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{{short description|The centers of the incircles of triangles inside a cyclic quadrilateral form a rectangle.}}
{{Short description|Centers of the incircles of triangles inside a cyclic quadrilateral form a rectangle}}
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[[Image:Japanese theorem 2.svg|thumb|right|450px|{{math|□''M''{{sub|1}}''M''{{sub|2}}''M''{{sub|3}}''M''{{sub|4}}}} is a rectangle.]]
[[File:Japanese theorem 2 correct version a.svg|thumb|right|upright=1.3|Japanese theorem:<br/>{{math|□''M''{{sub|1}}''M''{{sub|2}}''M''{{sub|3}}''M''{{sub|4}}}} is a rectangle. <br/> <math>r_1+r_3=r_2+r_4 </math>{{r|reyes}}]]
In [[geometry]], the '''Japanese theorem''' states that the centers of the [[incircle]]s of certain [[triangles]] inside a [[cyclic quadrilateral]] are vertices of a [[rectangle]].
In [[geometry]], the '''Japanese theorem''' states that the centers of the [[incircle]]s of certain [[triangles]] inside a [[cyclic quadrilateral]] are vertices of a [[rectangle]]. It was originally stated on a [[sangaku]] tablet on a temple in [[Yamagata prefecture]], Japan, in 1880.{{r|ctk}}


Triangulating an arbitrary cyclic quadrilateral by its diagonals yields four overlapping triangles (each diagonal creates two triangles). The centers of the incircles of those triangles form a rectangle.
Triangulating an arbitrary cyclic quadrilateral by its diagonals yields four overlapping triangles (each diagonal creates two triangles). The centers of the incircles of those triangles form a rectangle.


Specifically, let {{math|□''ABCD''}} be an arbitrary cyclic quadrilateral and let {{math|''M''{{sub|1}}}}, {{math|''M''{{sub|2}}}}, {{math|''M''{{sub|3}}}}, {{math|''M''{{sub|4}}}} be the incenters of the triangles {{math|△''ABD''}}, {{math|△''ABC''}}, {{math|△''BCD''}}, {{math|△''ACD''}}. Then the quadrilateral formed by {{math|''M''{{sub|1}}}}, {{math|''M''{{sub|2}}}}, {{math|''M''{{sub|3}}}}, {{math|''M''{{sub|4}}}} is a rectangle.
Specifically, let {{math|□''ABCD''}} be an arbitrary cyclic quadrilateral and let {{math|''M''{{sub|1}}}}, {{math|''M''{{sub|2}}}}, {{math|''M''{{sub|3}}}}, {{math|''M''{{sub|4}}}} be the incenters of the triangles {{math|△''ABD''}}, {{math|△''ABC''}}, {{math|△''BCD''}}, {{math|△''ACD''}}. Then the quadrilateral formed by {{math|''M''{{sub|1}}}}, {{math|''M''{{sub|2}}}}, {{math|''M''{{sub|3}}}}, {{math|''M''{{sub|4}}}} is a rectangle. Proofs are given by Bogomolny{{r|ctk}} and Reyes.{{r|reyes}}


Note that this theorem is easily extended to prove the [[Japanese theorem for cyclic polygons]]. To prove the quadrilateral case, simply construct the parallelogram tangent to the corners of the constructed rectangle, with sides parallel to the diagonals of the quadrilateral. The construction shows that the parallelogram is a rhombus, which is equivalent to showing that the sums of the radii of the incircles tangent to each diagonal are equal.
This theorem may be extended to prove the [[Japanese theorem for cyclic polygons]], according to which the sum of inradii of a triangulated cyclic polygon does not depend on how it is triangulated. The special case of the theorem for quadrilaterals states that the two pairs of opposite incircles of the theorem above have equal sums of radii. To prove the quadrilateral case, simply construct the parallelogram tangent to the corners of the constructed rectangle, with sides parallel to the diagonals of the quadrilateral. The construction shows that the parallelogram is a rhombus, which is equivalent to showing that the sums of the radii of the incircles tangent to each diagonal are equal. This related result comes from an earlier sangaku tablet, also from Yamagata, from 1800.{{r|ctk}}


The quadrilateral case immediately proves the general case by induction on the set of triangulating partitions of a general polygon.
The quadrilateral case immediately proves the general case, as any two triangulations of an arbitrary cyclic polygon can be connected by a sequence of [[Flip graph|flips]] that change one diagonal to another, replacing two incircles in a quadrilateral by the other two incircles with equal sum of radii.


==See also==
==See also==
*[[Carnot's theorem (inradius, circumradius)|Carnot's theorem]]
*[[Carnot's theorem (inradius, circumradius)|Carnot's theorem]]
*[[Sangaku]]
*[[Japanese mathematics]]
*[[Japanese mathematics]]


==References==
==References==
{{reflist|refs=
*Mangho Ahuja, Wataru Uegaki, Kayo Matsushita: [https://web.archive.org/web/20070208105128/http://www.math-cs.cmsu.edu/~mjms/2006.2/mangho999.ps ''In Search of the Japanese Theorem''] (postscript file)

*[http://www.cut-the-knot.org/Curriculum/Geometry/CyclicQuadrilateral.shtml#explanation Theorem] at [[Cut-the-Knot]]
<ref name=ctk>{{cite web|url=http://www.cut-the-knot.org/Curriculum/Geometry/CyclicQuadrilateral.shtml|title=Incenters in cyclic quadrilaterals|work=[[Cut-the-Knot]]|first=Alexander|last=Bogomolny|year=2018}}</ref>

