Lines through a given point P and asymptotic to line R.
A triangle immersed in a saddleshape plane (a
hyperbolic paraboloid), as well as two diverging ultraparallel lines.
In mathematics, hyperbolic geometry (also called Lobachevskian geometry or Bolyai–Lobachevskian geometry) is a nonEuclidean geometry, meaning that the parallel postulate of Euclidean geometry is replaced. The parallel postulate in Euclidean geometry is equivalent to the statement that, in twodimensional space, for any given line R and point P not on R, there is exactly one line through P that does not intersect R; i.e., that is parallel to R. In hyperbolic geometry there are at least two distinct lines through P which do not intersect R, so the parallel postulate is false. Models have been constructed within Euclidean geometry that obey the axioms of hyperbolic geometry, thus proving that the parallel postulate is independent of the other postulates of Euclid.
Because there is no precise hyperbolic analogue to Euclidean parallel lines, the hyperbolic use of parallel and related terms varies among writers. In this article, the two limiting lines are called asymptotic and lines sharing a common perpendicular are called ultraparallel; the simple word parallel may apply to both.
A characteristic property of hyperbolic geometry is that the angles of a triangle add to less than a straight angle, or 180°. In the limit, as the side lengths approach infinity, there are even ideal hyperbolic triangles in which all three angles are 0°.
Contents

Nonintersecting lines 1

Triangles 2

Circles, disks, spheres and balls 3

History 4

Models of the hyperbolic plane 5

Other models of the hyperbolic plane 5.1

Connection between the models 5.2

Visualizing hyperbolic geometry 6

Homogeneous structure 7

See also 8

Notes 9

References 10

External links 11
Nonintersecting lines
An interesting property of hyperbolic geometry follows from the occurrence of more than one line parallel to R through a point P, not on R: there are two classes of nonintersecting lines. Let B be the point on R such that the line PB is perpendicular to R. Consider the line x through P such that x does not intersect R, and the angle θ between PB and x counterclockwise from PB is as small as possible; i.e., any smaller angle will force the line to intersect R. This is called an asymptotic line in hyperbolic geometry. Symmetrically, the line y that forms the same angle θ between PB and itself but clockwise from PB will also be asymptotic. The only two lines asymptotic to R through P are x and y. All other lines through P not intersecting R, with angles greater than θ with PB, are called ultraparallel (or disjointly parallel) to R. Notice that since there are an infinite number of possible angles between θ and 90°, and each one will determine two lines through P and disjointly parallel to R, there exist an infinite number of ultraparallel lines.
Thus we have this modified form of the parallel postulate: In hyperbolic geometry, given any line R, and point P not on R, there are exactly two lines through P which are asymptotic to R, and infinitely many lines through P ultraparallel to R.
The differences between these types of lines can also be looked at in the following way: the distance between asymptotic lines shrinks toward zero in one direction and grows without bound in the other; the distance between ultraparallel lines (eventually) increases in both directions. The ultraparallel theorem states that there is a unique line in the hyperbolic plane that is perpendicular to each of a given pair of ultraparallel lines.
In Euclidean geometry, the "angle of parallelism" is a constant; that is, any distance \lVert BP \rVert between parallel lines yields an angle of parallelism equal to 90°. In hyperbolic geometry, the angle of parallelism varies with the Π(p) function. This function, described by Nikolai Ivanovich Lobachevsky, produces a unique angle of parallelism for each distance p = \lVert BP \rVert. As the distance gets shorter, Π(p) approaches 90°, whereas with increasing distance Π(p) approaches 0°. Thus, as distances get smaller, the hyperbolic plane behaves more and more like Euclidean geometry. Indeed, on small scales compared to \frac{1}{\sqrt{K}}, where K is the (constant) Gaussian curvature of the plane, an observer would have a hard time determining whether the environment is Euclidean or hyperbolic.
Triangles
Distances in the hyperbolic plane can be measured in terms of a unit of length R = \frac{1}{\sqrt{K}}, analogous to the radius of the sphere in spherical geometry. Using this unit of length a theorem in hyperbolic geometry can be stated which is analogous to the Pythagorean theorem. If a, b are the legs and c is the hypotenuse of a right triangle all measured in this unit then:


\cosh c=\cosh a\cosh b\,.
The cosh function is a hyperbolic function which is an analog of the standard cosine function. All six of the standard trigonometric functions have hyperbolic analogs. In trigonometric relations involving the sides and angles of a hyperbolic triangle the hyperbolic functions are applied to the sides and the standard trigonometric functions are applied to the angles. For example the law of sines for hyperbolic triangles is:

\frac{\sin A}{\sinh a} = \frac{\sin B}{\sinh b} = \frac{\sin C}{\sinh c}.
For more of these trigonometric relationships see hyperbolic triangles.
Unlike Euclidean triangles whose angles always add up to 180° or π radians the sum of the angles of a hyperbolic triangle is always strictly less than 180°. The difference is sometimes referred to as the defect. The area of a hyperbolic triangle is given by its defect multiplied by R² where R = \frac{1}{\sqrt{K}}. As a consequence all hyperbolic triangles have an area which is less than R²π. The area of a hyperbolic ideal triangle is equal to this maximum.
As in spherical geometry the only similar triangles are congruent triangles.
Circles, disks, spheres and balls
In hyperbolic geometry the circumference of a circle of radius r is greater than 2πr. It is in fact equal to

2\pi R \sinh \frac{r}{R} \,.
The area of the enclosed disk is

2\pi R^2 (\cosh \frac{r}{R}  1) \,.
The surface area of a sphere is

4\pi R^2 \sinh^2 \frac{r}{R} \,.
The volume of the enclosed ball is

\pi R^3 \sinh \frac{2r}{R}  2\pi R^2r \,.
For the measure of an n1 sphere in n dimensional space the corresponding expression is

\Omega_{n} R^{n1} \sinh^{n1} \frac{r}{R} \,
where the full ndimensional solid angle is

\Omega_{n}=\frac{2\pi^{n/2}}{\Gamma \left (\frac{n}{2} \right )} \,
using \Gamma \, for the Gamma function.
The measure of the enclosed n ball is:

\Omega_{n} R^{n1} \int_0^r \sinh^{n1} \frac{s}{R}ds \,.
History
A number of geometers made attempts to prove the parallel postulate by assuming its negation and trying to derive a contradiction, including Proclus, Ibn alHaytham (Alhacen), Omar Khayyám,^{[1]} Nasir alDin alTusi, Witelo, Gersonides, Alfonso, and later Giovanni Gerolamo Saccheri, John Wallis, Johann Heinrich Lambert, and Legendre.^{[2]} Their attempts failed, but their efforts gave birth to hyperbolic geometry.
The theorems of Alhacen, Khayyam and alTusi on quadrilaterals, including the Ibn alHaytham–Lambert quadrilateral and Khayyam–Saccheri quadrilateral, were the first theorems on hyperbolic geometry. Their works on hyperbolic geometry had a considerable influence on its development among later European geometers, including Witelo, Gersonides, Alfonso, John Wallis and Saccheri.^{[3]}
In the 18th century, Johann Heinrich Lambert introduced the hyperbolic functions^{[4]} and computed the area of a hyperbolic triangle.^{[5]}
In the nineteenth century, hyperbolic geometry was extensively explored by János Bolyai and Nikolai Ivanovich Lobachevsky, after whom it sometimes is named. Lobachevsky published in 1830, while Bolyai independently discovered it and published in 1832. Carl Friedrich Gauss also studied hyperbolic geometry, describing in an 1824 letter to Taurinus that he had constructed it, but did not publish his work. In 1868, Eugenio Beltrami provided models of it, and used this to prove that hyperbolic geometry was consistent if Euclidean geometry was.
The term "hyperbolic geometry" was introduced by Felix Klein in 1871.^{[6]}
For more history, see article on nonEuclidean geometry, and the references Coxeter and Milnor.
Models of the hyperbolic plane
Lines through a given point and parallel to a given line, illustrated in the Poincaré disc model
There are four models commonly used for hyperbolic geometry: the Klein model, the Poincaré disc model, the Poincaré halfplane model, and the Lorentz model, or hyperboloid model. These models define a real hyperbolic space which satisfies the axioms of a hyperbolic geometry. Despite their names, the first three mentioned above were introduced as models of hyperbolic space by Beltrami, not by Poincaré or Klein.

