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・ Hypercompe ockendeni
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・ Hyperbolic law of cosines
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Hyperbolic motion
・ Hyperbolic motion (relativity)
・ Hyperbolic navigation
・ Hyperbolic orthogonality
・ Hyperbolic partial differential equation
・ Hyperbolic plane (disambiguation)
・ Hyperbolic point
・ Hyperbolic quaternion
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・ Hyperbolic sector
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・ Hyperbolic tetrahedral-octahedral honeycomb


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Hyperbolic motion : ウィキペディア英語版
Hyperbolic motion

In geometry, hyperbolic motions are isometric automorphisms of a hyperbolic space. Under composition of mappings, the hyperbolic motions form a continuous group. This group is said to characterize the hyperbolic space. Such an approach to geometry was cultivated by Felix Klein in his Erlangen program. The idea of reducing geometry to its characteristic group was developed particularly by Mario Pieri in his reduction of the primitive notions of geometry to merely point and ''motion''.
Hyperbolic motions are often taken from inversive geometry: these are mappings composed of reflections in a line or a circle (or in a hyperplane or a hypersphere for hyperbolic spaces of more than two dimensions). To distinguish the hyperbolic motions, a particular line or circle is taken as the ''absolute''. The proviso is that the absolute must be an invariant set of all hyperbolic motions. The absolute divides the plane into two connected components, and hyperbolic motions must ''not'' permute these components.
One of the most prevalent contexts for inversive geometry and hyperbolic motions is in the study of mappings of the complex plane by Möbius transformations. Textbooks on complex functions often mention two common models of hyperbolic geometry: the Poincaré half-plane model where the absolute is the real line on the complex plane, and the Poincaré disk model where the absolute is the unit circle in the complex plane.
Hyperbolic motions can also be described on the hyperboloid model of hyperbolic geometry.〔Miles Reid & Balázs Szendröi (2005) ''Geometry and Topology'', §3.11 Hyperbolic motions, Cambridge University Press, ISBN 0-521-61325-6, 〕
This article exhibits these examples of the use of hyperbolic motions: the extension of the metric d(a,b) = \vert \log(b/a) \vert to the half-plane, and in the location of a quasi-sphere of a hypercomplex number system.

==Introduction of metric in upper half-plane==

The points of the upper half-plane model HP are given in Cartesian coordinates as or in polar coordinates as .The hyperbolic motions will be taken to be a composition of three fundamental hyperbolic motions.
Let ''p'' = (''x,y'') or ''p'' = (''r'' cos ''a'', ''r'' sin ''a''), ''p'' ∈ HP. The fundamental motions are:
: ''p'' → ''q'' = (''x'' + ''c'', ''y'' ), ''c'' ∈ R (left or right shift)
: ''p'' → ''q'' = (''sx'', ''sy'' ), ''s'' > 0 (dilation)
: ''p'' → ''q'' = ( ''r'' −1 cos ''a'', ''r'' −1 sin ''a'' ) (inversion in unit semicircle).
Note: the shift and dilation are mappings from inversive geometry composed of a pair of reflections in vertical lines or concentric circles respectively.

抄文引用元・出典: フリー百科事典『 ウィキペディア(Wikipedia)
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