Feuerbach hyperbola

It has the trilinear equation ${\displaystyle {\frac {\cos B-\cos C}{\alpha }}+{\frac {\cos C-\cos A}{\beta }}+{\frac {\cos A-\cos B}{\gamma }}}$ (here ${\displaystyle A,B,C}$  are the angles at the respective vertices and ${\displaystyle (\alpha ,\beta ,\gamma )}$  is the barycentric coordinate).^[2]

Like other rectangular hyperbolas, the orthocenter of any three points on the curve lies on the hyperbola. So, the orthocenter of the triangle ${\displaystyle ABC}$  lies on the curve.

The line ${\displaystyle OI}$  is tangent to this hyperbola at ${\displaystyle I}$ .

The hyperbola is the isogonal conjugate of ${\displaystyle OI}$ , the line joining the circumcenter and the incenter.^[3] This fact leads to a few interesting properties. Specifically all the points lying on the line ${\displaystyle OI}$  have their isogonal conjugates lying on the hyperbola. The Nagel point lies on the curve since its isogonal conjugate is the point of concurrency of the lines joining the vertices and the opposite Mixtilinear incircle touchpoints, also the in-similitude of the incircle and the circumcircle. Similarly, the Gergonne point lies on the curve since its isogonal conjugate is the ex-similitude of the incircle and the circumcircle.

The pedal circle of any point on the hyperbola passes through the Feuerbach point, the center of the hyperbola.

Given a triangle ${\displaystyle ABC}$ , let ${\displaystyle A_{1},B_{1},C_{1}}$  be the touchpoints of the incircle ${\displaystyle \odot I}$  with the sides of the triangle opposite to vertices ${\displaystyle A,B,C}$  respectively. Let ${\displaystyle X,Y,Z}$  be points lying on the lines ${\displaystyle IA_{1},IB_{1},IC_{1}}$  such that ${\displaystyle IX=IY=IZ}$ . Then, the lines ${\displaystyle AX,BY,CZ}$  are concurrent at a point lying on the Feuerbach hyperbola.

The Kariya's theorem has a long history.^[4] It was proved independently by Auguste Boutin and V. Retali.,^[5][6][7] but it became famous only after Kariya's paper.^[8] Around that time, many generalizations of this result were given. Kariya's theorem can be used for the construction of the Feuerbach hyperbola.

Both Lemoine's theorem and Kariya's theorem are a special case of Jacobi's theorem.

• Kiepert hyperbola, the unique conic which passes through a triangle's three vertices, its centroid, and its orthocenter
• Jeřábek hyperbola, a rectangular hyperbola centered on a triangle's nine-point circle and passing through the triangle's three vertices as well as its circumcenter, orthocenter, and various other notable centers

• Feuerbach Hyperbola, MathWorld