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0 replies
jlacosta
Apr 2, 2025
0 replies
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>=512 different isosceles triangles whose vertices have the same color
parmenides51   3
N 3 minutes ago by AlexCenteno2007
Source: Mathematics Regional Olympiad of Mexico West 2016 P6
The vertices of a regular polygon with $2016$ sides are colored gold or silver. Prove that there are at least $512$ different isosceles triangles whose vertices have the same color.
3 replies
parmenides51
Sep 7, 2022
AlexCenteno2007
3 minutes ago
J
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Fourth power ineq
Project_Donkey_into_M4   1
N 2 hours ago by sqing
Source: 2018 Mock RMO tdp and kayak P1
Let $a,b,c,d \in \mathbb{R}^+$ such that $a+b+c+d \leq 1$. Prove that\[\sqrt[4]{(1-a^4)(1-b^4)(1-c^4)(1-d^4)}\geq 255\cdot abcd.\]
1 reply
Project_Donkey_into_M4
Yesterday at 6:20 PM
sqing
2 hours ago
J
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Is this FE solvable?
ItzsleepyXD   0
2 hours ago
Source: Original
Let $c_1,c_2 \in \mathbb{R^+}$. Find all $f : \mathbb{R^+} \rightarrow \mathbb{R^+}$ such that for all $x,y \in \mathbb{R^+}$ $$f(x+c_1f(y))=f(x)+c_2f(y)$$
0 replies
1 viewing
ItzsleepyXD
2 hours ago
0 replies
J
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Dear Sqing: So Many Inequalities...
hashtagmath   36
N 2 hours ago by sqing
I have noticed thousands upon thousands of inequalities that you have posted to HSO and was wondering where you get the inspiration, imagination, and even the validation that such inequalities are true? Also, what do you find particularly appealing and important about specifically inequalities rather than other branches of mathematics? Thank you :)
36 replies
hashtagmath
Oct 30, 2024
sqing
2 hours ago
J
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Graph of polynomials
Ecrin_eren   1
N Yesterday at 5:36 PM by vanstraelen
The graph of the quadratic polynomial with real coefficients y = px^2 + qx + r, called G1, intersects the graph of the polynomial y = x^2, called G2, at points A and B. The lines tangent to G2 at points A and B intersect at point C. It is known that point C lies on G1. What is the value of p?
1 reply
Ecrin_eren
Yesterday at 3:00 PM
vanstraelen
Yesterday at 5:36 PM
J
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polynomial with inequality
nhathhuyyp5c   1
N Apr 18, 2025 by matt_ve
Given the polynomial \( P(x) = x^3 + ax^2 + bx + c \), where \( a, b, c \) are real numbers. Suppose that \( P(x) \) has three distinct real roots and the polynomial \( Q(x) = P(x^2 + 12x - 32) \) has no real roots. Prove that
\[ P(1) > 69^3. \]
1 reply
nhathhuyyp5c
Apr 18, 2025
matt_ve
Apr 18, 2025
J
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Polynomials
CuriousBabu   12
N Apr 18, 2025 by wh0nix
\[ \frac{(x+y+z)^5 - x^5 - y^5 - z^5}{(x+y)(y+z)(z+x)} = 0 \]
Find the number of real solutions.
12 replies
CuriousBabu
Apr 14, 2025
wh0nix
Apr 18, 2025
J
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School Math Problem
math_cool123   6
N Apr 5, 2025 by anduran
Find all ordered pairs of nonzero integers $(a, b)$ that satisfy $$(a^2+b)(a+b^2)=(a-b)^3.$$
6 replies
math_cool123
Apr 2, 2025
anduran
Apr 5, 2025
J
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Polynomial optimization problem
ReticulatedPython   2
N Apr 2, 2025 by Mathzeus1024
Let $$p(x)=-ax^4+x^3$$, where $a$ is a real number. Prove that for all positive $a$, $$p(x) \le \frac{27}{256a^3}.$$
2 replies
ReticulatedPython
Mar 31, 2025
Mathzeus1024
Apr 2, 2025
J
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Prove that \( S \) contains all integers.
nhathhuyyp5c   1
N Mar 30, 2025 by GreenTea2593
Let \( S \) be a set of integers satisfying the following property: For every positive integer \( n \) and every set of coefficients \( a_0, a_1, \dots, a_n \in S \), all integer roots of the polynomial $P(x) = a_0 + a_1 x + \dots + a_n x^n $ are also elements of \( S \). It is given that \( S \) contains all numbers of the form \( 2^a - 2^b \) where \( a, b \) are positive integers. Prove that \( S \) contains all integers.









