Rotational Symmetry - Math Steps, Examples & Questions

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Rotational symmetry

Here you will learn about rotational symmetry, including rotational symmetry within polygons, angle properties, and symmetry of different line graphs.

Students will first learn about rotational symmetry as part of geometry in high school.

What is rotational symmetry?

Rotational symmetry is the number of times a shape can “fit into itself” as it is rotated $360$ degrees about its center. Rotational symmetry is also known as radial symmetry.

For example,

A rectangle has a rotational symmetry of order $2$ shown below where one vertex is highlighted with a circle and the center of the shape is indicated with an $‘x’.$ In the diagram, the shape looks identical in two orientations and so the rotational symmetry of the rectangle is $2.$

To calculate the order of rotational symmetry of a shape, you need to locate the center of the shape.

If the polygon has an even number of sides, this can be done by joining the diagonals. If the polygon has an odd number of sides, this can be done by joining each vertex to the midpoint of the opposing side.

You then rotate the shape $360$ degrees around the center and see how many times the shape looks exactly like the original.

Rotational symmetry in regular shapes

Many 2D shapes have a rotational symmetry. Regular polygons have the same number of sides as their rotational symmetry due to the angles and side lengths within the shape being the same.

[FREE] Symmetry Worksheet (Grade 4 to 5)

Use this worksheet to check your grade 4 to 5 students’ understanding of symmetry. 15 questions with answers to identify areas of strength and support!

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[FREE] Symmetry Worksheet (Grade 4 to 5)

Use this worksheet to check your grade 4 to 5 students’ understanding of symmetry. 15 questions with answers to identify areas of strength and support!

DOWNLOAD FREE

Rotational symmetry in irregular shapes

If a shape is rotated around its center and the shape returns to the original position without it “fitting into itself”, then the shape is described to have no rotational symmetry. Irregular shapes tend to have no rotational symmetry.

As soon as the angles in two-dimensional shapes change from their equal property, the order of rotational symmetry changes.

Let’s look at different shapes (specifically quadrilaterals) and their order of rotational symmetry.

The kite is interesting because it may appear to have rotational symmetry since it has a line of symmetry. However, if the shape is rotated around its center, it returns back to the original orientation without it fitting into itself again so the order of rotational symmetry for a kite is $0.$

This is also true for any quadrilateral that is not a square, rectangle, parallelogram, or rhombus.

Rotational symmetry in graphs

You can also consider rotational symmetry with different types of graphs.

For example,

Below is the graph of the equation $y=x.$

Given that the line extends in both directions beyond the axes drawn above, you can use the origin as a center of rotation. If you rotate the line $180$ degrees about the origin, you will get exactly the same line. Continuing this rotation all the way through $360^{\circ},$ you get back to the original.

So the line $y=x$ has an order of rotation of $2.$

Rotational symmetry in circles

A regular hexagon has an order of rotation of $6,$ an octagon has an order of rotation of $8,$ and a dodecagon has an order of rotation of $12.$ But what about a circle?

A circle can be rotated around its center and the shape will remain identical as the radius is the same for every point on the circumference of the circle.

This means that the order of rotational symmetry for a circle is infinite.

What is rotational symmetry?

Common Core State Standards

How does this relate to high school math?

High school: Geometry – Congruence (HS.G.CO.A.3)
Given a rectangle, parallelogram, trapezoid, or regular polygon, describe the rotations and reflections that carry it onto itself.

How to calculate the order of rotational symmetry

In order to calculate the order of rotational symmetry:

Locate the center of the 2D shape.
Trace the shape onto a piece of tracing paper including the center and northline.
Rotate the tracing around the center and count the number of identical occurrences.

Rotational symmetry examples

Example 1: the isosceles triangle

Calculate the order of rotation for the isosceles triangle below.

Locate the center of the 2D shape.

Draw a small $x$ in the center of the triangle (draw a line from each vertex to the midpoint of the line opposite).

2Trace the shape onto a piece of tracing paper including the center and northline.

Here you use tracing paper to trace the shape, including the center of the shape and an upward arrow (northline). The northline shows us when the shape is facing the original orientation.

