Hyperbolic rotation
A hyperbolic rotation is a transformation of the hyperbolic plane which
has only one fix point. A hyperbolic rotation is the composition of two
reflections which cut in the fix point.
We can find the hyperbolic rotation of a point from the tools just
selecting two points of a hyperbolic line. To construct the tool for
obtaining the hyperbolic reflection of a point, we first plot the hyperbolic line and
then we use the inversion
tool to plot the image of the point, that's to say, the hyperbolic
reflection of the point.
To create
the tool we mark the fix point P
and the rotation angle. Then, we follow these steps:
(1) Construct the hyperbolic
circle with center P and
point, the point we want to transform, Q. The image point must lie in this
hyperbolic circle.
(2)As the Half-Plane Model is conformal with the
Euclidean plane we can make the Euclidean rotation with the same
center.
To obtain the point we have to rotate:
(3) Plot the hyperbolic line which contains the
center and the point which we want to transform.
(4) Plot the tangent line at P.
(5) Plot the perpendicular euclidean
line to the tangent line at P.
(6) Consider the intersection between the
lines plotted at steps (5) and (6).
(7) Rotate (euclidean rotation) the intersection
point at (6) and with the fixed angle and center the point P.
(8) Plot the euclidean line which contains P and the rotated point. This line
is the tangent to the hyperbolic line which contains the image for the
hyperbolic rotated point Q.
(9) Plot the euclidean circle with center at
the boundary line and passing through P
which has as tangent the line in (8).
(10) Consider the intersection between the circle
just constructed and the hyperbolic circle plotted at (1). This is the
hyperbolic rotation of Q.
The macro
we have created allows also to rotate segments,
triangles and circles. To construct this other tools we just transform
each of the defining points and then we construct again the object from
the images points.
Note
that the rotation of the hyperbolic circles with center the fix point
are invariant. From this fact, we obtain the name hyperbolic rotation.
In the next figure it
is plotted the rotation of a circle, which is not invariant.
Hyperbolic geometry
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