1 reply
nhathhuyyp5c
Mar 29, 2025
GreenTea2593
Mar 30, 2025
J
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Polynomial with roots in geometric progression
red_dog   0
Mar 21, 2025
Let $f\in\mathbb{C}[X], \ f=aX^3+bX^2+cX+d, \ a,b,c,d\in\mathbb{R}^*$ a polynomial whose roots $x_1,x_2,x_3$ are in geometric progression with ration $q\in(0,\infty)$. Find $S_n=x_1^n+x_2^n+x_3^n$.
0 replies
red_dog
Mar 21, 2025
0 replies
J
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polynomial
nghik33ccb   3
N Mar 18, 2025 by nghik33ccb
Find all polynomials P(x) with coefficients 1 or -1 that satisfy P with all real roots
3 replies
nghik33ccb
Feb 11, 2025
nghik33ccb
Mar 18, 2025
J
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2014 Community AIME / Marathon ... Algebra Medium #1 quartic
parmenides51   5
N Mar 16, 2025 by CubeAlgo15
Let there be a quartic function $f(x)$ with maximums $(4,5)$ and $(5,5)$. If $f(0) = -195$, and $f(10)$ can be expressed as $-n$ where $n$ is a positive integer, find $n$.

proposed by joshualee2000
5 replies
parmenides51
Jan 21, 2024
CubeAlgo15
Mar 16, 2025
J
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function composition with quadratics yields no real roots (Auckland MO 2024 P11)
Equinox8   2
N Mar 12, 2025 by alexheinis
It is known that for quadratic polynomials $P(x)=x^2+ax+b$ and $Q(x)=x^2+cx+d$ the equation $P(Q(x))=Q(P(x))$ does not have real roots. Prove that $b \neq d$.
2 replies
Equinox8
Mar 12, 2025
alexheinis
Mar 12, 2025
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J
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Parallel Lines and Q Point
taptya17   14
N Apr 6, 2025 by Haris1
Source: India EGMO TST 2025 Day 1 P3
Let $\Delta ABC$ be an acute angled scalene triangle with circumcircle $\omega$. Let $O$ and $H$ be the circumcenter and orthocenter of $\Delta ABC,$ respectively. Let $E,F$ and $Q$ be points on segments $AB,AC$ and $\omega$, respectively, such that
$$\angle BHE=\angle CHF=\angle AQH=90^\circ.$$Prove that $OQ$ and $AH$ intersect on the circumcircle of $\Delta AEF$.

Proposed by Antareep Nath
14 replies
taptya17
Dec 13, 2024
Haris1
Apr 6, 2025
J
Parallel Lines and Q Point
G H J
Reveal topic tags
geometry
L
G H BBookmark kLocked kLocked NReply
Source: India EGMO TST 2025 Day 1 P3
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taptya17
29 posts
taptya17
#1 Dec 13, 2024, 8:34 AM • 3 Y
Y by GeoKing, Rounak_iitr, SatisfiedMagma
Let $\Delta ABC$ be an acute angled scalene triangle with circumcircle $\omega$. Let $O$ and $H$ be the circumcenter and orthocenter of $\Delta ABC,$ respectively. Let $E,F$ and $Q$ be points on segments $AB,AC$ and $\omega$, respectively, such that
$$\angle BHE=\angle CHF=\angle AQH=90^\circ.$$Prove that $OQ$ and $AH$ intersect on the circumcircle of $\Delta AEF$.

