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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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0 replies
jlacosta
Apr 2, 2025
0 replies
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ALGEBRA INEQUALITY
Tony_stark0094   2
N 10 minutes ago by Sedro
$a,b,c > 0$ Prove that $$\frac{a^2+bc}{b+c} + \frac{b^2+ac}{a+c} + \frac {c^2 + ab}{a+b} \geq a+b+c$$
2 replies
Tony_stark0094
an hour ago
Sedro
10 minutes ago
J
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Checking a summand property for integers sufficiently large.
DinDean   2
N 31 minutes ago by DinDean
For any fixed integer $m\geqslant 2$, prove that there exists a positive integer $f(m)$, such that for any integer $n\geqslant f(m)$, $n$ can be expressed by a sum of positive integers $a_i$'s as
\[n=a_1+a_2+\dots+a_m,\]where $a_1\mid a_2$, $a_2\mid a_3$, $\dots$, $a_{m-1}\mid a_m$ and $1\leqslant a_1<a_2<\dots<a_m$.
2 replies
DinDean
Yesterday at 5:21 PM
DinDean
31 minutes ago
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Bunnies hopping around in circles
popcorn1   22
N 32 minutes ago by awesomeming327.
Source: USA December TST for IMO 2023, Problem 1 and USA TST for EGMO 2023, Problem 1
There are $2022$ equally spaced points on a circular track $\gamma$ of circumference $2022$. The points are labeled $A_1, A_2, \ldots, A_{2022}$ in some order, each label used once. Initially, Bunbun the Bunny begins at $A_1$. She hops along $\gamma$ from $A_1$ to $A_2$, then from $A_2$ to $A_3$, until she reaches $A_{2022}$, after which she hops back to $A_1$. When hopping from $P$ to $Q$, she always hops along the shorter of the two arcs $\widehat{PQ}$ of $\gamma$; if $\overline{PQ}$ is a diameter of $\gamma$, she moves along either semicircle.

Determine the maximal possible sum of the lengths of the $2022$ arcs which Bunbun traveled, over all possible labellings of the $2022$ points.

Kevin Cong
22 replies
popcorn1
Dec 12, 2022
awesomeming327.
32 minutes ago
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Iran second round 2025-q1
mohsen   4
N 33 minutes ago by MathLuis
Find all positive integers n>2 such that sum of n and any of its prime divisors is a perfect square.
4 replies
mohsen
Apr 19, 2025
MathLuis
33 minutes ago
J
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Σ to ∞
phiReKaLk6781   3
N Yesterday at 6:12 PM by Maxklark
Evaluate: $ \sum\limits_{k=1}^\infty \frac{1}{k\sqrt{k+2}+(k+2)\sqrt{k}}$
3 replies
phiReKaLk6781
Mar 20, 2010
Maxklark
Yesterday at 6:12 PM
J
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Geometric inequality
ReticulatedPython   0