<ref name=reyes>{{cite journal
| last = Reyes | first = Wilfred
| journal = Forum Geometricorum
| mr = 1990908
| pages = 183–185
| title = An application of Thébault's theorem
| volume = 2
| url = http://forumgeom.fau.edu/FG2002volume2/FG200223.pdf
| archive-url = https://web.archive.org/web/20240106233125/forumgeom.fau.edu/FG2002volume2/FG200223.pdf
| archive-date = 2024-01-06
| url-status = dead
| year = 2002}}</ref>

}}

==Further reading==
*Mangho Ahuja, Wataru Uegaki, Kayo Matsushita: "In Search of the Japanese Theorem". In: ''Missouri Journal of Mathematical Sciences'', vol 18, no. 2, May 2006 ([https://projecteuclid.org/journals/missouri-journal-of-mathematical-sciences/volume-18/issue-2/In-Search-of-The-Japanese-Theorem/10.35834/2006/1802087.full online] at project Euclid)
*Wataru Uegaki: [http://hdl.handle.net/10076/4917 "{{nihongo2|Japanese Theoremの起源と歴史}}"] (On the Origin and History of the Japanese Theorem). Departmental Bulletin Paper, Mie University Scholarly E-Collections, 2001-03-01
*Wataru Uegaki: [http://hdl.handle.net/10076/4917 "{{nihongo2|Japanese Theoremの起源と歴史}}"] (On the Origin and History of the Japanese Theorem). Departmental Bulletin Paper, Mie University Scholarly E-Collections, 2001-03-01
*{{Cite web|author=笹部貞市郎|url=https://archive.org/details/20240618_20240618_1431/page/119/mode/1up |title=几何学辞典: 问题解法 |website=[[Archive.org]] |date=1976 |at=Problem 587}}
*Wilfred Reyes: [http://forumgeom.fau.edu/FG2002volume2/FG200223.pdf ''An Application of Thebault’s Theorem'']. Forum Geometricorum, Volume 2, 2002, pp. 183–185


==External links==
==External links==
*[http://www.gogeometry.com/sangaku2.html Japanese theorem, interactive proof with animation]
*[https://www.gogeometry.com/geometry/sangaku_cyclic_quadrilateral.htm Japanese theorem, interactive proof with animation]


[[Category:Euclidean plane geometry]]
[[Category:Euclidean plane geometry]]
[[Category:Japanese mathematics]]
[[Category:Japanese mathematics]]
[[Category:Theorems in plane geometry]]
[[Category:Theorems about quadrilaterals and circles]]

Latest revision as of 22:51, 14 November 2024

Japanese theorem:
M1M2M3M4 is a rectangle.
[1]

In geometry, the Japanese theorem states that the centers of the incircles of certain triangles inside a cyclic quadrilateral are vertices of a rectangle. It was originally stated on a sangaku tablet on a temple in Yamagata prefecture, Japan, in 1880.[2]

Triangulating an arbitrary cyclic quadrilateral by its diagonals yields four overlapping triangles (each diagonal creates two triangles). The centers of the incircles of those triangles form a rectangle.

Specifically, let ABCD be an arbitrary cyclic quadrilateral and let M1, M2, M3, M4 be the incenters of the triangles ABD, ABC, BCD, ACD. Then the quadrilateral formed by M1, M2, M3, M4 is a rectangle. Proofs are given by Bogomolny[2] and Reyes.[1]

This theorem may be extended to prove the Japanese theorem for cyclic polygons, according to which the sum of inradii of a triangulated cyclic polygon does not depend on how it is triangulated. The special case of the theorem for quadrilaterals states that the two pairs of opposite incircles of the theorem above have equal sums of radii. To prove the quadrilateral case, simply construct the parallelogram tangent to the corners of the constructed rectangle, with sides parallel to the diagonals of the quadrilateral. The construction shows that the parallelogram is a rhombus, which is equivalent to showing that the sums of the radii of the incircles tangent to each diagonal are equal. This related result comes from an earlier sangaku tablet, also from Yamagata, from 1800.[2]

The quadrilateral case immediately proves the general case, as any two triangulations of an arbitrary cyclic polygon can be connected by a sequence of flips that change one diagonal to another, replacing two incircles in a quadrilateral by the other two incircles with equal sum of radii.

See also

[edit]

References

[edit]
  1. ^ a b Reyes, Wilfred (2002). "An application of Thébault's theorem" (PDF). Forum Geometricorum. 2: 183–185. MR 1990908. Archived from the original (PDF) on 2024-01-06.
  2. ^ a b c Bogomolny, Alexander (2018). "Incenters in cyclic quadrilaterals". Cut-the-Knot.

Further reading

[edit]
  • Mangho Ahuja, Wataru Uegaki, Kayo Matsushita: "In Search of the Japanese Theorem". In: Missouri Journal of Mathematical Sciences, vol 18, no. 2, May 2006 (online at project Euclid)
  • Wataru Uegaki: "Japanese Theoremの起源と歴史" (On the Origin and History of the Japanese Theorem). Departmental Bulletin Paper, Mie University Scholarly E-Collections, 2001-03-01
  • 笹部貞市郎 (1976). "几何学辞典: 问题解法". Archive.org. Problem 587.
[edit]