Trillium_theorem Knowpia

In geometry, the incenter–excenter lemma is the theorem that the line segment between the incenter and any excenter of a triangle, or between two excenters, is the diameter of a circle (an incenter–excenter or excenter–excenter circle) also passing through two triangle vertices with its center on the circumcircle.^[1]^[2]^[3] This theorem is best known in Russia, where it is called the trillium theorem (теорема трилистника) or trident lemma (лемма о трезубце), based on the geometric figure's resemblance to a trillium flower or trident;^[4]^[5] these names have sometimes also been adopted in English.^[6]^[7]

These relationships arise because the incenter and excenters of any triangle form an orthocentric system whose nine-point circle is the circumcircle of the original triangle.^[8]^[2] The theorem is helpful for solving competitive Euclidean geometry problems,^[1] and can be used to reconstruct a triangle starting from one vertex, the incenter, and the circumcenter.

Statement edit

incenter–excenter lemma with incenter

I

and excenter

E

Let $ABC$ be an arbitrary triangle. Let $I$ be its incenter and let $D$ be the point where line $BI$ (the angle bisector of $∠ ABC$ ) crosses the circumcircle of $ABC$ . Then, the theorem states that $D$ is equidistant from $A$ , $C$ , and $I$ . Equivalently:

The circle through $A$ , $C$ , and $I$ has its center at $D$ . In particular, this implies that the center of this circle lies on the circumcircle.^[9]^[10]
The three triangles $AID$ , $CID$ , and $ACD$ are isosceles, with $D$ as their apex.

A fourth point $E$ , the excenter of $ABC$ relative to $B$ , also lies at the same distance from $D$ , diametrically opposite from $I$ .^[5]^[11]

Proof edit

By the inscribed angle theorem, $\angle IBA=\angle DCA,\ \angle IBC=\angle DAC.$

Since $BI$ is an angle bisector, $\angle DCA=\angle DAC\implies AD=CD.$

We also get

{\begin{aligned}\angle DIA&=180^{\circ }-\angle AIB\\&=180^{\circ }-(180^{\circ }-\angle IAB-\angle IBA)\\&=\angle IAB+\angle IBA\\&=\angle IAC+\angle DAC\\&=\angle IAD\\\implies AD&=DI.\end{aligned}}

Application to triangle reconstruction edit

This theorem can be used to reconstruct a triangle starting from the locations only of one vertex, the incenter, and the circumcenter of the triangle. For, let $B$ be the given vertex, $I$ be the incenter, and $O$ be the circumcenter. This information allows the successive construction of:

the circumcircle of the given triangle, as the circle with center $O$ and radius $OB$ ,
point $D$ as the intersection of the circumcircle with line $BI$ ,
the circle of the theorem, with center $D$ and radius $DI$ , and
vertices $A$ and $C$ as the intersection points of the two circles.^[12]

However, for some triples of points $B$ , $I$ , and $O$ , this construction may fail, either because line $IB$ is tangent to the circumcircle or because the two circles do not have two crossing points. It may also produce a triangle for which the given point $I$ is an excenter rather than the incenter. In these cases, there can be no triangle having $B$ as vertex, $I$ as incenter, and $O$ as circumcenter.^[13]

Other triangle reconstruction problems, such as the reconstruction of a triangle from a vertex, incenter, and center of its nine-point circle, can be solved by reducing the problem to the case of a vertex, incenter, and circumcenter.^[13]

Generalization edit

Let $I$ and $J$ be any two of the four points given by the incenter and the three excenters of a triangle $ABC$ . Then $I$ and $J$ are collinear with one of the three triangle vertices. The circle with $IJ$ as diameter passes through the other two vertices and is centered on the circumcircle of $ABC$ . When one of $I$ or $J$ is the incenter, this is the trillium theorem, with line $IJ$ as the (internal) angle bisector of one of the triangle's angles. However, it is also true when $I$ and $J$ are both excenters; in this case, line $IJ$ is the external angle bisector of one of the triangle's angles.^[14]

References edit

^ ^a ^b Chen, Evan (2016). "§1.4 The Incenter/Excenter Lemma". Euclidean Geometry in Mathematical Olympiads. Mathematical Association of America. pp. 9–10. ISBN 9780883858394.
^ ^a ^b Le, Nguyen; Wildberger, Norman (2016). "Incenter Symmetry, Euler Lines, and Schiffler Points". KoG. 20 (20): 22–30.
^ Weisstein, Eric W. (1999). CRC Concise Encyclopedia of Mathematics. CRC Press. "Excenter–Excenter Circle" p. 591, "Incenter–Excenter Circle" p. 894. ISBN 0849396409. Republished at MathWorld: "Excenter–Excenter Circle", "Incenter–Excenter Circle".
^ Trillium theorem: И. А. Кушнир. "Это открытие - золотой ключ Леонарда Эйлера" (PDF) (in Russian). Ф7 (Теорема трилистника), page 34; proof on page 36.

