Generalized trigonometry

Short description: Study of triangles in other spaces than the Euclidean plane

Ordinary trigonometry studies triangles in the Euclidean plane $ℝ^{2}$ . There are a number of ways of defining the ordinary Euclidean geometric trigonometric functions on real numbers, for example right-angled triangle definitions, unit circle definitions, series definitions^{[broken anchor]}, definitions via differential equations^{[broken anchor]}, and definitions using functional equations. Generalizations of trigonometric functions are often developed by starting with one of the above methods and adapting it to a situation other than the real numbers of Euclidean geometry. Generally, trigonometry can be the study of triples of points in any kind of geometry or space. A triangle is the polygon with the smallest number of vertices, so one direction to generalize is to study higher-dimensional analogs of angles and polygons: solid angles and polytopes such as tetrahedrons and $n$ -simplices.

Trigonometry

In spherical trigonometry, triangles on the surface of a sphere are studied. The spherical triangle identities are written in terms of the ordinary trigonometric functions but differ from the plane triangle identities.
Hyperbolic trigonometry:
1. Study of hyperbolic triangles in hyperbolic geometry with hyperbolic functions.
2. Hyperbolic functions in Euclidean geometry: The unit circle is parameterized by (cos t, sin t) whereas the equilateral hyperbola is parameterized by (cosh t, sinh t).
3. Gyrotrigonometry: A form of trigonometry used in the gyrovector space approach to hyperbolic geometry, with applications to special relativity and quantum computation.
Trigonometry for taxicab geometry^[1]
Spacetime trigonometries^[2]
Fuzzy qualitative trigonometry^[3]
Operator trigonometry^[4]
Lattice trigonometry^[5]
Trigonometry on symmetric spaces^[6]^[7]^[8]

Higher dimensions

Schläfli orthoschemes - right simplexes (right triangles generalized to n dimensions) - studied by Schoute who called the generalized trigonometry of n Euclidean dimensions polygonometry.
- Pythagorean theorems for n-simplices with an "orthogonal corner"
Trigonometry of a tetrahedron^[9]
- De Gua's theorem – a Pythagorean theorem for a tetrahedron with a cube corner
- A law of sines for tetrahedra
Polar sine

Trigonometric functions

Trigonometric functions can be defined for fractional differential equations.^[10]

In time scale calculus, differential equations and difference equations are unified into dynamic equations on time scales which also includes q-difference equations. Trigonometric functions can be defined on an arbitrary time scale (a subset of the real numbers).
The series definitions^{[broken anchor]} of sin and cos define these functions on any algebra where the series converge such as complex numbers^{[broken anchor]}, p-adic numbers, matrices, and various Banach algebras.

Other

Polar/Trigonometric forms of hypercomplex numbers^[11]^[12]
Polygonometry – trigonometric identities for multiple distinct angles^[13]
The Lemniscate elliptic functions, sinlem and coslem

References

↑ Thompson, K.; Dray, T. (2000), "Taxicab angles and trigonometry", Pi Mu Epsilon Journal 11 (2): 87–96, Bibcode: 2011arXiv1101.2917T, http://www.physics.orst.edu/~tevian/taxicab/taxicab.pdf, retrieved 2009-05-18
↑ Herranz, Francisco J.; Ortega, Ramón; Santander, Mariano (2000), "Trigonometry of spacetimes: a new self-dual approach to a curvature/signature (in)dependent trigonometry", Journal of Physics A 33 (24): 4525–4551, doi:10.1088/0305-4470/33/24/309, Bibcode: 2000JPhA...33.4525H
↑ Liu, Honghai; Coghill, George M. (2005), "Fuzzy Qualitative Trigonometry", 2005 IEEE International Conference on Systems, Man and Cybernetics, 2, pp. 1291–1296, archived from the original on 2011-07-25, https://web.archive.org/web/20110725170037/http://userweb.port.ac.uk/~liuh/Papers/LiuCoghill05c_SMC.pdf
↑ Gustafson, K. E. (1999), "A computational trigonometry, and related contributions by Russians Kantorovich, Krein, Kaporin", Вычислительные технологии 4 (3): 73–83, http://www.ict.nsc.ru/jct/getfile.php?id=159
↑ Karpenkov, Oleg (2008), "Elementary notions of lattice trigonometry", Mathematica Scandinavica 102 (2): 161–205, doi:10.7146/math.scand.a-15058
↑ Aslaksen, Helmer; Huynh, Hsueh-Ling (1997), "Laws of trigonometry in symmetric spaces", Geometry from the Pacific Rim (Singapore, 1994), Berlin: de Gruyter, pp. 23–36
↑ Leuzinger, Enrico (1992), "On the trigonometry of symmetric spaces", Commentarii Mathematici Helvetici 67 (2): 252–286, doi:10.1007/BF02566499
↑ Masala, G. (1999), "Regular triangles and isoclinic triangles in the Grassmann manifolds $G 2 (R N)$ ", Rendiconti del Seminario Matematico Università e Politecnico di Torino 57 (2): 91–104
↑ Richardson, G. (1902-03-01). "The Trigonometry of the Tetrahedron". The Mathematical Gazette 2 (32): 149–158. doi:10.2307/3603090. https://zenodo.org/record/1449743.
↑ West, Bruce J.; Bologna, Mauro; Grigolini, Paolo (2003), Physics of fractal operators, Institute for Nonlinear Science, New York: Springer-Verlag, p. 101, doi:10.1007/978-0-387-21746-8, ISBN 0-387-95554-2
↑ Harkin, Anthony A.; Harkin, Joseph B. (2004), "Geometry of generalized complex numbers", Mathematics Magazine 77 (2): 118–129, doi:10.1080/0025570X.2004.11953236
↑ Yamaleev, Robert M. (2005), "Complex algebras on $n$ -order polynomials and generalizations of trigonometry, oscillator model and Hamilton dynamics", Advances in Applied Clifford Algebras 15 (1): 123–150, doi:10.1007/s00006-005-0007-y, archived from the original on 2011-07-22, https://web.archive.org/web/20110722194119/http://www.clifford-algebras.org/v15/v151/YAMAL151.pdf
↑ Antippa, Adel F. (2003), "The combinatorial structure of trigonometry", International Journal of Mathematics and Mathematical Sciences 2003 (8): 475–500, doi:10.1155/S0161171203106230, http://www.emis.de/journals/HOA/IJMMS/2003/8475.pdf