Proposed by Antareep Nath
This post has been edited 2 times. Last edited by taptya17, Dec 17, 2024, 6:08 AM
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starchan
1603 posts
starchan
#2 Dec 13, 2024, 9:29 AM • 5 Y
Y by bin_sherlo, Rounak_iitr, mxlcv, GeoKing, HoRI_DA_GRe8
nice problem
solution
This post has been edited 1 time. Last edited by starchan, Dec 13, 2024, 1:24 PM
Reason: unriddling the typos
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LP088
6 posts
LP088
#3 Dec 13, 2024, 9:52 AM • 1 Y
Y by GeoKing
Nice
Sketch of my solution : Hc and Hb are reflections of H respect to AB and AC respectively, E is circumcenter of QHHc and F is circumcenter of HQHb now note that with angle chasing you can prove AEFQ(w) is concylice and OE and OF are tangent to w then by harmonic bundles you can finish the problem
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bin_sherlo
705 posts
bin_sherlo
#4 Dec 13, 2024, 10:11 AM • 2 Y
Y by GeoKing, egxa
Let $D,K,L$ be the feet of the altitudes from $A,B,C$ to $BC,CA,AB$ respectively. Note that $Q$ is $A-$queue point. Let $(AEF)\cap AH=P$.
Claim: $A,E,F,Q$ are concyclic.
Proof: Let's apply coaxiality lemma on $(AQHKL)$ and $(AQBC)$.
\[\frac{EL.EA}{EB.EA}\overset{?}{=}\frac{FK.FA}{FC.FA}\iff \frac{HL.HK}{HB.HC}=\frac{EA.\frac{LH}{HC}}{EA.\frac{HB}{HK}}=\frac{EL}{EB}\overset{?}{=}\frac{FK}{FC}=\frac{FA.\frac{HK}{HB}}{FA.\frac{HC}{HL}}=\frac{HK.HL}{HB.HC}\]Which proves the result.$\square$
Claim: $OE=OF$.
Proof: Work on the complex plane.
\[\overline{e}=\frac{1}{a}+\frac{1}{b}-\frac{e}{ab}, \ \ \frac{h-b}{h-e}=-\frac{\overline{h}-\overline{b}}{\overline{h}-\overline{e}}\implies \frac{1}{e-a-b-c}=\frac{1}{a+\frac{ec}{b}}\]Thus, $e=\frac{(2a+b+c)b}{b-c}$. Similarily $f=\frac{(2a+b+c)c}{(c-b)}$.
\[e.\overline{e}=\frac{(2a+b+c)b}{b-c}.\frac{\overline{(2a+b+c)}.\frac{1}{b}}{c-b}=\frac{(2a+b+c)c}{c-b}.\frac{\overline{(2a+b+c)}.\frac{1}{c}}{b-c}=f.\overline{f}\]So $OE=OF$.$\square$
Let $AO\cap (AEFQ)=S$. $\measuredangle FAS=90-\measuredangle B=\measuredangle PAE$ thus, $PS\parallel EF$. We have $OE=OF,OA=OQ$ and $A,F,E,Q$ are concyclic and $O$ is not the circumcenter of $(AEFQ)$ hence the perpendicular bisectors of $AQ,EF$ intersect at another point than circumcenter of $(AEF)$ which implies their perpendicular bisectors coincide. We see that $PS \parallel EF\parallel AQ$. Since $ASPQ$ is an isosceles trapezoid and $OA=OQ$, also $OS=OP$ must hold. $\measuredangle SPO=\measuredangle OSP=\measuredangle OAQ=\measuredangle AQO$ which proves the collinearity of $O,P,Q$ as desired.$\blacksquare$
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HoRI_DA_GRe8
597 posts
HoRI_DA_GRe8
#5 Dec 13, 2024, 12:12 PM • 17 Y
Y by bin_sherlo, GeoKing, iamnotgentle, LP088, starchan, alexanderhamilton124, ehuseyinyigit, Supercali, MrOreoJuice, SatisfiedMagma, Aryan-23, Combe2768, kamatadu, EpicBird08, BVKRB-, SilverBlaze_SY, ihategeo_1969
My first problem proposed to any contest and I am so happy it is selected.
starchan wrote:
nice problem
solution

This was more or less the solution I sent in.The problem was inspired by the last paragraph .I learnt about this isogonal conjugate thing in quadrilaterals from D4P3 of this year India TST .I had changed the conditions of the original problem from circumcentre to orthocentre and then played in geogebra to finally land up here !

