Kosnita's theorem

Last updated July 13, 2023

In Euclidean geometry, Kosnita's theorem is a property of certain circles associated with an arbitrary triangle.

Let $ABC$ be an arbitrary triangle, $O$ its circumcenter and $O_{a},O_{b},O_{c}$ are the circumcenters of three triangles $OBC$ , $OCA$ , and $OAB$ respectively. The theorem claims that the three straight lines $AO_{a}$ , $BO_{b}$ , and $CO_{c}$ are concurrent.^[1] This result was established by the Romanian mathematician Cezar Coşniţă (1910-1962).^[2]

Their point of concurrence is known as the triangle's Kosnita point (named by Rigby in 1997). It is the isogonal conjugate of the nine-point center.^[3]^[4] It is triangle center $X(54)$ in Clark Kimberling's list.^[5] This theorem is a special case of Dao's theorem on six circumcenters associated with a cyclic hexagon in.^[6]^[7]^[8]^[9]^[10]^[11]^[12]

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References

↑ Weisstein, Eric W. "Kosnita Theorem". MathWorld .
↑ Ion Pătraşcu (2010), A generalization of Kosnita's theorem (in Romanian)
↑ Darij Grinberg (2003), On the Kosnita Point and the Reflection Triangle. Forum Geometricorum, volume 3, pages 105–111. ISSN 1534-1178
↑ John Rigby (1997), Brief notes on some forgotten geometrical theorems. Mathematics and Informatics Quarterly, volume 7, pages 156-158 (as cited by Kimberling).
↑ Clark Kimberling (2014), Encyclopedia of Triangle Centers Archived 2012-04-19 at the Wayback Machine , section X(54) = Kosnita Point. Accessed on 2014-10-08
↑ Nikolaos Dergiades (2014), Dao's Theorem on Six Circumcenters associated with a Cyclic Hexagon. Forum Geometricorum, volume 14, pages=243–246. ISSN 1534-1178.
↑ Telv Cohl (2014), A purely synthetic proof of Dao's theorem on six circumcenters associated with a cyclic hexagon. Forum Geometricorum, volume 14, pages 261–264. ISSN 1534-1178.
↑ Ngo Quang Duong, International Journal of Computer Discovered Mathematics, Some problems around the Dao's theorem on six circumcenters associated with a cyclic hexagon configuration, volume 1, pages=25-39. ISSN 2367-7775
↑ Clark Kimberling (2014), X(3649) = KS(INTOUCH TRIANGLE)
↑ Nguyễn Minh Hà, Another Purely Synthetic Proof of Dao's Theorem on Sixcircumcenters . Journal of Advanced Research on Classical and Modern Geometries, ISSN 2284-5569, volume 6, pages 37–44. MR ....
↑ Nguyễn Tiến Dũng, A Simple proof of Dao's Theorem on Sixcircumcenters . Journal of Advanced Research on Classical and Modern Geometries, ISSN 2284-5569, volume 6, pages 58–61. MR ....
↑ The extension from a circle to a conic having center: The creative method of new theorems, International Journal of Computer Discovered Mathematics, pp.21-32.

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[wolframKosnita-1] Weisstein, Eric W. "Kosnita Theorem". MathWorld .

[patrascu-2] Ion Pătraşcu (2010), A generalization of Kosnita's theorem (in Romanian)

[grinberg2003-3] Darij Grinberg (2003), On the Kosnita Point and the Reflection Triangle. Forum Geometricorum, volume 3, pages 105–111. ISSN 1534-1178

[rigby1997-4] John Rigby (1997), Brief notes on some forgotten geometrical theorems. Mathematics and Informatics Quarterly, volume 7, pages 156-158 (as cited by Kimberling).

[kimberlingX54-5] Clark Kimberling (2014), Encyclopedia of Triangle Centers Archived 2012-04-19 at the Wayback Machine , section X(54) = Kosnita Point. Accessed on 2014-10-08

[dergiadesDao6CCCH-6] Nikolaos Dergiades (2014), Dao's Theorem on Six Circumcenters associated with a Cyclic Hexagon. Forum Geometricorum, volume 14, pages=243–246. ISSN 1534-1178.

[cohlDao6CCCH-7] Telv Cohl (2014), A purely synthetic proof of Dao's theorem on six circumcenters associated with a cyclic hexagon. Forum Geometricorum, volume 14, pages 261–264. ISSN 1534-1178.

[NgoQuangDuong-8] Ngo Quang Duong, International Journal of Computer Discovered Mathematics, Some problems around the Dao's theorem on six circumcenters associated with a cyclic hexagon configuration, volume 1, pages=25-39. ISSN 2367-7775

[C.Kimberling-9] Clark Kimberling (2014), X(3649) = KS(INTOUCH TRIANGLE)

[10] Nguyễn Minh Hà, Another Purely Synthetic Proof of Dao's Theorem on Sixcircumcenters . Journal of Advanced Research on Classical and Modern Geometries, ISSN 2284-5569, volume 6, pages 37–44. MR ....

[11] Nguyễn Tiến Dũng, A Simple proof of Dao's Theorem on Sixcircumcenters . Journal of Advanced Research on Classical and Modern Geometries, ISSN 2284-5569, volume 6, pages 58–61. MR ....

[12] The extension from a circle to a conic having center: The creative method of new theorems, International Journal of Computer Discovered Mathematics, pp.21-32.

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