Yesterday at 5:12 PM
Let $A$ and $B$ be points on a plane such that $AB=n$, where $n$ is a positive integer. Let $S$ be the set of all points $P$ such that $\frac{AP^2+BP^2}{(AP)(BP)}=c$, where $c$ is a real number. The path that $S$ traces is continuous, and the value of $c$ is minimized. Prove that $c$ is rational for all positive integers $n.$
0 replies
ReticulatedPython
Yesterday at 5:12 PM
0 replies
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Inequalities
sqing   27
N Yesterday at 3:51 PM by Jackson0423
Let $ a,b $ be reals such that $ a^2+ab+b^2 =3$ . Prove that
$$ \frac{4}{ 3}\geq \frac{1}{ a^2+5 }+ \frac{1}{ b^2+5 }+ab \geq -\frac{11}{4 }$$$$ \frac{13}{ 4}\geq \frac{1}{ a^2+5 }+ \frac{1}{ b^2+5 }+ab \geq -\frac{2}{3 }$$$$ \frac{3}{ 2}\geq \frac{1}{ a^4+3 }+ \frac{1}{ b^4+3 }+ab \geq -\frac{17}{6 }$$$$ \frac{19}{ 6}\geq \frac{1}{ a^4+3 }+ \frac{1}{ b^4+3 }-ab \geq -\frac{1}{2}$$Let $ a,b $ be reals such that $ a^2-ab+b^2 =1 $ . Prove that
$$ \frac{3}{ 2}\geq \frac{1}{ a^2+3 }+ \frac{1}{ b^2+3 }+ab \geq \frac{4}{15 }$$$$ \frac{14}{ 15}\geq \frac{1}{ a^2+3 }+ \frac{1}{ b^2+3 }-ab \geq -\frac{1}{2 }$$$$ \frac{3}{ 2}\geq \frac{1}{ a^4+3 }+ \frac{1}{ b^4+3 }+ab \geq \frac{13}{42 }$$$$ \frac{41}{ 42}\geq \frac{1}{ a^4+3 }+ \frac{1}{ b^4+3 }-ab \geq -\frac{1}{2 }$$
27 replies
sqing
Apr 16, 2025
Jackson0423
Yesterday at 3:51 PM
J
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Problem of the Week--The Sleeping Beauty Problem
FiestyTiger82   1
N Yesterday at 3:24 PM by martianrunner
Put your answers here and discuss!
The Problem
1 reply
FiestyTiger82
Yesterday at 2:30 PM
martianrunner
Yesterday at 3:24 PM
J
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Inequalities
sqing   4
N Yesterday at 1:09 PM by sqing
Let $ a,b,c $ be real numbers such that $ a^2+b^2+c^2=1. $ Prove that$$ |a-b|+|b-2c|+|c-3a|\leq 5$$$$|a-2b|+|b-3c|+|c-4a|\leq \sqrt{42}$$$$ |a-b|+|b-\frac{11}{10}c|+|c-a|\leq \frac{29}{10}$$
4 replies
sqing
Yesterday at 5:05 AM
sqing
Yesterday at 1:09 PM
J
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Inequalities
nhathhuyyp5c   2
N Yesterday at 12:38 PM by pooh123
Let $a, b, c$ be non-negative real numbers such that $a^2 + b^2 + c^2 = 3$. Find the maximum and minimum values of the expression
\[ P = \frac{a}{a^2 + 2} + \frac{b}{b^2 + 2} + \frac{c}{c^2 + 2}. \]
2 replies
nhathhuyyp5c
Apr 20, 2025
pooh123
Yesterday at 12:38 PM
J
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Challenging Optimization Problem
Shiyul   5
N Yesterday at 12:28 PM by exoticc
Let $xyz = 1$. Find the minimum and maximum values of $\frac{1}{1 + x + xy}$ + $\frac{1}{1 + y + yz}$ + $\frac{1}{1 + z + zx}$

