Geometry Area, Symmetry, Translations, Reflections, and Rotations

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Geometry Area, Symmetry, Translations, Reflections, and Rotations

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Title: Geometry Area, Symmetry, Translations, Reflections, and Rotations

1
GeometryArea, Symmetry, Translations,
Reflections, and Rotations

Jim Rahn
LL Teach, Inc.
James.rahn_at_verizon.net
www.jamesrahn.com

2
On a geoboard

Use one geoband to make a rectangle whose area is
15 square units.

What is the base and height of your rectangle?
How did you determine the dimensions of a
rectangle with the specified area of 15 square
units?
If the geoboard was a different size what other
rectangle could you build?

Which rectangle(s) do not have an area of 15
square units. Support your answer.

How is the area of a rectangle found?
Why is the formula A bh give you the area of a
rectangle?

5
Establishing the Area of a Triangle

Make a square with an area of 36 square units and
one vertex at (3, 1).

Lift the geoband from the vertex at (9, 7) so
that a right triangle is formed.

Determine the area of the triangle. Support your
answer in two ways.

Make a square with an area of 16 square units and
a vertex at (2, 3).

Lift the geoboard from the vertex at (2, 7) to
once again create a right triangle. Find the area
of the triangle in two ways.

Make a square with an area of 25 square units and
a vertex at (8, 3).

Lift the geoboard from the vertex at (3, 8) to
make a right triangle. Determine the area of the
triangle in two ways.

What conclusion can you make about each triangle
and the related square?
Will the area of a right triangle formed from a
rectangle be half of the related rectangle?

Make a rectangle whose area is 20 square units
anywhere on the geoboard.

What do you think about the area of the related
triangle will be?
Lift the geoband from one of the vertices of the
rectangle to form the right triangle that has the
same base and height as the original.

Count the full and partial squares to estimate
the area of the triangle.
Do both right triangles have the same area?
Support your answer.

10
Establishing Area of Non-right Triangles

Make a square with an area of 36 square units and
one vertex at the ordered pair (0, 0).
Take another geoband and make a right triangle
whose base and height both measure 6 units, and
whose right angle is at the ordered pair (0, 0).
What is the area of this triangle?

Move the geoband forming the right triangle so
that the top vertex is at the ordered pair (3,
6). The triangle is now an isosceles triangle.

What makes this triangle isosceles?
Why isnt it also a right triangle?
What would be the name of this triangle if it
were classified by its angles instead of its
sides?

What is the area of this isosceles triangle?
Support your answer.
How can you be sure that it is half the square?
Describe your method to find the area of the
green isosceles triangle.

Now move the top vertex of the isosceles triangle
to the ordered pair (4, 6).

What kind of triangle is now formed?
Why is this a scalene triangle?
If this triangle were classified by its angles,
what would it be called?
What do you think the area of this triangle is?
Is it still half of the square?
Show that it is 18 square units.

Make a right triangle with an area of 24 square
units whose right angle vertex is at the ordered
pair (4, 0).
Make the related rectangle. What is the area of
the rectangle?

Move the geoband so that the top vertex is at the
ordered pair (6, 8) instead of (4, 8).

What kind of triangle did the right triangle
become?
Why is it scalene?
What is the area of this scalene triangle?
Is it still 24 square units?
Show that it is 24 square units.

If you make different triangles by moving the
geoband along the top base of the rectangle, the
triangle changes shape. But does it change its
area in relationship to the rectangle?

Notice that the areas of the triangles are still
24 square units because the height and the length
of the bases of the related rectangle stay the
same.

Use the geoboard to make a rectangle with a base
of 5 units in length, a height of 6 units and one
vertex at the ordered pair of (0, 0).
Use another geoband to show a triangle that has
the same base and height as the rectangle but
that has one vertex at the ordered pair (2, 6).
What is the area of this triangle?
How do you know?

Take a new geoband and make a segment from (4, 0)
to (4, 6) What is the length of this line
segment?
What is the relationship between this line
segment and the height of the rectangle?

Remove the geoband for the vertical segment you
just made. Now make a segment from (3, 0) to (3,
6).
What is the relationship between this segment and
the height of the rectangle?
Remove the geoband and move it so that its
endpoints are (2, 0) and (2, 6).
What is the relationship between this vertical
segment and the height of the rectangle?

Notice that the segments drawn are the same
length as the height of the related rectangle.
Often the height of a triangle is given as the
segment that is the same length and parallel to
the height of the related rectangle. The picture
at the right is often used to represent this
concept.

Usually triangles are shown as they are above,
but it is still important to think of the
triangle as half of its related rectangle, which
would be the rectangle that has the same base and
height as the triangle.

