In hyperbolic geometry, two lines are said to be ultraparallel if they do not intersect and are not limiting parallel.
The ultraparallel theorem states that every pair of (distinct) ultraparallel lines has a unique common perpendicular (a hyperbolic line which is perpendicular to both lines).
Let and be two ultraparallel lines.
From any two distinct points and on s draw and perpendicular to with and on .
If it happens that AB = CB', then the desired common perpendicular joins the midpoints of AC and BB' (by the symmetry of the Saccheri quadrilateral ACB'B).
If not, we may suppose AB < CB' without loss of generality. Let E be a point on the line s on the opposite side of A from C. Take A' on CB' so that A'B' = AB. Through A' draw a line s' (A'E') on the side closer to E, so that the angle B'A'E' is the same as angle BAE. Then s' meets s in an ordinary point D'. Construct a point D on ray AE so that AD = A'D'.
Then D' ≠ D. They are the same distance from r and both lie on s. So the perpendicular bisector of D'D (a segment of s) is also perpendicular to r.[1]
(If r and s were asymptotically parallel rather than ultraparallel, this construction would fail because s' would not meet s. Rather s' would be limiting parallel to both s and r.)
Let
a<b<c<d
be four distinct points on the abscissa of the Cartesian plane. Let
p
q
ab
cd
p
q
Compose the following two hyperbolic motions:
x\tox-a
inversionintheunitsemicircle.
Then
a\toinfty, b\to(b-a)-1, c\to(c-a)-1, d\to(d-a)-1.
Now continue with these two hyperbolic motions:
x\tox-(b-a)-1
x\to\left[(c-a)-1-(b-a)-1\right]-1x
Then
a
infty
b\to0
c\to1
d\toz
1z
\begin{matrix}
| 1 | |
| 2 |
\end{matrix}(z+1)
\begin{matrix}
| 1 | |
| 2 |
\end{matrix}(z-1)
1z
| 1 | |
| 4 |
\left[(z+1)2-(z-1)2\right]=z.
The four hyperbolic motions that produced
z
\sqrt{z}
p
q
In the Beltrami-Klein model of the hyperbolic geometry:
If one of the chords happens to be a diameter, we do not have a pole, but in this case any chord perpendicular to the diameter it is also perpendicular in the Beltrami-Klein model, and so we draw a line through the pole of the other line intersecting the diameter at right angles to get the common perpendicular.
The proof is completed by showing this construction is always possible:
Alternatively, we can construct the common perpendicular of the ultraparallel lines as follows: the ultraparallel lines in Beltrami-Klein model are two non-intersecting chords. But they actually intersect outside the circle. The polar of the intersecting point is the desired common perpendicular.[2]