The Klein model, also known as the projective disc model and Beltrami–Klein model, uses the interior of a circle for the hyperbolic plane, and chords of the circle as lines.

The Poincaré disc model, also known as the conformal disc model, also employs the interior of a circle, but lines are represented by arcs of circles that are orthogonal to the boundary circle, plus diameters of the boundary circle.

The Poincaré halfplane model takes onehalf of the Euclidean plane, as determined by a Euclidean line B, to be the hyperbolic plane (B itself is not included).

Hyperbolic lines are then either halfcircles orthogonal to B or rays perpendicular to B.

Both Poincaré models preserve hyperbolic angles, and are thereby conformal. All isometries within these models are therefore Möbius transformations.

The halfplane model is identical (at the limit) to the Poincaré disc model at the edge of the disc

The Lorentz model or hyperboloid model employs a 2dimensional hyperboloid of revolution (of two sheets, but using one) embedded in 3dimensional Minkowski space. This model is generally credited to Poincaré, but Reynolds (see below) says that Wilhelm Killing and Karl Weierstrass used this model from 1872.

This model has direct application to special relativity, as Minkowski 3space is a model for spacetime, suppressing one spatial dimension. One can take the hyperboloid to represent the events that various moving observers, radiating outward in a spatial plane from a single point, will reach in a fixed proper time. The hyperbolic distance between two points on the hyperboloid can then be identified with the relative rapidity between the two corresponding observers.
Other models of the hyperbolic plane

The Gans model or flattened hyperboloid model
In 1966 David Gans proposed this model in the journal American Mathematical Monthly ^{[7]} This model is not as widely used as other models but nevertheless is quite useful in the understanding of hyperbolic geometry.

Unlike the Klein or the Poincaré model, this model utilizes the entire Euclidean plane.

The lines in this model are interpreted as the branches of a hyperbola.^{[8]}
Connection between the models



Poincaré disk, hemispherical and hyperboloid models are related by central projection from −1. Klein disk model is vertical projection from hemispheric model. Poincaré halfplane model here projected from the hemisphere model by rays from left end of Poincaré disk model.
The four models essentially describe the same structure. The difference between them is that they represent different coordinate charts laid down on the same metric space, namely the hyperbolic space. The characteristic feature of the hyperbolic space itself is that it has a constant negative scalar curvature, which is indifferent to the coordinate chart used. The geodesics are similarly invariant: that is, geodesics map to geodesics under coordinate transformation. Hyperbolic geometry generally is introduced in terms of the geodesics and their intersections on the hyperbolic space.^{[9]}
Once we choose a coordinate chart (one of the "models"), we can always embed it in a Euclidean space of same dimension, but the embedding is clearly not isometric (since the scalar curvature of Euclidean space is 0). The hyperbolic space can be represented by infinitely many different charts; but the embeddings in Euclidean space due to these four specific charts show some interesting characteristics.
Since the four models describe the same metric space, each can be transformed into the other. See, for example, the Beltrami–Klein model's relation to the hyperboloid model, the Beltrami–Klein model's relation to the Poincaré disk model, and the Poincaré disk model's relation to the hyperboloid model.
Visualizing hyperbolic geometry
M. C. Escher's famous prints Circle Limit III and Circle Limit IV illustrate the conformal disc model quite well. The white lines in III are not quite geodesics (they are hypercycles), but are quite close to them. It is also possible to see quite plainly the negative curvature of the hyperbolic plane, through its effect on the sum of angles in triangles and squares.
For example, in Circle Limit III every vertex belongs to three triangles and three squares. In the Euclidean plane, their angles would sum to 450°; i.e., a circle and a quarter. From this we see that the sum of angles of a triangle in the hyperbolic plane must be smaller than 180°. Another visible property is exponential growth. In Circle Limit III, for example, one can see that the number of fishes within a distance of n from the center rises exponentially. The fishes have equal hyperbolic area, so the area of a ball of radius n must rise exponentially in n.
There are several ways to physically realize a hyperbolic plane (or approximation thereof). A particularly wellknown paper model based on the pseudosphere is due to William Thurston. The art of crochet has been used to demonstrate hyperbolic planes with the first being made by Daina Taimina,^{[10]} whose book Crocheting Adventures with Hyperbolic Planes won the 2009 Bookseller/Diagram Prize for Oddest Title of the Year.^{[11]} In 2000, Keith Henderson demonstrated a quicktomake paper model dubbed the "hyperbolic soccerball". Instructions on how to make a hyperbolic quilt, designed by Helaman Ferguson,^{[12]} has been made available by Jeff Weeks.^{[13]}
Homogeneous structure
Hyperbolic space of dimension n is a special case of a Riemannian symmetric space of noncompact type, as it is isomorphic to the quotient


