In hyperbolic geometry, an ideal point, omega point or point at infinity is a well-defined point outside the hyperbolic plane or space. Given a line ''l'' and a point ''P'' not on ''l'', right- and left- limiting parallels to ''l'' through ''P'' converge to ''l'' at ''ideal points''. Unlike the projective case, ideal points form a

boundary Boundary or Boundaries may refer to: * Border, in political geography Entertainment * ''Boundaries'' (2016 film), a 2016 Canadian film * ''Boundaries'' (2018 film), a 2018 American-Canadian road trip film * Boundary (cricket), the edge of the pl ...

, not a submanifold. So, these lines do not intersect at an ideal point and such points, although well-defined, do not belong to the hyperbolic space itself. The ideal points together form the Cayley absolute or boundary of a hyperbolic geometry. For instance, the unit circle forms the Cayley absolute of the Poincaré disk model and the Klein disk model. While the real line forms the Cayley absolute of the Poincaré half-plane model . Pasch's axiom and the exterior angle theorem still hold for an omega triangle, defined by two points in hyperbolic space and an omega point.

Properties

* The hyperbolic distance between an ideal point and any other point or ideal point is infinite. * The centres of

horocycle In hyperbolic geometry, a horocycle (), sometimes called an oricycle, oricircle, or limit circle, is a curve whose normal or perpendicular geodesics all converge asymptotically in the same direction. It is the two-dimensional case of a horosph ...

s and

horoball In hyperbolic geometry, a horosphere (or parasphere) is a specific hypersurface in hyperbolic ''n''-space. It is the boundary of a horoball, the limit of a sequence of increasing balls sharing (on one side) a tangent hyperplane and its point of ...

s are ideal points; two

s are

concentric In geometry, two or more objects are said to be concentric, coaxal, or coaxial when they share the same center or axis. Circles, regular polygons and regular polyhedra, and spheres may be concentric to one another (sharing the same center poin ...

when they have the same centre.

Polygons with ideal vertices

Ideal triangles

if all vertices of a triangle are ideal points the triangle is an

ideal triangle In hyperbolic geometry an ideal triangle is a hyperbolic triangle whose three vertices all are ideal points. Ideal triangles are also sometimes called ''triply asymptotic triangles'' or ''trebly asymptotic triangles''. The vertices are sometimes ...

. Some properties of ideal triangles include: * All ideal triangles are congruent. * The interior angles of an ideal triangle are all zero. * Any ideal triangle has an infinite perimeter. * Any ideal triangle has area

\pi / -K

where K is the (negative) curvature of the plane.

Ideal quadrilaterals

if all vertices of a quadrilateral are ideal points, the quadrilateral is an ideal quadrilateral. While all ideal triangles are congruent, not all quadrilaterals are; the diagonals can make different angles with each other resulting in noncongruent quadrilaterals. Having said this: * The interior angles of an ideal quadrilateral are all zero. * Any ideal quadrilateral has an infinite perimeter. * Any ideal (convex non intersecting) quadrilateral has area

2 \pi / -K

where K is the (negative) curvature of the plane.

Ideal square

The ideal quadrilateral where the two diagonals are

perpendicular In elementary geometry, two geometric objects are perpendicular if they intersect at a right angle (90 degrees or π/2 radians). The condition of perpendicularity may be represented graphically using the ''perpendicular symbol'', ⟂. It can ...

to each other form an ideal square. It was used by Ferdinand Karl Schweikart in his memorandum on what he called "astral geometry", one of the first publications acknowledging the possibility of hyperbolic geometry.

Ideal ''n''-gons

An ideal ''n''-gon can be subdivided into ideal triangles, with area times the area of an ideal triangle.

Representations in models of hyperbolic geometry

In the Klein disk model and the Poincaré disk model of the hyperbolic plane the ideal points are on the unit circle (hyperbolic plane) or unit sphere (higher dimensions) which is the unreachable boundary of the hyperbolic plane. When projecting the same hyperbolic line to the Klein disk model and the Poincaré disk model both lines go through the same two ideal points (the ideal points in both models are on the same spot).

Klein disk model

Given two distinct points ''p'' and ''q'' in the open unit disk the unique straight line connecting them intersects the unit circle in two ideal points, ''a'' and ''b'', labeled so that the points are, in order, ''a'', ''p'', ''q'', ''b'' so that , aq, > , ap, and , pb, > , qb, . Then the hyperbolic distance between ''p'' and ''q'' is expressed as :

d(p,q) = \frac \log \frac ,

Poincaré disk model

Given two distinct points ''p'' and ''q'' in the open unit disk then the unique circle arc orthogonal to the boundary connecting them intersects the unit circle in two ideal points, ''a'' and ''b'', labeled so that the points are, in order, ''a'', ''p'', ''q'', ''b'' so that , aq, > , ap, and , pb, > , qb, . Then the hyperbolic distance between ''p'' and ''q'' is expressed as :

d(p,q) =  \log \frac ,

Where the distances are measured along the (straight line) segments aq, ap, pb and qb.

Poincaré half-plane model

In the Poincaré half-plane model the ideal points are the points on the boundary axis. There is also another ideal point that is not represented in the half-plane model (but rays parallel to the positive y-axis approach it).

Hyperboloid model

In the hyperboloid model there are no ideal points.

References

{{reflist Hyperbolic geometry Infinity