Thanks everyone.
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ayeen_izady
32 posts
ayeen_izady
#6 Dec 15, 2024, 4:25 PM • 2 Y
Y by GeoKing, iliya8788
One can also show that $QM$ and $AO$ intersect on $(AEF)$ where $M$ is the midpoint of $AH$.
Anyways, very nice configuration!
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Om245
163 posts
Om245
#7 Dec 17, 2024, 4:30 AM • 3 Y
Y by taptya17, GeoKing, HoRI_DA_GRe8
Congratulations HoRI_DA_GRe8 :coolspeak: Indeed cool problem

Consider $E$ on $AC$ and $F$ on $AB$ (mainly cuz after writing whole solution I realize that it's opposite (weird))

Let $D = AH \cap BC$, $R = AQ \cap BC$ and $N=AH \cap EF$. It's well known that $(D,Q;B,C)=-1$. Now we project cross ratio from $A$ to get $$(AQ,AN;AE,AF)=-1$$As $N$ is midpoint of $EF$, we get $AQ \parallel EF$. As $N$ is center of circle $(AQH)$ we get $AQEF$ is cyclic trapezium.

Let $A'$ is point on $(ABC)$ such that $\angle A'BA = \angle A'CA = 90$. It's well known that $Q-H-M-A'$ where $M$ is midpoint of $BC$.
Notice by angle chase we get \[\Box AEHF \sim \Box CHBA'\]
Destination is now within reach; it's just an angle chase that will lead us there.
Let $X = OQ \cap AH$ then assuming $AC > AB$ we get $$\angle AXQ = \angle XAO + \angle XOA = \angle B - \angle C + 2 \angle QBA$$
By parallelograms similarity $$\angle AEF = \angle CA'H = \angle CA'Q = \angle CBQ$$Thus $$\angle AEQ = \angle AEF - \angle QEF = \angle QBC - \angle QAB = (\angle B + \angle QBA) + (\angle QBA - \angle C) = \angle AXQ$$Hence $X$ lie on circle $(AEF)$.

hehe Comments
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taptya17
29 posts
taptya17
#8 Dec 17, 2024, 6:04 AM • 2 Y
Y by Om245, GeoKing
Some part of it was done with Om245.

Since $\angle AFH+\angle AEH=180$, $H$ and $O$ are isogonal conjugates in $FECB$. Thus, $\angle OFE=\angle OEF=\angle BAC \implies OF=OE$ are tangents to $AEF$. We know $OA=OQ$.
As shown in Om245's solution above, parallelograms $AEHF$ and $BHCA'$ are similar and thus an angle chase tells us $AQ || EF$. Thus, since $O$ lies on the perpendicular bisectors of both $AQ$ and $EF$, we conclude that $AQEF$ must be an isosceles trapezium and hence cyclic. Further, $AO$ is the symmedian in $\Delta AEF$ and thus if $P=OQ\cap\odot AEF$ then by symmetry $AP$ must bisect $EF$ and thus $P\in AH$.
This post has been edited 4 times. Last edited by taptya17, Dec 17, 2024, 6:21 AM
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Sanjana42
19 posts
Sanjana42
#9 Dec 20, 2024, 9:30 AM • 1 Y
Y by GeoKing
Let $P=OQ\cap AH$. Let $E',F'$ be the feet from $B,C$ to $AC, AB$ respectively. By similar triangles we have $\frac{BF'}{F'E}=\frac{CE'}{E'F}$, so by spiral similarity we get $AQEF$ cyclic. Let the center of $(AQEF)$ be $O'$. Therefore $O'$ lies on the perpendicular bisectors of $AQ$ and $EF$.

Let $N=AH\cap EF$. Since $AFHE$ is clearly a parallelogram, $N$ is the midpoint of both $EF$ and $AH$. $\angle AQH=90^\circ\implies N$ is the center of $(AQH)\implies N$ lies on the perpendicular bisector of $AQ$. Therefore $N$ also lies on the perpendicular bisectors of $AQ$ and $EF$. (Clearly $N$ and $O'$ are distinct because $\angle A$ cannot be $90^\circ$.)

