A rotation is a transformation of a figure by turning it about a point called the point of rotation. The amount of rotation can be expressed in the number of degress. The direction of the rotation for two-dimensional figures can be described in the clockwise or counterclockwise direction. When it is not specified we assume the direction is counterclockwise.
A rotation can be denoted in functional notation in the form R_{\theta\degree,P}(\text{Shape being rotated}) where \theta\degree is the measure of the directed angle (the angle of rotation in the counterclockwise direction) and P is the point of rotation. For any point being rotated, the function representation R_{\theta\degree,P}\left(A\right)=A\rq means that m\angle APA\rq=\theta\degree, and also that AP=A\rq P.
If the input for a rotation is a figure, then we will have that any corresponding points, A and A\rq, in the pre-image and image will have these relationships.
When rotated about the origin, the transformation mappings are as follows:
If the point of rotation is not at the origin we will not have such nice transformation maps, but the principles of rotation remain the same.
If a rotation maps a figure onto itself, then we say that the figure has rotational symmetry about that point. We can call that point the shape's center of rotation.
\overline{AB} has been rotated counterclockwise about the origin.
Describe the rotation required to map \overline{AB} to \overline{A'B'}.
Write the transformation mapping.
Consider the figure ABCD:
Determine the image of ABCD when rotated about the point A by 180\degree.
Determine the image of ABCD when rotated about the point \left(2,0\right) by 90\degree clockwise.
Identify the rotation(s) that map ABCD onto itself.
Sketch the result of the rotation R_{135\degree,B}\left(ABCD\right), using the figure ABCD that is shown.