Can anyone give me a hint? I got that either the minimum or maximum was 1, but I'm sure if I'm correct.
5 replies
Shiyul
Monday at 8:20 PM
exoticc
Yesterday at 12:28 PM
J
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Radical Axes and circles
mathprodigy2011   4
N Yesterday at 7:53 AM by spiderman0
Can someone explain how to do this purely geometrically?
4 replies
mathprodigy2011
Yesterday at 1:58 AM
spiderman0
Yesterday at 7:53 AM
J
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Combinatoric
spiderman0   0
Yesterday at 7:46 AM
Let $ S = \{1, 2, 3, \ldots, 2024\}.$ Find the maximum positive integer $n \geq 2$ such that for every subset $T \subset S$ with n elements, there always exist two elements a, b in T such that:

$|\sqrt{a} - \sqrt{b}| < \frac{1}{2} \sqrt{a - b}$
0 replies
spiderman0
Yesterday at 7:46 AM
0 replies
J
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BMT 2018 Algebra Round Problem 7
IsabeltheCat   5
N Yesterday at 6:56 AM by P162008
Let $$h_n := \sum_{k=0}^n \binom{n}{k} \frac{2^{k+1}}{(k+1)}.$$Find $$\sum_{n=0}^\infty \frac{h_n}{n!}.$$
5 replies
IsabeltheCat
Dec 3, 2018
P162008
Yesterday at 6:56 AM
J
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J
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Beautiful problem
luutrongphuc   13
N Apr 10, 2025 by ItzsleepyXD
(Phan Quang Tri) Let triangle $ABC$ be circumscribed about circle $(I)$, and let $H$ be the orthocenter of $\triangle ABC$. The circle $(I)$ touches line $BC$ at $D$. The tangent to the circle $(BHC)$ at $H$ meets $BC$ at $S$. Let $J$ be the midpoint of $HI$, and let the line $DJ$ meet $(I)$ again at $X$. The tangent to $(I)$ parallel to $BC$ meets the line $AX$ at $T$. Prove that $ST$ is tangent to $(I)$.
13 replies
luutrongphuc
Apr 4, 2025
ItzsleepyXD
Apr 10, 2025
J
Beautiful problem
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Reveal topic tags
geometry
L
G H BBookmark kLocked kLocked NReply
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luutrongphuc
35 posts
luutrongphuc
#1 Apr 4, 2025, 5:35 AM • 1 Y
Y by PikaPika999
(Phan Quang Tri) Let triangle $ABC$ be circumscribed about circle $(I)$, and let $H$ be the orthocenter of $\triangle ABC$. The circle $(I)$ touches line $BC$ at $D$. The tangent to the circle $(BHC)$ at $H$ meets $BC$ at $S$. Let $J$ be the midpoint of $HI$, and let the line $DJ$ meet $(I)$ again at $X$. The tangent to $(I)$ parallel to $BC$ meets the line $AX$ at $T$. Prove that $ST$ is tangent to $(I)$.
This post has been edited 1 time. Last edited by luutrongphuc, Apr 7, 2025, 1:49 AM
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aidenkim119
32 posts
aidenkim119
#2 Apr 5, 2025, 12:45 PM • 1 Y
Y by PikaPika999
bump0ppppppppp
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whwlqkd
97 posts
whwlqkd
#3 Apr 6, 2025, 11:26 AM • 2 Y
Y by aidenkim119, PikaPika999
BUMPPPPPP
Why it didn’t proposed for imo p3/6
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aidenkim119
32 posts
aidenkim119
#4 Apr 6, 2025, 11:29 AM • 1 Y
Y by PikaPika999
whwlqkd wrote:
BUMPPPPPP
Why it didn’t proposed for imo p3/6

Solved but i dont know how to type this in latex sorry
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whwlqkd
97 posts
whwlqkd
#5 Apr 6, 2025, 11:55 AM
Y by
\angle:
$\angle$
\triangle:
$\triangle$
\perp:
$\perp$
\times:
$\times$
\cap:
$\cap$
etc
(You can search the latex code more)
If you want to write $\LaTeX$, you have to write dollar sign before and after the code.
Some example of latex:
$1+1=2$
$2\times 5=10$
$3-(1-2)=4$
$\frac{3}{67}$
etc
Click the text, then you can see the latex code
This post has been edited 3 times. Last edited by whwlqkd, Apr 6, 2025, 12:01 PM
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whwlqkd
97 posts
whwlqkd
#9 Apr 6, 2025, 12:11 PM
Y by
You have to write $ on the end of the alphabet
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aidenkim119
32 posts
aidenkim119
#19 Apr 6, 2025, 12:22 PM • 1 Y
Y by whwlqkd
Use six point line and polepolar to erase useless points

Then use pascal to change the question

Then easy calaulation finishes it
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hukilau17
283 posts
hukilau17
#26 Apr 6, 2025, 7:53 PM • 1 Y
Y by PikaPika999
No one's actually going to post a solution? All right, here goes.