Since two points lie on both perpendicular bisectors, the perpendicular bisectors must be the same implying $AQEF$ is an isosceles trapezoid. Let $QF$ intersect $(ABC)$ again at $Y$. By Reims', $BY\parallel EF\parallel AQ$. Therefore $QY$ and $AB$ subtend equal arcs in $(ABC)$. Now $$\angle PQF = \angle OQY=\frac{180^\circ-\angle QOY}{2}=90^\circ-\angle QCY=90^\circ-C=\angle PAF.$$This implies $P\in (AQEF)$, as desired.
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GeoKing
518 posts
GeoKing
#10 Jan 1, 2025, 9:42 AM • 1 Y
Y by Om245
Solved with sanyalarnab
Note that $AEHF$ is a parallelogram . Let $D$ be the common midpoint of $AH,EF$. Since (AQ,AH;AB,AC)=-1 and $AH$ bisects $EF$ we have $AQ \parallel EF$ .Note that $(AQH)$ is a right triangle with circumcenter $D$ ,thus $EF$ is the perpendicular bisector of $QH$.Thus $Q$ is the reflection of $H$ across $EF$ which implies $AQEF$ is cyclic isosceles trapezoid. Let $AH$ meet $(AEF)$ again at $G$ and $QE$ meet $(ABC)$ again at $Y$. By reims theorem $YC \parallel EF$ which implies $AQYC$ is an isosceles trapezoid.
$\measuredangle YQO=90^\circ-\measuredangle QCY=90^\circ-\measuredangle CYA=90^\circ-\measuredangle CBA=\measuredangle EAG=\measuredangle EQG=\measuredangle YQG$.
Thus $Q-O-G$ are collinear.
https://cdn.discordapp.com/attachments/1247512024687181896/1323949288837087242/image.png?ex=67765f5c&is=67750ddc&hm=b14eee297feabbb9f3dfd1e113e4b9f9fc244ab953ec98c7ef1b41eb3c3dfd3e&
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TestX01
339 posts
TestX01
#11 Jan 4, 2025, 9:49 AM • 1 Y
Y by GeoKing
no proj :)

i want copic markers but im too poor

Let $G$ be the intersection point.

firstly, $BH\perp AC$ so $EH\parallel AC$. Similarly, $FH\parallel AB$. Using the Forgotten Coaxiality Lemma on $E,F$ with $(AH)$ and $(ABC)$, we want if $E'$ is foot of $H$ to $AB$ and $F'$ foot of $H$ to $AC$, that $\frac{EE'}{EB}=\frac{FF'}{FC}$ but this is because of $\triangle HBE\sim \triangle HCF$ and similarly defined altitude.

now let $AH$ intersect $(ABC)$ at $H'$. Forgotten coaxiality lemma makes us want $\frac{EE'}{EB}=\frac{GH}{GH'}$. But note that
\[\frac{EE'}{EB}=\frac{EE'\times EB}{EB^2}=\frac{EH^2}{EB^2}=\sin^2{90^\circ-\angle A}=\cos^2{\angle A}\]Now use ratio lemma on $\triangle QHH'$ so
\[\frac{GH}{GH'}=\frac{QH}{QH'}\times\frac{\sin HQO}{\sin H'QO}\]now $\angle HQO=90^\circ-\angle OQA=\angle AH'Q$ (because angle at centre theorem), and $\angle H'QO=90^\circ-\angle QAH'=\angle AHQ$.
Sine law in $\triangle QHH'$ means this relation is $\frac{QH}{QH'}$.
Hence, $\frac{GH}{GH'}=\left(\frac{QH}{QH'}\right)^2$, so all we want now is
\[\cos{\angle A}=\frac{QH}{QH'}\]Now, doing more trig,
\[\frac{QH}{QH'}=\frac{AH \sin \angle QAH}{\sin\angle QAH}\times \frac{\sin \angle AQH'}{AH'}=\frac{AH}{AH'}\times \sin\angle AQH'\]hence we just need \[\frac{AH}{AH'}=\frac{\sin \angle ACH}{\sin \angle ACH'}\]This is a direct consequence of ratio lemma on $\triangle ACH'$ and the well known fact $CH=CH'$.
This post has been edited 2 times. Last edited by TestX01, Jan 4, 2025, 9:51 AM
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ENDER2085
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ENDER2085
#12 Jan 25, 2025, 11:44 AM
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An Apollonius Circle
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ihategeo_1969
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ihategeo_1969
#13 Feb 23, 2025, 1:09 AM • 2 Y
Y by babarazamtruefan152-0, HoRI_DA_GRe8
Let $\triangle XYZ$ be orthic triangle of $\triangle ABC$.