3Rotate the tracing around the center and count the number of identical occurrences.

Rotating the shape around the center, you have to turn the shape all $360^{\circ}$ before the traced image looks identical to the original.

The isosceles triangle has a rotational symmetry of order $0.$

Example 2: the regular hexagon

Calculate the order of rotational symmetry for a regular hexagon.

Locate the center of the 2D shape.

Draw a small $x$ in the center of the hexagon (join the opposing vertices together to locate the center).

Trace the shape onto a piece of tracing paper including the center and northline.

As the regular hexagon has a lot of vertices, it is useful to also draw a dot in one vertex so you don’t lose sight of what the original looks like.

Rotate the tracing around the center and count the number of identical occurrences.

Rotating the shape around the center, there are multiple occasions when the shape is identical to the original. Below are multiple stages of the rotation:

By placing a dot in each position when the shape is identical, you can count the order of rotation once the shape has been rotated $360^{\circ}$ around the center.

The regular hexagon has a rotational symmetry of order $6.$

Tip: a shape cannot have a rotational symmetry of $1$ but you include the original orientation if the shape has a rotational symmetry.

Example 3: using angles

Calculate the rotational symmetry of the octagon below.

Locate the center of the 2D shape.

Draw a small $x$ in the center of the hexagon (join the opposing vertices together to locate the center).

Trace the shape onto a piece of tracing paper including the center and northline.

Being able to visualize the rotation without tracing is a difficult skill, however, for this example, as the shape is not drawn accurately, you cannot use the trace method. Instead, you need to think about the angles in the shape and whether or not the angles would match when you rotate the shape.

If you rotate the shape through $90$ degrees, you can see that the angles in the octagon look like this:

If you compare it to the original, you can see that the angles do not match, so let’s continue to rotate the shape clockwise:

Now you have rotated the shape to $180^{\circ}$ from the original, you can see that the size of the angles match their original position.

Rotate the tracing around the center and count the number of identical occurrences.

If you rotated the shape a further $90$ degrees, this would also not match the original and then you return the shape back to the original position.

This means that the order of rotational symmetry for this octagon is $2.$

Tip: Divide the angle at the center by the number of sides in the shape. This angle can be used to rotate the shape around. For example, a hexagon can be rotated by an angle of $60^{\circ}$ clockwise six times to complete a full turn, a rectangle can be rotated $90^{\circ}$ clockwise four times to complete a full turn.

Example 4: angle facts

The shape $ABCD$ has two pairs of parallel sides. Use angle facts to calculate the order of rotation for the shape $ABCD.$

Locate the center of the 2D shape.

To find the center of the shape, join the diagonals together. Here you have:

Next, you need to calculate all of the interior angles of the shape and use them to calculate the order of rotation:

$BAD = 180 - 55 = 125^{\circ}$ (co-interior angles total $180^{\circ}$ )

$BCD = 180 - 55 = 125^{\circ}$ (angles on a straight line total $180^{\circ}$ )

$ABC = 180 - 125 = 55^{\circ}$ (co-interior angles total $180^{\circ}$ )

You now have the following information:

Trace the shape onto a piece of tracing paper including the center and northline.

Again, you are going to try visualizing the rotation without tracing paper. As the shape is a quadrilateral, you will visualize turning the object through four $90$ -degree turns in a clockwise direction and see if the angles match.

By rotating the shape $90^{\circ}$ clockwise, you get a shape that is not exactly like the original.

Continuing this by another $90$ -degree rotation, you get

Rotate the tracing around the center and count the number of identical occurrences.

If you rotated the shape a further $90$ degrees, this would also not match the original and then you return the shape back to the original position.

The order of rotational symmetry for the shape $ABCD$ (which is a parallelogram) is $2.$

Example 5: cubic graph

Calculate the order of rotational symmetry for the cubic graph $y=x^3+2$ around the center $(0,2).$

Locate the center of the 2D shape.

You know the center $(0,2)$ so let us draw it onto the graph:

Trace the shape onto a piece of tracing paper including the center and northline.

As the shape is now a graph, sketch the graph onto a piece of tracing paper. You do not need to include the axes as it is the graph that is important.