Complex bash with the incircle of $\triangle ABC$ as the unit circle, and let it touch $AC,AB$ at $E,F$ respectively, and let $\triangle ABC$ have circumcenter $O$, so
$$|d|=|e|=|f|=1$$$$a = \frac{2ef}{e+f}$$$$b = \frac{2df}{d+f}$$$$c = \frac{2de}{d+e}$$$$o = \frac{2def(d+e+f)}{(d+e)(d+f)(e+f)}$$$$h = a+b+c-2o = \frac{2(d^2e^2+d^2ef+d^2f^2+de^2f+def^2+e^2f^2)}{(d+e)(d+f)(e+f)}$$$$j = \frac{h}2 = \frac{d^2e^2+d^2ef+d^2f^2+de^2f+def^2+e^2f^2}{(d+e)(d+f)(e+f)}$$Now we find the coordinate of $S$. Since $S$ lies on line $BC$ we have
$$\overline{s} = \frac{2d-s}{d^2}$$Since line $SH$ is tangent to the circumcircle of $\triangle BHC$, we have
$$\frac{(b-c)(h-s)}{(b-h)(c-h)} \in \mathbb{R} \implies \frac{d(h-s)}{ef} \in i\mathbb{R}$$$$\frac{d\left[2(d^2e^2+d^2ef+d^2f^2+de^2f+def^2+e^2f^2) - s(d+e)(d+f)(e+f)\right]}{ef(d+e)(d+f)(e+f)} = -\frac{ef\left[2d^2(d^2+de+df+e^2+ef+f^2) - (2d-s)(d+e)(d+f)(e+f)\right]}{d^3(d+e)(d+f)(e+f)}$$$$2d^4(d^2e^2+d^2ef+d^2f^2+de^2f+def^2+e^2f^2) - d^4s(d+e)(d+f)(e+f) = -2d^2e^2f^2(d^2+de+df+e^2+ef+f^2) + 2de^2f^2(d+e)(d+f)(e+f) - e^2f^2s(d+e)(d+f)(e+f)$$$$s = \frac{2d^4(d^2e^2+d^2ef+d^2f^2+de^2f+def^2+e^2f^2) + 2d^2e^2f^2(d^2+de+df+e^2+ef+f^2) - 2de^2f^2(d+e)(d+f)(e+f)}{d^4(d+e)(d+f)(e+f) - e^2f^2(d+e)(d+f)(e+f)}$$We simplify this to get
$$s = \frac{2d(d^5e^2+d^5ef+d^5f^2+d^4e^2f+d^4ef^2+2d^3e^2f^2-de^3f^3-e^4f^3-e^3f^4)}{(d+e)(d+f)(e+f)(d^2+ef)(d^2-ef)}$$Next we find the coordinate of $X$. We have
$$d - j = \frac{d^3e+d^3f+d^2ef-e^2f^2}{(d+e)(d+f)(e+f)}$$and so
$$x = \frac{d-j}{d\overline{\jmath}-1} = -\frac{d-j}{d(\overline{d}-\overline{\jmath})} = -\frac{d^3e+d^3f+d^2ef-e^2f^2}{e^2f+ef^2+def-d^3}$$Now we solve the rest of this problem in reverse. We know $T$ doesn't lie on line $BC$, so if the line $ST$ is tangent to the unit circle, it must be the other tangent to the unit circle passing through $S$ (besides line $BC$). So letting the other tangent through $S$ touch the unit circle at $U$, we have
$$s = \frac{2du}{d+u}$$and so
$$u = \frac{ds}{2d-s}$$Now
$$2d - s = \frac{2d\left[(d^4-e^2f^2)(d+e)(d+f)(e+f) - (d^5e^2+d^5ef+d^5f^2+d^4e^2f+d^4ef^2+2d^3e^2f^2-de^3f^3-e^4f^3-e^3f^4)\right]}{(d+e)(d+f)(e+f)(d^2+ef)(d^2-ef)}$$which we simplify to
$$2d - s = -\frac{2d(-d^6e-d^6f-d^5ef+2d^3e^2f^2+d^2e^3f^2+d^2e^2f^3+de^4f^2+de^3f^3+de^2f^4)}{(d+e)(d+f)(e+f)(d^2+ef)(d^2-ef)}$$So
$$u = -\frac{d^5e^2+d^5ef+d^5f^2+d^4e^2f+d^4ef^2+2d^3e^2f^2-de^3f^3-e^4f^3-e^3f^4}{-d^5e-d^5f-d^4ef+2d^2e^2f^2+de^3f^2+de^2f^3+e^4f^2+e^3f^3+e^2f^4}$$Then let the tangent to the unit circle at $U$ meet the tangent line to the unit circle parallel to $BC$ at $V$. We want to show that $V$ lies on line $AX$ -- then it will follow that $V=T$ and that $ST$ is tangent to the unit circle at $U$. Now
$$v = \frac{2(-d)u}{-d+u} = -\frac{2d(d^5e^2+d^5ef+d^5f^2+d^4e^2f+d^4ef^2+2d^3e^2f^2-de^3f^3-e^4f^3-e^3f^4)}{-d^6e-d^6f+d^5e^2+d^5f^2+d^4e^2f+d^4ef^2+4d^3e^2f^2+d^2e^3f^2+d^2e^2f^3+de^4f^2+de^2f^4-e^4f^3-e^3f^4}$$Then we find the vectors
$$a-x = \frac{2ef(e^2f+ef^2+def-d^3) + (e+f)(d^3e+d^3f+d^2ef-e^2f^2)}{(e+f)(e^2f+ef^2+def-d^3)} = \frac{d^3e^2+d^3f^2+d^2e^2f+d^2ef^2+2de^2f^2+e^3f^2+e^2f^3}{(e+f)(e^2f+ef^2+def-d^3)}$$and