Claim: $(AEF)$, $(AH)$, $(ABC)$ are coaxial.
Proof: Using the OG coaxiality lemma, we need to prove \[\frac{\text{Pow}(E,(AH))}{\text{Pow}(E,(ABC))}=\frac{\text{Pow}(F,(AH))}{\text{Pow}(F,(ABC))} \iff \frac{EZ}{EB}=\frac{FY}{FC}\]Which is true since $\triangle HEB \cup Z \overset{-}{\sim} \triangle HFC \cup Y$ because see that $\angle EZH=\angle FYH=90^{\circ}$. $\square$

Let $T=\overline{AH} \cap (AEF)$. See that $(Q,T;E,F) \overset{A}=(\overline{AQ} \cap \overline{BC},X;B,C)=-1$ and so all we need to prove is that $O$ is pole of $\overline{EF}$ in $(AEF)$.

Now since $\angle BHE+\angle CHF=180 ^{\circ}$, it is well known that this is equivalent to $H$ having an isogonal conjugate in $BEFC$ and it is obvious that this must be $O$.

To finish just look at this angle chase \[\angle OFE=\angle HFC=90 ^{\circ}-\angle ACH=\angle BAC=\angle EAF\]And so $\overline{OF}$ is tangent to $(AEF)$ and so is $\overline{OE}$ and done.

Remarks
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everythingpi3141592
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everythingpi3141592
#14 Apr 5, 2025, 1:57 PM • 1 Y
Y by HoRI_DA_GRe8
Note that $BEFC$ is convex, and $H$ satisfies $\angle BHE + \angle CHF = 180^{\circ}$, thus its isogonal conjugate in said quadrilateral exists. This must be O, due to its reflections in the angle bisectors of $B$, $C$. This means $\angle OEF = \angle HEC = 90^{\circ} - \angle HCE = \angle BAC = \angle EAF$, thus $OE$ and analogously $OF$ are both tangents to the circumcircle of $\triangle AEF$.

This means that $OA$ is the symmedian in $\triangle AEF$, and thus $AH$ being its reflection in angle bisector must be the median, so, $(AE, AF; AH, A\infty) = -1$. We project at $A$ to get that $AH$ intersects $(AEF)$ at the harmonic conjugate of $A'$, reflection of $A$ in the perpendicular bisector of $EF$. Reflecting back, about this line we see that in fact, this point is reflection of the isogonal conjugate of $A$ in the perpendicular bisector of $EF$, i.e. angle bisector of $\angle EOF$. Thus, it suffices to show that $OA$, $OQ$ are isogonal in $\angle EOF$, which we can do by proving that $AQ$ and $EF$ share a perpendicular bisector. For this, we prove $(AQEF)$ is concyclic, which would finish as the line joining $O$ with the centre of this circle works ($O$ is not the centre itself as it is intersection of tangents at $E$, $F$ and thus lies outside the circle)

To prove this, note that $Q$ is $(AE'F') \cap (ABC)$ where $E'$, $F'$ are the feet of perpendiculars from $B$, $C$ respectively. This is the centre of spiral similarity sending $BF'$ to $CE'$. To finish, note that $BF = \frac{BH}{\cos(90^{\circ}-A)}$ and $BF' = BH\cos(90^{\circ}-A)$, and thus $\frac{BF'}{BF}$ can be expressed in trigonometric ratios in $\angle BAC$, and thus it is equal to $\frac{CE'}{CE}$ which we can calculate analogously, thus the spiral similarity also sends $F$ to $E$, and we are done.

Remark/light-hearted rant: This does indeed give TST Day 4 P3 vibes as author has mentioned above, in some ways the opposite since you are isogonal conjugating perpendiculars at H and not O. But unlike TST, I did not fail this time redemption. We can only hope that holds for this edition of TST as well true redemption, that being said, I did find this problem interesting, with its 'config geo' flavor, thanks @HoRI_DA_GRe8 for giving me the idea to try this problem
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Haris1
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Haris1
#15 Apr 6, 2025, 11:38 AM
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Just $\sqrt(AE*AF)$ invert then the whole problem turns into a very famous $Hm$, $Dm$ config which is very easy to prove.
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