Which of the triangles below can be derived from
a square whose area is 36 square inches?
What is the base and height of the related
rectangle for Triangle B?

Make a triangle on your geoboard that has a
height of 8 units and a base with a length of 3
units. Show the triangles.
Use another geoband to make the rectangle from
which your triangle could be derived.
Hold up the answers.
Are all the rectangles you made congruent?
Are all the triangles the same area? Why?

Make a rectangle that has the same height and
base as a scalene triangle whose area is 16
square units.

How are the areas of the triangle and rectangle
related?

25
Drawing Heights

Draw on a Communicator a scalene acute triangle
similar to the one shown.

Draw the height and base of this triangle as
shown, and establish that the height of the
triangle can be determined by the length of the
perpendicular segment drawn from the vertex of
one angle to form right angles at the opposite
side.

The height must be perpendicular so it can be
matched with the height of the relative rectangle
that can be formed around the triangle. Since the
rectangle has right angles, the height within the
triangle must have right angles as well.

height
base
28

Turn the Communicator several times
Draw a new height from this direction.
Each time ask if the height is still the same and
if it still goes from the vertex of one angle and
forms a perpendicular with the opposite side.

29
Is there a relative rectangle with the new base
and height?
Is the area of the triangle ½ of the area of the
relative rectangle?
30
A height drawn from vertex A

Draw the another scalene acute triangle on the
Communicator.

Label the triangle as illustrated.
Label one base and height.

Is there a relative rectangle with the same base
and height?

height
base
31

Can you draw the base and height two other ways?

Can you draw a height from vertex B?

Is there a relative rectangle for each of these?
Label the base and height.

Can you draw the base and height two other ways?
Can you draw a height from vertex C?
Is there a relative rectangle for each of these?
Label the base and height.

base
height
33

Complete Determining the Areas of Triangles
(Page 77).
Draw the heights from the vertex shown and label
the height and the length of the related bases
and the draw in the relative rectangle.
Compute the area of the triangles.

34
Derive and apply the area formula for a
parallelogram.

Build the parallelogram on a geoboard that has
vertices at (1, 5), (3, 7), (10, 7), and (8, 5).

Determine the area or the number of square units
contained in the parallelogram using any method.
You will be asked to explain how you found the
area. Be prepared to explain your method.
You may want to place your Communicators on top
of the parallelograms to help in determining the
area of the parallelogram

35
Derive and apply the area formula for a
parallelogram.

Build the parallelogram on a geoboard that has
vertices at (0, 8) (6, 8) (10, 4) and (4, 4).

Determine the area or the number of square units
contained in the parallelogram using any method.
You will be asked to explain how you found the
area. Be prepared to explain your method.
You may want to place your Communicators on top
of the parallelograms to help in determining the
area of the parallelogram.

Will your method for finding the area of a
parallelogram always work?
Use the template of the first quadrant to draw
the parallelograms whose vertices are
Parallelogram 1 (0, 6) (1, 10) (4, 10) (3, 6)
Parallelogram 2 (4, 6) (6, 10) (9, 10) (7, 6)
Parallelogram 3 (0, 1) (3, 5) (6, 5) (3, 1)
Parallelogram 4 (7, 1) (7, 5) (10, 5) (10, 1)

Once you have drawn them cut them out and try
cutting the shape to create a rectangle out of
each parallelogram. Use the glue sticks to
attach the transformed shape (rectangle) to an
index card.
Is the area of the parallelogram equal to each
transformed shape?
How does the transformed shape help you find the
area of the parallelogram?

Use the grid to plot each set of coordinates. Use
a ruler to connect the points so that a
parallelogram is formed.
Determine the area of each of the parallelograms.
Parallelogram 1 (0, 10) (3, 10) (7, 6) (4, 6)
Parallelogram 2 (0, 5) (4, 5) (10, 0) (6, 0)

Why do you think that determining the height of
these parallelograms would be different from
determining the heights of the parallelograms on
the previous sheet?
What do you think the height of these new
parallelograms would be?
Why?
If this is the height, what would be the area of
each of the parallelograms? Why?
Whatever method we use we must be sure, without a
doubt, that it will work all the time.

To show that this is true, draw rectangle EFGH,
shown at the right
Label the Triangles A and B.
Determine the area of each of the triangles.
If we know the area of each of the triangles, how
can we determine the area of the parallelogram?

What is the length of the base of
this rectangle?
What is the height of this rectangle? What is the
area of this rectangle?
What is the area of Parallelogram 1?

Complete parallelogram 2 in the same manner. Draw
the triangles to make the rectangle, and label
the triangles C and D. Label the rectangle JKLM.
How can we find the area of Parallelogram 2?

