Hyperboloid model


In geometry, the hyperboloid model, also known as the Minkowski model after Hermann Minkowski is a model of n-dimensional hyperbolic geometry in which points are represented by the points on the forward sheet S+ of a two-sheeted hyperboloid in -dimensional Minkowski space and m-planes are represented by the intersections of the -planes in Minkowski space with S+. The hyperbolic distance function admits a simple expression in this model. The hyperboloid model of the n-dimensional hyperbolic space is closely related to the Beltrami–Klein model and to the Poincaré disk model as they are projective models in the sense that the isometry group is a subgroup of the projective group.

Minkowski quadratic form

If is a vector in the -dimensional coordinate space Rn+1, the Minkowski quadratic form is defined to be
The vectors such that form an n-dimensional hyperboloid S consisting of two connected components, or sheets: the forward, or future, sheet S+, where x0>0 and the backward, or past, sheet S, where x0<0. The points of the n-dimensional hyperboloid model are the points on the forward sheet S+.
The Minkowski bilinear form B is the polarization of the Minkowski quadratic form Q,
Explicitly,
The hyperbolic distance between two points u and v of S+ is given by the formula
where inverse hyperbolic function| is the inverse function of hyperbolic cosine.

Straight lines

A straight line in hyperbolic n-space is modeled by a geodesic on the hyperboloid. A geodesic on the hyperboloid is the intersection of the hyperboloid with a two-dimensional linear subspace of the n+1-dimensional Minkowski space. If we take u and v to be basis vectors of that linear subspace with
and use w as a real parameter for points on the geodesic, then
will be a point on the geodesic.
More generally, a k-dimensional "flat" in the hyperbolic n-space will be modeled by the intersection of the hyperboloid with a k+1-dimensional linear subspace of the Minkowski space.

Isometries

The indefinite orthogonal group O, also called the
-dimensional Lorentz group, is the Lie group of real × matrices which preserve the Minkowski bilinear form. In a different language, it is
the group of linear isometries of the Minkowski space. In particular, this group preserves the hyperboloid S. Recall that indefinite orthogonal groups have four connected components, corresponding to reversing or preserving the orientation on each subspace, and form a Klein four-group. The subgroup of O that preserves the sign of the first coordinate is the orthochronous Lorentz group, denoted O+, and has two components, corresponding to preserving or reversing the orientation of the spatial subspace. Its subgroup SO+ consisting of matrices with determinant one is a connected Lie group of dimension n/2 which acts on S+ by linear automorphisms and preserves the hyperbolic distance. This action is transitive and the stabilizer of the vector consists of the matrices of the form
Where belongs to the compact special orthogonal group SO. It follows that the n-dimensional hyperbolic space can be exhibited as the homogeneous space and a Riemannian symmetric space of rank 1,
The group SO+ is the full group of orientation-preserving isometries of the n-dimensional hyperbolic space.

History

The hyperboloid was explored as a metric space by Alexander Macfarlane in his Papers in Space Analysis. He noted that points on the hyperboloid could be written as
where α is a basis vector orthogonal to the hyperboloid axis. For example, he obtained the hyperbolic law of cosines through use of his
Algebra of Physics.
H. Jansen made the hyperboloid model the explicit focus of his 1909 paper "Representation of hyperbolic geometry on a two sheeted hyperboloid".
In 1993 W.F. Reynolds recounted some of the early history of the model in his article in the American Mathematical Monthly.
Being a commonplace model by the twentieth century, it was identified with the Geschwindigkeitsvectoren by Hermann Minkowski in his 1907 Göttingen lecture 'The Relativity Principle'. Scott Walter, in his 1999 paper "The Non-Euclidean Style of Minkowskian Relativity" recalls Minkowski's awareness, but traces the lineage of the model to Hermann Helmholtz rather than Weierstrass and Killing.
In the early years of relativity the hyperboloid model was used by Vladimir Varićak to explain the physics of velocity. In his speech to the German mathematical union in 1912 he referred to Weierstrass coordinates.