O(1,n)/(O(1) \times O(n)).
The orthogonal group O(1,n) acts by normpreserving transformations on Minkowski space R^{1,n}, and it acts transitively on the twosheet hyperboloid of norm 1 vectors. Timelike lines (i.e., those with positivenorm tangents) through the origin pass through antipodal points in the hyperboloid, so the space of such lines yields a model of hyperbolic nspace. The stabilizer of any particular line is isomorphic to the product of the orthogonal groups O(n) and O(1), where O(n) acts on the tangent space of a point in the hyperboloid, and O(1) reflects the line through the origin. Many of the elementary concepts in hyperbolic geometry can be described in linear algebraic terms: geodesic paths are described by intersections with planes through the origin, dihedral angles between hyperplanes can be described by inner products of normal vectors, and hyperbolic reflection groups can be given explicit matrix realizations.
In small dimensions, there are exceptional isomorphisms of Lie groups that yield additional ways to consider symmetries of hyperbolic spaces. For example, in dimension 2, the isomorphisms SO^{+}(1,2) ≅ PSL(2,R) ≅ PSU(1,1) allow one to interpret the upper half plane model as the quotient SL(2,R)/SO(2) and the Poincaré disc model as the quotient SU(1,1)/U(1). In both cases, the symmetry groups act by fractional linear transformations, since both groups are the orientationpreserving stabilizers in PGL(2,C) of the respective subspaces of the Riemann sphere. The Cayley transformation not only takes one model of the hyperbolic plane to the other, but realizes the isomorphism of symmetry groups as conjugation in a larger group. In dimension 3, the fractional linear action of PGL(2,C) on the Riemann sphere is identified with the action on the conformal boundary of hyperbolic 3space induced by the isomorphism O^{+}(1,3) ≅ PGL(2,C). This allows one to study isometries of hyperbolic 3space by considering spectral properties of representative complex matrices. For example, parabolic transformations are conjugate to rigid translations in the upper halfspace model, and they are exactly those transformations that can be represented by unipotent upper triangular matrices.
See also
Notes

^ See for instance, "Omar Khayyam 1048–1131". Retrieved 20080105.

^ http://www.math.columbia.edu/~pinkham/teaching/seminars/NonEuclidean.html

^ Boris A. Rosenfeld and Adolf P. Youschkevitch (1996), "Geometry", in Roshdi Rashed, ed., Encyclopedia of the History of Arabic Science, Vol. 2, p. 447–494 [470], Routledge, London and New York:
"Three scientists, Ibn alHaytham, Khayyam and alTusi, had made the most considerable contribution to this branch of geometry whose importance came to be completely recognized only in the nineteenth century. In essence their propositions concerning the properties of quadrangles which they considered assuming that some of the angles of these figures were acute of obtuse, embodied the first few theorems of the hyperbolic and the elliptic geometries. Their other proposals showed that various geometric statements were equivalent to the Euclidean postulate V. It is extremely important that these scholars established the mutual connection between this postulate and the sum of the angles of a triangle and a quadrangle. By their works on the theory of parallel lines Arab mathematicians directly influenced the relevant investigations of their European counterparts. The first European attempt to prove the postulate on parallel lines – made by Witelo, the Polish scientists of the thirteenth century, while revising Ibn alHaytham's Book of Optics (Kitab alManazir) – was undoubtedly prompted by Arabic sources. The proofs put forward in the fourteenth century by the Jewish scholar Levi ben Gerson, who lived in southern France, and by the abovementioned Alfonso from Spain directly border on Ibn alHaytham's demonstration. Above, we have demonstrated that PseudoTusi's Exposition of Euclid had stimulated both J. Wallis's and G. Saccheri's studies of the theory of parallel lines."