Rotate the tracing around the center and count the number of identical occurrences.

If you turn the tracing $180^{\circ}$ around the point $(0,2)$ you get a match with the original. This is the only occurrence along with the original and so the order of rotation for the cubic graph $y=x^3+2$ around the point $(0,2)$ is $2.$

Example 6: sine graph

Calculate the order of rotational symmetry for the graph $y=\sin (\theta)$ around the origin.

Locate the center of the 2D shape.

The center of rotation is given as the origin, so let us highlight this point on the graph:

Trace the shape onto a piece of tracing paper including the center and northline.

Rotate the tracing around the center and count the number of identical occurrences.

Here, you can only get an exact copy of the original image by rotating the tracing paper around the origin once excluding the original image.

The order of rotational symmetry for the graph of $y=\sin (\theta)$ is $2.$

Teaching tips for rotational symmetry

Allow students to trace shapes on transparent paper or use plastic sheets, and rotate them to see how they fit over the original position.

Use animations to visually demonstrate how shapes look the same after certain rotations.

Provide cut-out shapes that students can physically rotate to observe rotational symmetry.

Provide rotational symmetry worksheets with examples of shapes with various orders of rotational symmetry. Use shapes like squares, equilateral triangles, and regular hexagons.

Easy mistakes to make

Confusing rotational symmetry with lines of symmetry
Lines of symmetry are mixed up with rotational symmetry. A line of symmetry divides the shape equally into two symmetrical pieces. A rotational symmetry is the number of times a shape fits into itself when rotated around its center.

Thinking a shape can have an order of rotational symmetry of $\bf{1}$
A shape cannot have an order of rotational symmetry of $1.$ If a shape had a rotational symmetry of order $1,$ it would mean that it looks the same only after a full rotation of $360^{\circ},$ which is true for all shapes.

The original shape is included if the shape has a rotational symmetry, so you must always have a rotational symmetry of at least $2.$ Saying a shape has rotational symmetry of order $1$ is essentially saying it has no rotational symmetry at all.

Thinking that the number of sides $\bf{=}$ the order of rotational symmetry
Although this is true for regular shapes, this is not true for many rotationally symmetric shapes.

Practice rotational symmetry questions

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Rotational Symmetry 31 US

Labeling one corner and the center, if you rotate the polygon around the center, the kite rotates $360^{\circ}$ before it looks like the original so it has no rotational symmetry.

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Rotational Symmetry 33 US

Labeling one corner and the center, if you rotate the polygon around the center, the pentagon rotates $360^{\circ}$ before it looks like the original so it has no rotational symmetry.

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Rotational Symmetry 35 US

Labeling one corner and the center, if you rotate the polygon around the center, the polygon can rotate $90^{\circ}$ before it looks like the original. Placing a dot for each time the polygon fits (a further $3$ rotations of $90^{\circ}$ ) so it has a rotational symmetry of $4.$

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Rotational Symmetry 37 US

All the interior angles are equal to $120^{\circ}$ and all sides are equal length.

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Rotational Symmetry 39 US

Rotating the graph $180^{\circ}$ around the point $(0,- \, 2),$ you get an identical image of the original. A further rotation of $180^{\circ}$ returns the shape back to the original and so it has an order of rotation of $2.$

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Rotational Symmetry 41 US

When rotated $180^{\circ},$ this is the result. This is not identical to the original.

Rotational Symmetry 42 US

Rotational symmetry FAQs

What is rotational symmetry?

Rotational symmetry is the number of times a shape can “fit into itself” as it is rotated $360^{\circ}$ about its center.

How do you find the order of rotational symmetry?

To find the order of rotational symmetry of a shape, identify the center of the shape, rotate the shape around its center, and count how many times the shape matches its original position in one full $360^{\circ}$ rotation.

What is the difference between rotational symmetry and reflectional symmetry?

Rotational symmetry involves rotating a shape around a center point to see if it looks the same; reflectional symmetry (or mirror symmetry) involves flipping the shape over a line (the line of symmetry) to see if it looks the same.

The next lessons are

Angles in polygons
Congruence and similarity
Transformations

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