Trident lemma: Р. Н. Карасёв; В. Л. Дольников; И. И. Богданов; А. В. Акопян. "Задачи для школьного математического кружка" (PDF) (in Russian). Problem 1.2. p. 4.{{cite web}}: CS1 maint: location (link)
^ ^a ^b "6. Лемма о трезубце" (PDF) (in Russian). СУНЦ МГУ им. М. В. Ломоносова - школа им. А.Н. Колмогорова. 2014-10-29.
^ Garcia, Ronaldo; Odehnal, Boris; Reznik, Dan (2022). "Loci of poncelet triangles in the general closure case". Journal of Geometry. 113 (1): 17. arXiv:2108.05430. doi:10.1007/s00022-022-00629-3.
^ Zaslavsky, Alexey A.; Skopenkov, Mikhail B. (2021). Mathematics via Problems. Part 2: Geometry. American Mathematical Society. p. 15. ISBN 9781470448790.
^ Johnson, Roger A. (1929). "X. Inscribed and Escribed Circles". Modern Geometry. Houghton Mifflin. pp. 182–194.
^ Morris, Richard (1928), "Circles through notable points of the triangle", The Mathematics Teacher, 21 (2): 63–71, doi:10.5951/MT.21.2.0069, JSTOR 27951001. See in particular the discussion on p. 65 of circles $BIC$ , $CIA$ , $AIB$ , and their centers.
^ Bogomolny, Alexander. "A Property of Circle Through the Incenter". Cut-the-Knot. Retrieved 2016-01-26.
^ Bogomolny, Alexander. "Midpoints of the Lines Joining In- and Excenters". Cut-the-Knot. Retrieved 2016-01-26.
^ Aref, M. N.; Wernick, William (1968). Problems and Solutions in Euclidean Geometry. Dover. 3.3(i), p. 68. ISBN 9780486477206..
^ ^a ^b Yiu, Paul (2012), "Conic construction of a triangle from its incenter, nine-point center, and a vertex" (PDF), Journal for Geometry and Graphics, 16 (2): 171–183, MR 3088369
^ Chou, Shang-Ching; Gao, Xiao-Shan; Zhang, Jingzhong (1994). Machine Proofs in Geometry. World Scientific. Examples 6.145 and 6.146, pp. 328–329. ISBN 9789810215842..

[chen-1] Chen, Evan (2016). "§1.4 The Incenter/Excenter Lemma". Euclidean Geometry in Mathematical Olympiads. Mathematical Association of America. pp. 9–10. ISBN 9780883858394.

[lw-2] Le, Nguyen; Wildberger, Norman (2016). "Incenter Symmetry, Euler Lines, and Schiffler Points". KoG. 20 (20): 22–30.

[weisstein-3] Weisstein, Eric W. (1999). CRC Concise Encyclopedia of Mathematics. CRC Press. "Excenter–Excenter Circle" p. 591, "Incenter–Excenter Circle" p. 894. ISBN 0849396409. Republished at MathWorld: "Excenter–Excenter Circle", "Incenter–Excenter Circle".

[rusources-4] Trillium theorem: И. А. Кушнир. "Это открытие - золотой ключ Леонарда Эйлера" (PDF) (in Russian). Ф7 (Теорема трилистника), page 34; proof on page 36.

Trident lemma: Р. Н. Карасёв; В. Л. Дольников; И. И. Богданов; А. В. Акопян. "Задачи для школьного математического кружка" (PDF) (in Russian). Problem 1.2. p. 4.{{cite web}}: CS1 maint: location (link)

[mosolymp-5] "6. Лемма о трезубце" (PDF) (in Russian). СУНЦ МГУ им. М. В. Ломоносова - школа им. А.Н. Колмогорова. 2014-10-29.

[gor-6] Garcia, Ronaldo; Odehnal, Boris; Reznik, Dan (2022). "Loci of poncelet triangles in the general closure case". Journal of Geometry. 113 (1): 17. arXiv:2108.05430. doi:10.1007/s00022-022-00629-3.

[zs-7] Zaslavsky, Alexey A.; Skopenkov, Mikhail B. (2021). Mathematics via Problems. Part 2: Geometry. American Mathematical Society. p. 15. ISBN 9781470448790.

[johnson-8] Johnson, Roger A. (1929). "X. Inscribed and Escribed Circles". Modern Geometry. Houghton Mifflin. pp. 182–194.

[morris-9] Morris, Richard (1928), "Circles through notable points of the triangle", The Mathematics Teacher, 21 (2): 63–71, doi:10.5951/MT.21.2.0069, JSTOR 27951001. See in particular the discussion on p. 65 of circles $BIC$ , $CIA$ , $AIB$ , and their centers.

[bogomolny2-10] Bogomolny, Alexander. "A Property of Circle Through the Incenter". Cut-the-Knot. Retrieved 2016-01-26.

[bogomolny1-11] Bogomolny, Alexander. "Midpoints of the Lines Joining In- and Excenters". Cut-the-Knot. Retrieved 2016-01-26.

[aw-12] Aref, M. N.; Wernick, William (1968). Problems and Solutions in Euclidean Geometry. Dover. 3.3(i), p. 68. ISBN 9780486477206..

[yiu-13] Yiu, Paul (2012), "Conic construction of a triangle from its incenter, nine-point center, and a vertex" (PDF), Journal for Geometry and Graphics, 16 (2): 171–183, MR 3088369

[cgz-14] Chou, Shang-Ching; Gao, Xiao-Shan; Zhang, Jingzhong (1994). Machine Proofs in Geometry. World Scientific. Examples 6.145 and 6.146, pp. 328–329. ISBN 9789810215842..

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Summary

Statement edit

Proof edit

Application to triangle reconstruction edit

Generalization edit

See also edit

References edit