Orthic triangle

Revision as of 19:06, 11 May 2021 by Geometry285 (talk | contribs) (Excenters of the orthic triangle)
Case 1: $\triangle ABC$ is acute.
Case 2: $\triangle ABC$ is obtuse.

In geometry, given any $\triangle ABC$, let $D$, $E$, and $F$ denote the feet of the altitudes from $A$, $B$, and $C$, respectively. Then, $\triangle DEF$ is called the orthic triangle of $\triangle ABC$.

It's easy to see that there is no orthic triangle if $\triangle ABC$ is right. The two cases are when $\triangle ABC$ is either acute or obtuse must be handled separately, as they each carry different characteristics.

Orthic triangles are not unique to their mother triangles, as one acute and one to three obtuse triangles are guaranteed to have the same orthic triangle. To see this, take an acute triangle and swap its orthocenter and any vertex to get an obtuse triangle. It's easy to verify that this placement of the orthocenter is correct and that the orthic triangle will remain the same as before the swapping, as seen in the diagrams to the right.

Cyclic quadrilaterals

In both the acute and obtuse case, quadrilaterals $ADEB$, $BEFC$, $CFAD$, $AEHF$, $BFHD$, and $CDHE$ are cyclic.

Proof: we will be using directed angles, denoted by $\measuredangle$ instead of the conventional $\angle$. We know that \[\measuredangle ADB = 90^{\circ} = \measuredangle AEB,\] and thus $ADEB$ is cyclic. In addition, \[\measuredangle AEH = 90^{\circ} = \measuredangle AFH,\] so $AEHF$ is also cyclic. It follows that the other cyclic quadrilaterals are also cyclic. $\square$

These cyclic quadrilaterals make frequent appearances in olympiad geometry and are the most crucial section of this article.

Connection with incenters and excenters

Incenter of the orthic triangle

If $\triangle ABC$ is acute, then the incenter of the orthic triangle of $\triangle ABC$ is the orthocenter $H$.


If $\triangle ABC$ is obtuse, then the incenter of the orthic triangle of $\triangle ABC$ is the obtuse vertex.

Excenters of the orthic triangle

For any acute $\triangle ABC$ and any $\triangle DEF$, $\triangle DEF$ is the orthic triangle of $\triangle ABC$ if and only if $A$, $B$, and $C$ are the excenters of $\triangle DEF$.

Proof: First, we show that the orthic triangle leads to the excenters. Let $D$, $E$, and $F$ be on $\overline{AB}$, $\overline{BC}$, and $\overline{CA}$, respectively. Because $ADEB$ is cyclic, $\angle EDC = \angle A$. Likewise, $\angle BDF = \angle A$ as well. Then because $\angle BDF + \angle D + \angle EDC = 180^{\circ}$, $\angle A + \angle D + \angle A = 180^{\circ}$ and so $\angle D = 180^{\circ} - 2\angle A$.

Thus, the exterior angle of $\angle D$ is $2\angle A$. But $\angle BDF = \angle EDC = \angle A$, so $\overline{BC}$ bisects the exterior angle of $\angle D$. Similarly, $\overline{CA}$ and $\overline{AB}$ bisect the exterior angles of $\angle E$ and $\angle F$ respectively. Thus, the intersections of $\overline{AB}$, $\overline{BC}$, and $\overline{CA}$ (namely $A$, $B$, and $C$) are the excenters of $\triangle DEF$, and we're done.

Next, we show that the excenters lead to the orthic triangle. Let $A$, $B$, and $C$ be the $D$-excenter, $E$-excenter, and $F$-excenter of $\triangle DEF$, and let $H$ be the incenter of $\triangle DEF$. $A$ is equidistant from $\overline{DE}$ and $\overline{FE}$, so $A$ is on $\overline{DH}$, and $\overline{AH}$ is an internal angle bisector of $\angle D$.

We know that $\angle ADE = \frac{1}{2} \angle D$ and because $C$ is an $F$-excenter of $\triangle DEF$, $\angle EDC = 90^{\circ} - \frac{1}{2} \angle D$. Thus, $\angle ADC = 90^{\circ}$, and because $D$ is on $\overline{BC}$, $D$ is the foot of the altitude from $A$ of $\triangle ABC$. Similarly, $E$ and $F$ are feet of the altitudes from $B$ and $C$, respectively. Then $\triangle DEF$ is the orthic triangle of $\triangle ABC$, and we are done. $\square$

This lemma makes frequent appearances in olympiad geometry. Problems written in either excenters or the orthic triangle can often be solved by shifting perspective to the other, via the medium of this lemma. Also, note the converse works as well.

In the obtuse case, the two vertices with acute angles and the orthocenter of $\triangle ABC$ are the excenters.

Relationship with the incenter/excenter lemma

With this knowledge in mind, we can transfer results about the incenter and excenters to the orthic triangle. In particular, the incenter/excenter lemma can be translated into the language of the orthic triangle. It tells that all six cyclic quadrilaterals of the orthic triangle have a circumcenter on the nine-point circle of $\triangle ABC$.

In the case where $\triangle ABC$ is acute, quadrilaterals $AEHF$, $BFHD$, and $CDHE$ follow immediately from the lemma. Actually, because $\angle AEH = 90^{\circ}$, the circumcenter of $AEHF$ is the midpoint of $A$ and $H$, called an Euler point. It follows that the circumcenters of $BFHD$ and $CDHE$ are the other two Euler points.

As for $ADEB$, $BEFC$, and $CFDA$, via the inscribed angle theorem, their circumcenters are the midpoints of the side lengths of $\triangle ABC$, which we know to be on the nine-point circle.

Identical reasoning follows that in the obtuse case, the six cyclic quadrilaterals still have circumcenters on the nine-point circle.



  • Let $\triangle ABC$ be an acute triangle with $D$, $E$, $F$ the feet of the altitudes lying on $\overline{BC}$, $\overline{CA}$, and $\overline{AB}$ respectively. One of the intersection points of the line $\overline{EF}$ and the circumcircle is $P$. The lines $\overline{BP}$ and $\overline{DF}$ meet at point $Q$. Prove that $|AP| = |AQ|$. (IMO Shortlist 2010 G1)

See also

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