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[1] Thompson, K.; Dray, T. (2000), "Taxicab angles and trigonometry", Pi Mu Epsilon Journal 11 (2): 87–96, Bibcode: 2011arXiv1101.2917T, http://www.physics.orst.edu/~tevian/taxicab/taxicab.pdf, retrieved 2009-05-18

[2] Herranz, Francisco J.; Ortega, Ramón; Santander, Mariano (2000), "Trigonometry of spacetimes: a new self-dual approach to a curvature/signature (in)dependent trigonometry", Journal of Physics A 33 (24): 4525–4551, doi:10.1088/0305-4470/33/24/309, Bibcode: 2000JPhA...33.4525H

[3] Liu, Honghai; Coghill, George M. (2005), "Fuzzy Qualitative Trigonometry", 2005 IEEE International Conference on Systems, Man and Cybernetics, 2, pp. 1291–1296, archived from the original on 2011-07-25, https://web.archive.org/web/20110725170037/http://userweb.port.ac.uk/~liuh/Papers/LiuCoghill05c_SMC.pdf

[4] Gustafson, K. E. (1999), "A computational trigonometry, and related contributions by Russians Kantorovich, Krein, Kaporin", Вычислительные технологии 4 (3): 73–83, http://www.ict.nsc.ru/jct/getfile.php?id=159

[5] Karpenkov, Oleg (2008), "Elementary notions of lattice trigonometry", Mathematica Scandinavica 102 (2): 161–205, doi:10.7146/math.scand.a-15058

[6] Aslaksen, Helmer; Huynh, Hsueh-Ling (1997), "Laws of trigonometry in symmetric spaces", Geometry from the Pacific Rim (Singapore, 1994), Berlin: de Gruyter, pp. 23–36

[7] Leuzinger, Enrico (1992), "On the trigonometry of symmetric spaces", Commentarii Mathematici Helvetici 67 (2): 252–286, doi:10.1007/BF02566499

[8] Masala, G. (1999), "Regular triangles and isoclinic triangles in the Grassmann manifolds $G 2 (R N)$ ", Rendiconti del Seminario Matematico Università e Politecnico di Torino 57 (2): 91–104

[9] Richardson, G. (1902-03-01). "The Trigonometry of the Tetrahedron". The Mathematical Gazette 2 (32): 149–158. doi:10.2307/3603090. https://zenodo.org/record/1449743.

[10] West, Bruce J.; Bologna, Mauro; Grigolini, Paolo (2003), Physics of fractal operators, Institute for Nonlinear Science, New York: Springer-Verlag, p. 101, doi:10.1007/978-0-387-21746-8, ISBN 0-387-95554-2

[11] Harkin, Anthony A.; Harkin, Joseph B. (2004), "Geometry of generalized complex numbers", Mathematics Magazine 77 (2): 118–129, doi:10.1080/0025570X.2004.11953236

[12] Yamaleev, Robert M. (2005), "Complex algebras on $n$ -order polynomials and generalizations of trigonometry, oscillator model and Hamilton dynamics", Advances in Applied Clifford Algebras 15 (1): 123–150, doi:10.1007/s00006-005-0007-y, archived from the original on 2011-07-22, https://web.archive.org/web/20110722194119/http://www.clifford-algebras.org/v15/v151/YAMAL151.pdf

[13] Antippa, Adel F. (2003), "The combinatorial structure of trigonometry", International Journal of Mathematics and Mathematical Sciences 2003 (8): 475–500, doi:10.1155/S0161171203106230, http://www.emis.de/journals/HOA/IJMMS/2003/8475.pdf

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