Do each of the calculated areas match the areas
of the conjecture made earlier?
The area of any parallelogram will always be A
bh as long as the height is the measure of a
vertical segment that forms a perpendicular
intersection with each base, even though the
segment may not be inside the parallelogram

44
Derive and apply the area formula for trapezoids.

Use a geoboard and a geoband to create a square
with an area of 16 square units and a vertex at
the ordered pair (0, 0).
Use a second geoband to create another square of
16 square units that DOES NOT overlap the first
one and is anchored at the ordered pair (4, 0).
Form a triangle from the second square by lifting
the geoband from the vertex at (8, 4).

Determine the area of the figure formed by the
square and the triangle.
What kind of figure is formed by these two
polygons

Create a square with an area of 9 square units
and a vertex at (0, 0).
Create another square of 9 square units that does
not overlap the first and is anchored at the
ordered pair (3, 0), and still another at (6, 0)
whose area is also 9 square units

Form a right triangle from the first square by
lifting the geoboard from the vertex at (0, 3)

What is the area of the figure formed by these
three polygons?
What kind of figure is made from this combination
of figures?

Lift the geoband from the vertex at (9, 3) to
form a right triangle

What is the area of entire figure?
What kind of figure is made from this combination
of figures?

Move the vertex located at (0, 0) to (2, 0)

What is the area of the combined figures?
Is the figure formed from these three figures a
trapezoid?
Why?
Find its area

Have students use one geoband and a geoboard to
create a right trapezoid whose vertices are (0,
0) (0, 4) (3, 4) and (5, 0).
Place a Communicator on top of the geoboard to
highlight the partitions and discuss how to
determine the area of each subfigure.

Place the geoboard grid under your communicator
.
Draw the trapezoid at the right and label the
bases
Rotate the communicator and copy a duplicate
copy of your first trapezoid. Label the new
bases.

How can you use this picture to find the area of
one trapezoid?

Turn to Determining the Area of Trapezoids (Page
83).
Draw the each trapezoid. Find the area of each
trapezoid using two methods.

51
11 square units
52
13 ½ square units
53
22 square units
54
22 square units
55
Assessing Student Understanding of Area
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61
Use pattern blocks to identify and create designs
with line and rotationalsymmetry.
62

Use the pattern blocks at your table.
Identify the number of lines of symmetry for each
of the shapes.
Which have one line of symmetry?
Two lines?
Three lines?
Four lines?
Six lines?

63
Establishing Rotational Symmetry

Imagine drilling a hole in the middle of the
hexagon and placing a dot near one of the
vertices of the hexagon.
Place a pencil through the hole.
If the top polygon can be rotated around the
pencil point, or center, less than 360 or less
than one full turn around and still exactly match
the bottom polygon, the shape is said to have
rotational symmetry.
The hexagon has 60 rotational symmetry because
it can be positioned on the top of another
congruent hexagon in 6 different ways

Find the rotational symmetry of the other 5
pattern blocks. Explain how you found the number
of degrees for the rotation.

60o or 6 different ways
180o or 2 different ways
90o or 4 different ways
120o or 3 different ways
No ways
180o or 2 different ways
65

Make various designs with the overhead pattern
blocks and determine whether they have rotational
and/or line symmetry.

No lines of symmetry 90o rotation or 4 different
ways
1 line of symmetryNo rotational symmetry
66

Show one side of a design with line symmetry.
Then make the other half of the design so the
line shown becomes a line of symmetry.

67
Think about it

If a design has rotational symmetry, must it also
have line symmetry?
If a design has line symmetry, must it also have
rotational symmetry?
Can a design have both rotational and line
symmetry?

Use the Working with Symmetry (Page 133) with
your Communicators.
Which designs have exactly one line of symmetry?
Which designs have exactly two lines of symmetry?
Which designs have exactly five lines of
symmetry?
Which designs have exactly six lines of symmetry?
Which designs have exactly eight lines of
symmetry?
Which designs have exactly nine lines of
symmetry?
Which designs have no lines of symmetry?

Use the Working with Symmetry (Page 133) with
your Communicators.
Establish the degree of rotational symmetry for
each of the shapes or designs by tracing each one
and then rotating the Communicator
appropriately.

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75
Create a translation

Place the Communicator on top of the
Transformation Grid and Chart template.
Locate the three vertices A(1, 1), B(2, 3), and
C(4, 1).
Draw the line segments between these points to
create a triangle.
Record the coordinates on the chart under the
original figure.

