Lemoine's problem

In mathematics, Lemoine's problem is a certain construction problem in elementary plane geometry posed by the French mathematician Émile Lemoine (1840–1912) in 1868.[1][2] The problem was published as Question 864 in Nouvelles Annales de Mathématiques (Series 2, Volume 7 (1868), p 191). The chief interest in the problem is that a discussion of the solution of the problem by Ludwig Kiepert published in Nouvelles Annales de Mathématiques (series 2, Volume 8 (1869), pp 40–42) contained a description of a hyperbola which is now known as the Kiepert hyperbola.[3]

Statement of the problem

The question published by Lemoine poses the following construction problem:

Given one vertex of each of the equilateral triangles placed on the sides of a triangle, construct the original triangle.

Ludwig Kiepert's solution

Diagram illustrating Lemma 1 .
Diagram illustrating Ludwig Kiepert's solution to Lemoine's problem

Kiepert establishes the validity of his construction by proving a few lemmas.[3][4]

Problem
Let A1, B1, C1 be the vertices of the equilateral triangles placed on the sides of a triangle ABC. Given A1, B1, C1 construct A, B, C.
Lemma 1
If on the three sides of an arbitrary triangle ABC, one describes equilateral triangles ABC1, ACB1, BCA1, then the line segments AA1, BB1, CC1 are equal, they concur in a point P, and the angles they form one another are equal to 60°.
Lemma 2
If on A1B1C1 one makes the same construction as that on ABC, there will have three equilateral triangles A1B1C2, A1C1B2, B1C1A2, three equal line segments A1A2, B1B2, C1C2, which will also concur at the point P.
Lemma 3
A, B, C are respectively the midpoints of A1A2, B1B2, C1C2.
Solution
  • Describe on the segments A1B1, A1C1, B1C1 the equilateral triangles A1B1C2, A1C1B2, B1C1A2, respectively.
  • The midpoints of A1A2, B1B2, C1C2 are, respectively, the vertices A, B, C of the required triangle.

Other solutions

Several other people in addition to Kiepert submitted their solutions during 1868–9, including Messrs Williere (at Arlon), Brocard, Claverie (Lycee de Clermont), Joffre (Lycee Charlomagne), Racine (Lycee de Poitiers), Augier (Lycee de Caen), V. Niebylowski, and L. Henri Lorrez. Kiepert's solution was more complete than the others.[3]

References

  1. Weisstein, Eric W. "Lemoine's Problem". From MathWorld—A Wolfram Web Resource. Retrieved 9 May 2012.
  2. Wetzel, John E. (April 1992). "Converses of Napoleon's Theorem" (PDF). The American Mathematical Monthly 99 (4): 339–351. doi:10.2307/2324901. Retrieved 9 May 2012.
  3. 1 2 3 The details of the construction as given by Kiepert in French can be read here.
  4. Julio Gonzalez Cabillon. "Kiepert's hyperbola". Math Forum. Goodwin College of Professional Studies. Retrieved 9 May 2012.
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