^ Eves, Howard (2012), Foundations and Fundamental Concepts of Mathematics, Courier Dover Publications, p. 59,

^ Ratcliffe, John (2006), Foundations of Hyperbolic Manifolds, Graduate Texts in Mathematics 149, Springer, p. 99,

^ F. Klein, Über die sogenannte NichtEuklidische, Geometrie, Math. Ann. 4, 573–625 (cf. Ges. Math. Abh. 1, 244–350).

^ [Gans David (1966). A New Model of the Hyperbolic Plane. American Mathematical Monthly, Vol. 73, Issue 3, March 1966.

^ http://www.d.umn.edu/cs/thesis/kedar_bhumkar_ms.pdf

^ Arlan Ramsay, Robert D. Richtmyer, Introduction to Hyperbolic Geometry, Springer; 1 edition (December 16, 1995)

^ "Hyperbolic Space". The Institute for Figuring. December 21, 2006. Retrieved January 15, 2007.

^ Bloxham, Andy (March 26, 2010). "Crocheting Adventures with Hyperbolic Planes wins oddest book title award".

^ "Helaman Ferguson, Hyperbolic Quilt".

^ "How to sew a Hyperbolic Blanket".
References

A'Campo, Norbert and Papadopoulos, Athanase, (2012) Notes on hyperbolic geometry, in: Strasbourg Master class on Geometry, pp. 1–182, IRMA Lectures in Mathematics and Theoretical Physics, Vol. 18, Zürich: European Mathematical Society (EMS), 461 pages, SBN ISBN 9783037191057, DOI 10.4171/105.

Coxeter, H. S. M., (1942) NonEuclidean geometry, University of Toronto Press, Toronto



Lobachevsky, Nikolai I., (2010) Pangeometry, Edited and translated by Athanase Papadopoulos, Heritage of European Mathematics, Vol. 4. Zürich: European Mathematical Society (EMS). xii, 310~p, ISBN 9783037190876/hbk

Milnor, John W., (1982) Hyperbolic geometry: The first 150 years, Bull. Amer. Math. Soc. (N.S.) Volume 6, Number 1, pp. 9–24.

Reynolds, William F., (1993) Hyperbolic Geometry on a Hyperboloid, American Mathematical Monthly 100:442–455.


Samuels, David., (March 2006) Knit Theory Discover Magazine, volume 27, Number 3.

James W. Anderson, Hyperbolic Geometry, Springer 2005, ISBN 1852339349

James W. Cannon, William J. Floyd, Richard Kenyon, and Walter R. Parry (1997) Hyperbolic Geometry, MSRI Publications, volume 31.
External links

Java freeware for creating sketches in both the Poincaré Disk and the Upper HalfPlane Models of Hyperbolic Geometry University of New Mexico

"The Hyperbolic Geometry Song" A short music video about the basics of Hyperbolic Geometry available at YouTube.

Hazewinkel, Michiel, ed. (2001), "Lobachevskii geometry",

Weisstein, Eric W., "Gauss–Bolyai–Lobachevsky Space", MathWorld.

Weisstein, Eric W., "Hyperbolic Geometry", MathWorld.

More on hyperbolic geometry, including movies and equations for conversion between the different models University of Illinois at UrbanaChampaign

Hyperbolic Voronoi diagrams made easy, Frank Nielsen

Stothers, Wilson (2000). "Hyperbolic geometry". , interactive instructional website.

Universal Hyperbolic Geometry II: A pictorial overview

Universal Hyperbolic Geometry III: First Steps in Projective Triangle Geometry

Hyperbolic Planar Tesselations
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