76
Create a translation

Translate the figure 5 units to the left and
redraw the triangle.
Read the coordinates for the translated triangle
and record them in the chart.
Study the coordinates and write a description on
how the coordinates are changing if the figure is
translated 5 units to the left. (x, y)gt
(___,___)

77
Create a translation

Erase the translated triangle.
Translate the original triangle 3 units down and
redraw the triangle.
Read the coordinates for the translated triangle
and record them in the chart.
Study the coordinates and write a description on
how the coordinates are changing if the figure is
translated 3 units down. (x, y)gt (___,___)

78
Create a translation

Erase the translated triangle.
Translate the original triangle 5 units to the
left and 5 units down and redraw the triangle.
Read the coordinates for the translated triangle
and record them in the chart.
Study the coordinates and write a description on
how the coordinates are changing if the figure is
translated 4 units to the left and 5 units down.
(x, y)gt (___,___)

79
Create a translation

Erase the translated triangle.
Translate the original triangle figure using the
transformation (x, y)gt (x-1, y-3)
Explain how you translated the triangle to
perform this translation.

80
Create a translation

Study the green triangle.
Describe a translation that would move the
triangle to its new position described by the red
triangle.
(x, y)gt (___,___)

81
Create a reflection

Place the Communicator on top of the
Transformation Grid and Chart template
Locate the three vertices A(0, 1), B(2, 3), and
C(4, 2).
Draw the line segments between these points to
create a triangle.
Record the coordinates on the chart under the
original figure.

82
Create a reflection

Erase the reflected the triangle.
Reflect the original triangle over the x-axis.
You may flip the communicator to help you perform
this reflection.
Read the coordinates for the reflected triangle
and record them in the chart.
Study the coordinates and write a description on
how the coordinates are changing if the figure is
reflected over the x-axis. (x, y)gt (___,___)
Explain why this transformation makes sense.

83
Create a reflection

Place the Communicator on top of the
Transformation Grid and Chart template
Locate the three vertices A(2, 1), B(1, 3), and
C(4, 2).
Perform the following transformation
(x, y)gt(x, -y)
(x, y)gt(-x, y)
(x, y)gt(-x, -y)

84
Create a reflection

Study the transformation at the right. The green
triangle is the original. The red triangle is
the transformed triangle.
What type of transformation has taken place?
Describe the transformation (x, y)gt(___, ___)

85
Create a reflection

Study the transformation at the right. The green
triangle is the original. The red triangle is
the transformed triangle.
What type of transformation has taken place?
Describe the transformation (x, y)gt(___, ___)

Turn to Studying Reflections (Page 143).
Study the set of four trapezoids on the sheet and
use Trapezoid 1 as the original figure, or
pre-image.
Two of the other trapezoids are the images after
reflections, and one of them is the result of a
translation.
Describe the reflection or translation of each of
the trapezoids in relation to Trapezoid 1.

Triangle 5 is the original triangle, or
pre-image.
Describe the action that had to take place for
each of the other triangles to be formed.
Use the Communicator to confirm and model each
of the answers.

88
Identify and apply rotations on the coordinate
plane.

Place a Communicator on top of Studying
Rotations I (Page 145.

Trace the dotted trapezoid in Quadrant I on the
Communicator and mark the vertex at (2, 5).
Rotate the Communicator a quarter of a turn, or
90, in a clockwise direction around
the point (2, 5) so the traced trapezoid ends up
on top of the trapezoid which also shares the
vertex (2, 5).
You have just performed a rotation of the figure
90about a point, which in this case is the
vertex (2, 5).
Was the shape congruent to the original shape?

Erase your Communicator.
Rrace the dashed trapezoid in Quadrant II and
mark the vertex at (6, 4) on the Communicator
Turn the Communicator about the point (6, 4) a
quarter of a turn, or 90, in a clockwise
direction so the traced trapezoid ends up on top
of the trapezoid which also shares the vertex
(6, 4).
This is a 90 clockwise rotation about the point
(6, 4).
Was the shape congruent to the original shape?

Erase the Communicator.
Trace the dashed trapezoid in Quadrant III and
highlight the vertex at (5, 4).
Turn the Communicator a quarter of a turn, or
90, in a counterclockwise direction around the
point (5, 4) so the traced trapezoidis
positioned on top of the trapezoid which also
shares the vertex (5, 4).
You have completed a 90 counterclockwise
rotation about the point (5, 4).
Was the shape congruent to the original shape?

Erase the Communicator.
Trace the dashed trapezoid in Quadrant IV and
highlight the vertex at (6, 5).
Rotate the Communicator a quarter of a turn, or
90, in a counterclockwise fashion about the
point (6, 5) so the traced trapezoid ends up on
top of the trapezoid that also shares a vertex at
(6, 5).
You have performed a 90 counterclockwise
rotation about the point (6, 5).
Was the shape congruent to the original shape?