Conway circle theorem

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In plane geometry, the Conway circle theorem states that when the sides meeting at each vertex of a triangle are extended by the length of the opposite side, the six endpoints of the three resulting line segments lie on a circle whose centre is the incentre of the triangle. The circle on which these six points lie is called the Conway circle of the triangle.^[1]^[2]^[3] The theorem and circle are named after mathematician John Horton Conway.

Proof

Let I be the center of the incircle of triangle ABC, r its radius and F_a, F_b and F_c the three points where the incircle touches the triangle sides a, b and c. Since the (extended) triangle sides are tangents of the incircle it follows that IF_a, IF_b and IF_c are perpendicular to a, b and c. Furthermore the following equalities for line segments hold. |AF_c|=|AF_b|, |BF_c|=|BF_a|, |CF_a|=|CF_b|. With that the six triangles IF_cP_a, IF_cQ_b, IF_aP_b, IF_aQ_c, IF_bQ_a and IF_bP_c all have a side of length |AF_c|+|BF_c|+|CF_a| and a side of length r with a right angle between them. This means that due SAS congruence theorem for triangles all six triangles are congruent, which yields |IP_a|=|IQ_a|=|IP_b|=|IQ_b|=|IP_c|=|IQ_c|. So the six points P_a, Q_a, P_b, Q_b, P_c and Q_c have all the same distance from the triangle incenter I, that is they lie on a common circle with center I.

Additional properties

The radius of the Conway circle is

{\sqrt {r^{2}+s^{2}}}={\sqrt {\frac {a^{2}b+ab^{2}+b^{2}c+bc^{2}+a^{2}c+ac^{2}+abc}{a+b+c}}}

where $r$ and $s$ are the inradius and semiperimeter of the triangle.^[3]

Generalisation

Conway's circle is a special case of a more general circle for a triangle that can be obtained as follows: Given any △ABC with an arbitrary point P on line AB. Construct BQ = BP, CR = CQ, AS = AR, BT = BS, CU = CT. Then AU = AP, and PQRSTU is cyclic.^[4]

If you place P on the extended triangle side AB such that BP=b and BP being completely outside the triangle then the above constructions yield Conway's circle theorem.

References

^ "John Horton Conway". www.cardcolm.org. Archived from the original on 20 May 2020. Retrieved 29 May 2020.
^ Weisstein, Eric W. "Conway Circle". MathWorld. Retrieved 29 May 2020.
^ ^a ^b Francisco Javier García Capitán (2013). "A Generalization of the Conway Circle" (PDF). Forum Geometricorum. 13: 191–195.
^ Michael de Villiers (2023). "Conway's Circle Theorem as a Special Case of a More General Side Divider Theorem". Learning and Teaching Mathematics (34): 37–42.

External links

Kimberling, Clark. "Encyclopedia of Triangle Centers".
Colin Beveridge: Conway’s Circle, a proof without words. The Aperiodical, 07 May 2020
Colin Beveridge, Elizabeth A. Williams: Conway’s Circle Theorem: a proof, this time with words. The Aperiodical, 11 June 2020 (Video, 9:12 min.)
De Villiers, Michael. "Conway's Circle Theorem as special case of Side Divider (Windscreen Wiper) Theorem". dynamicmathematicslearning.com.
Polster, Burkard (6 April 2024). "Conway's Iris and the Windscreen Wiper Theorem". Mathologer. YouTube.

[1] "John Horton Conway". www.cardcolm.org. Archived from the original on 20 May 2020. Retrieved 29 May 2020.

[2] Weisstein, Eric W. "Conway Circle". MathWorld. Retrieved 29 May 2020.

[FJGC-3] Francisco Javier García Capitán (2013). "A Generalization of the Conway Circle" (PDF). Forum Geometricorum. 13: 191–195.

[MdeV-4] Michael de Villiers (2023). "Conway's Circle Theorem as a Special Case of a More General Side Divider Theorem". Learning and Teaching Mathematics (34): 37–42.

[1]

[2]

[3]

[4]

Proof

Additional properties

Generalisation

See also

References

External links