# Lemoine point Information

*https://en.wikipedia.org/wiki/Lemoine_point*

In
geometry, the **symmedian point**, **Lemoine point** or **Grebe point** is the intersection of the three
symmedians (
medians reflected at the associated
angle bisectors) of a triangle.

Ross Honsberger called its existence "one of the crown jewels of modern geometry".^{
[1]}

In the
Encyclopedia of Triangle Centers the symmedian point appears as the sixth point, X(6).^{
[2]} For a non-equilateral triangle, it lies in the open
orthocentroidal disk punctured at its own center, and could be any point therein.^{
[3]}

The symmedian point of a triangle with side lengths a, b and c has homogeneous
trilinear coordinates [*a* : *b* : *c*].^{
[2]}

An algebraic way to find the symmedian point is to express the triangle by three linear equations in two unknowns given by the
hesse normal forms of the corresponding lines. The solution of this
overdetermined system found by the
least squares method gives the coordinates of the point. It also solves the optimization problem to find the point with a minimal sum of squared distances from the sides.
The
Gergonne point of a triangle is the same as the symmedian point of the triangle's
contact triangle.^{
[4]}

The symmedian point of a triangle ABC can be constructed in the following way: let the
tangent lines of the circumcircle of ABC through B and C meet at A', and analogously define B' and C'; then A'B'C' is the
tangential triangle of ABC, and the lines AA', BB' and CC' intersect at the symmedian point of ABC.^{
[a]} It can be shown that these three lines meet at a point using
Brianchon's theorem. Line AA' is a symmedian, as can be seen by drawing the circle with center A' through B and C.^{[
citation needed]}

The French mathematician
Émile Lemoine proved the existence of the symmedian point in 1873, and
Ernst Wilhelm Grebe published a paper on it 1847.
Simon Antoine Jean L'Huilier had also noted the point in 1809.^{
[1]}

For the extension to an irregular tetrahedron see symmedian.

## Notes

**^**If ABC is a right triangle with right angle at A, this statement needs to be modified by dropping the reference to AA' since the point A' does not exist.

## References

- ^
^{a}^{b}Honsberger, Ross (1995), "Chapter 7: The Symmedian Point",*Episodes in Nineteenth and Twentieth Century Euclidean Geometry*, Washington, D.C.: Mathematical Association of America. - ^
^{a}^{b}Encyclopedia of Triangle Centers, accessed 2014-11-06. **^**Bradley, Christopher J.; Smith, Geoff C. (2006), "The locations of triangle centers",*Forum Geometricorum*,**6**: 57–70.**^**Beban-Brkić, J.; Volenec, V.; Kolar-Begović, Z.; Kolar-Šuper, R. (2013), "On Gergonne point of the triangle in isotropic plane",*Rad Hrvatske Akademije Znanosti i Umjetnosti*,**17**: 95–106, MR 3100227.