Video Crash Courses
Want to watch animated videos and solve interactive exercises about rotational symmetry?
When you rotate a figure, you move it along an arc.
It is often said that something rotates “about an axis.” That means that it rotates around something fixed. In the picture you can see a monkey sitting on a swing. When the monkey swings, it moves in an arc—and not in a straight line. Curved movement like this is called rotation. In this case, the axis the monkey is rotating about is the pole the swing is attached to.
This monkey has been rotated. The monkey is the same size as before, but it has moved to a different point on the arc of the swing. When you rotate a figure, it’s important that the figure itself stays the same through the rotation. The only difference should be that the figure is tilted relative to the original figure. Below, you will take a closer look at rotation, both on its own, and combined with translation.
Example 1
Rotate a phone clockwise about an axis from the phone. You can decide where to put the axis.
Draw the axis on a sheet of paper. Draw a cm long line from the axis in any direction. Place the phone where the line ends, measure with your protractor, and mark the point where the protractor shows . Imagine that there is an invisible and taut piece of string tied between each corner of the phone and the axis (like a swing). The strings will help you keep the orientation of the phone correct. Move your phone to the point you marked.
Example 2
Rotate a phone clockwise about its own axis, and translate it to the right
You begin by rotating the phone as in Example 1, except this time you rotate it . Then you translate the rotated phone cm to the right.
When you rotate a figure about a point , you need to know how many degrees the figure should be rotated. There are two ways to do this: one for rotating , and one for all rotations that are not . Below are instructions for both.
The figure shows a triangle rotated .
Rule
This figure shows a point rotated about a point :
Rule
Think About This
Why do you think rotation about a point is the same as reflection about a line?