle has been entirely decomposed into squares.

How many squares of each size are in your diagram?

What is the side length of the smallest square?

Draw a rectangle that is 28 units by 12 units.

In your rectangle, draw a line segment that decomposes the rectangle into a new rectangle and a square that is as large as possible. Continue until the diagram shows that your original rectangle has been decomposed into squares.

How many squares of each size are in your diagram?

What is the side length of the smallest square?

\frac{16}{5}

\frac{21}{6}

\frac{28}{12}

Accurately draw a rectangle that is 9 units by 4 units.

In your rectangle, draw a line segment that decomposes the rectangle into a new rectangle and a square that is as large as possible. Continue until your original rectangle has been entirely decomposed into squares.

How many squares of each size are there?

What are the side lengths of the last square you drew?

Write \frac{9}{4} as a mixed number.

Accurately draw a rectangle that is 27 units by 12 units.

In your rectangle, draw a line segment that decomposes the rectangle into a new rectangle and a square that is as large as possible. Continue until your original rectangle has been entirely decomposed into squares.

How many squares of each size are there?

What are the side lengths of the last square you drew?

Write \frac{27}{12} as a mixed number.

Accurately draw a 37-by-16 rectangle.

In your rectangle, draw a line segment that decomposes the rectangle into a new rectangle and a square that is as large as possible. Continue until your original rectangle has been entirely decomposed into squares.

How many squares of each size are there?

What are the dimensions of the last square you drew?

What does this have to do with 2 + \frac{1}{3 + \frac{1}{5}}

Consider a 52-by-15 rectangle.

In your rectangle, draw a line segment that decomposes the rectangle into a new rectangle and a square that is as large as possible. Continue until your original rectangle has been entirely decomposed into squares.

Write a fraction equal to this expression: 3 + \frac{1}{2 + \frac{1}{7}}

Notice some connections between the rectangle and the fraction.

What is the greatest common factor of 52 and 15?

Consider a 98-by-21 rectangle.

In your rectangle, draw a line segment that decomposes the rectangle into a new rectangle and a square that is as large as possible. Continue until your original rectangle has been entirely decomposed into squares.

Write a fraction equal to this expression: 4 + \frac{1}{1 + \frac{7}{14}}

Notice some connections between the rectangle and the fraction.

What is the greatest common factor of 98 and 21?

Use the decomposition-into-squares process to write a continued fraction for \frac{121}{38}. Verify that it works.

What is the greatest common factor of 121 and 38?