词条 | Hyperbolic triangle |
释义 |
In hyperbolic geometry, a hyperbolic triangle is a triangle in the hyperbolic plane. It consists of three line segments called sides or edges and three points called angles or vertices. Just as in the Euclidean case, three points of a hyperbolic space of an arbitrary dimension always lie on the same plane. Hence planar hyperbolic triangles also describe triangles possible in any higher dimension of hyperbolic spaces. DefinitionA hyperbolic triangle consists of three non-collinear points and the three segments between them.[1] PropertiesHyperbolic triangles have some properties that are analogous to those of triangles in Euclidean geometry:
Hyperbolic triangles have some properties that are analogous to those of triangles in spherical or elliptic geometry:
Hyperbolic triangles have some properties that are the opposite of the properties of triangles in spherical or elliptic geometry:
Hyperbolic triangles also have some properties that are not found in other geometries:
Triangles with ideal verticesThe definition of a triangle can be generalized, permitting vertices on the ideal boundary of the plane while keeping the sides within the plane. If a pair of sides is limiting parallel (i.e. the distance between them approaches zero as they tend to the ideal point, but they do not intersect), then they end at an ideal vertex represented as an omega point. Such a pair of sides may also be said to form an angle of zero. A triangle with a zero angle is impossible in Euclidean geometry for straight sides lying on distinct lines. However, such zero angles are possible with tangent circles. A triangle with one ideal vertex is called an omega triangle. Special Triangles with ideal vertices are: Triangle of parallelismA triangle where one vertex is an ideal point, one angle is right: the third angle is the angle of parallelism for the length of the side between the right and the third angle. Schweikart triangleThe triangle where two vertices are ideal points and the remaining angle is right, one of the first hyperbolic triangles (1818) described by Ferdinand Karl Schweikart. Ideal triangle{{Main|Ideal triangle}}The triangle where all vertices are ideal points, an ideal triangle is the largest possible triangle in hyperbolic geometry because of the zero sum of the angles. Standardized Gaussian curvatureThe relations among the angles and sides are analogous to those of spherical trigonometry; the length scale for both spherical geometry and hyperbolic geometry can for example be defined as the length of a side of an equilateral triangle with fixed angles. The length scale is most convenient if the lengths are measured in terms of the absolute length (a special unit of length analogous to a relations between distances in spherical geometry). This choice for this length scale makes formulas simpler.[2] In terms of the Poincaré half-plane model absolute length corresponds to the infinitesimal metric and in the Poincaré disk model to . In terms of the (constant and negative) Gaussian curvature {{mvar|K}} of a hyperbolic plane, a unit of absolute length corresponds to a length of . In a hyperbolic triangle the sum of the angles A, B, C (respectively opposite to the side with the corresponding letter) is strictly less than a straight angle. The difference between the measure of a straight angle and the sum of the measures of a triangle's angles is called the defect of the triangle. The area of a hyperbolic triangle is equal to its defect multiplied by the square of {{mvar|R}}: . This theorem, first proven by Johann Heinrich Lambert,[3] is related to Girard's theorem in spherical geometry. TrigonometryIn all the formulas stated below the sides {{mvar|a}}, {{mvar|b}}, and {{mvar|c}} must be measured in absolute length, a unit so that the Gaussian curvature {{mvar|K}} of the plane is −1. In other words, the quantity {{mvar|R}} in the paragraph above is supposed to be equal to 1. Trigonometric formulas for hyperbolic triangles depend on the hyperbolic functions sinh, cosh, and tanh. Trigonometry of right trianglesIf C is a right angle then:
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Relations between anglesWe also have the following equations:[5] AreaThe area of a right angled triangle is: also {{citation needed|date=October 2015}}[6] Angle of parallelismThe instance of an omega triangle with a right angle provides the configuration to examine the angle of parallelism in the triangle. In this case angle B = 0, a = c = and , resulting in . Equilateral triangleThe trigonometry formulas of right triangles also give the relations between the sides s and the angles A of an equilateral triangle (a triangle where all sides have the same length and all angles are equal). The relations are: General trigonometryWhether C is a right angle or not, the following relationships hold: The hyperbolic law of cosines is as follows: Its dual theorem is There is also a law of sines: and a four-parts formula: which is derived in the same way as the analogue formula in spherical trigonometry. See also
For hyperbolic trigonometry:
References1. ^{{citation|first=Wilson|last=Stothers|title=Hyperbolic geometry|url=http://www.maths.gla.ac.uk/~wws/cabripages/hyperbolic/hyperbolic0.html|publisher=University of Glasgow|year=2000}}, interactive instructional website 2. ^{{cite book|last=Needham|first=Tristan|title=Visual Complex Analysis|publisher=Oxford University Press|year=1998|isbn=9780198534464|page=270|url=https://books.google.com/books?id=ogz5FjmiqlQC&pg=PA270}} 3. ^{{cite book|title=Foundations of Hyperbolic Manifolds|volume=149|series=Graduate Texts in Mathematics|first=John|last=Ratcliffe|publisher=Springer|year=2006|isbn=9780387331973|page=99|url=https://books.google.com/books?id=JV9m8o-ok6YC&pg=PA99|quotation=That the area of a hyperbolic triangle is proportional to its angle defect first appeared in Lambert's monograph Theorie der Parallellinien, which was published posthumously in 1786.}} 4. ^{{cite book|last1=Martin|first1=George E.|title=The foundations of geometry and the non-Euclidean plane|date=1998|publisher=Springer|location=New York, NY|isbn=0-387-90694-0|page=433|edition=Corrected 4. print.}} 5. ^{{cite book|last1=Smogorzhevski|first1=A.S.|title=Lobachevskian geometry|publisher=Mir Publishers|location=Moscow 1982|page=63}} 6. ^{{cite web|title=Area of a right angled hyperbolic triangle as function of side lengths|url=https://math.stackexchange.com/questions/1462778/area-of-a-right-angled-hyperbolic-triangle-as-function-of-side-lengths|website=Stack Exchange Mathematics|accessdate=11 October 2015}} Further reading
2 : Hyperbolic geometry|Triangles |
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