\begin{align*} a-v &= \frac{2ef(-d^6e-d^6f+d^5e^2+d^5f^2+d^4e^2f+d^4ef^2+4d^3e^2f^2+d^2e^3f^2+d^2e^2f^3+de^4f^2+de^2f^4-e^4f^3-e^3f^4) + 2d(e+f)(d^5e^2+d^5ef+d^5f^2+d^4e^2f+d^4ef^2+2d^3e^2f^2-de^3f^3-e^4f^3-e^3f^4)}{(e+f)(-d^6e-d^6f+d^5e^2+d^5f^2+d^4e^2f+d^4ef^2+4d^3e^2f^2+d^2e^3f^2+d^2e^2f^3+de^4f^2+de^2f^4-e^4f^3-e^3f^4)} \\ &= \frac{2(d^6e^3+d^6e^2f+d^6ef^2+d^6f^3+2d^5e^3f+2d^5e^2f^2+2d^5ef^3+3d^4e^3f^2+3d^4e^2f^3+4d^3e^3f^3-2de^4f^4-e^5f^4-e^4f^5)}{(e+f)(-d^6e-d^6f+d^5e^2+d^5f^2+d^4e^2f+d^4ef^2+4d^3e^2f^2+d^2e^3f^2+d^2e^2f^3+de^4f^2+de^2f^4-e^4f^3-e^3f^4)} \end{align*}Now there's only one way that the numerator of $a-v$ could conceivably factor so that $\frac{a-x}{a-v}$ is real, and so we conveniently discover the factorization
$$a-v = \frac{2(d^3e+d^3f+d^2ef-e^2f^2)(d^3e^2+d^3f^2+d^2e^2f+d^2ef^2+2de^2f^2+e^3f^2+e^2f^3)}{(e+f)(-d^6e-d^6f+d^5e^2+d^5f^2+d^4e^2f+d^4ef^2+4d^3e^2f^2+d^2e^3f^2+d^2e^2f^3+de^4f^2+de^2f^4-e^4f^3-e^3f^4)}$$Then
$$\frac{a-x}{a-v} = \frac{-d^6e-d^6f+d^5e^2+d^5f^2+d^4e^2f+d^4ef^2+4d^3e^2f^2+d^2e^3f^2+d^2e^2f^3+de^4f^2+de^2f^4-e^4f^3-e^3f^4}{2(d^3e+d^3f+d^2ef-e^2f^2)(e^2f+ef^2+def-d^3)}$$This is equal to its conjugate and thus real. $\blacksquare$
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aidenkim119
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aidenkim119
#28 Apr 8, 2025, 2:16 AM
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Any synthetic proof?
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WLOGQED1729
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WLOGQED1729
#29 Apr 8, 2025, 6:53 AM • 1 Y
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Fantastic Problem! Here’s my synthetic proof.
First WLOG, we can assume that $AB<AC$
Part 1 Simplify the problem
Let $(I)$ tangent to $AB,AC$ at $F,E$, respectively.
Let $L \neq D$ be a point on $(I)$ s.t. $SL$ is tangent to $(I)$ and define $D’$ as the antipode of $D$ wrt. $(I)$
Let $T’$ be the intersection between $SL$ and the tangent line of $(I)$ at $D’$
If we can prove that $A,T’,X$ are collinear, we can conclude that $T’=T$ and we’re done.
Next, by pole-polar duality we know that poles are collinear if and only if its polars are concurrent.
Thus, we can just prove that $D’L$, $EF$ and the tangent of $(I)$ at $X$ are concurrent.
This is equivalent to show that there exists an involution on $(I)$ which swaps $(D’,L),(E,F)$ and $(X,X)$.

Part 2 Breakdown the problems into different parts
Since $D$ lies on $(I)$, an involution swapping $(D', L), (E, F), (X, X)$ on $(I)$
is equivalent to an involution on the pencil from $D$ swapping $(DD', DL), (DE, DF), (DX, DX)$.
Let $DL, DX, DD'$ intersect $EF$ at $L', X', K$, respectively.
Projecting this pencil onto line $EF$, we seek an involution on $EF$ that swaps $(K, L'), (E, F), (X', X')$.
Let $AK, AX, AL'$ intersect $BC$ at $M, Y, T$, respectively.
Projecting through $A$ onto line $BC$, this reduces to showing that there exists an involution on $BC$ that swaps $(M, T), (C, B), (Y, Y)$.
We claim that $HY$ bisects $\angle BHC$ and $TH,MH$ are isogonal conjugate wrt. $\angle BHC$ and will prove in the next section. If this is true, we get the desired involution.

Part 3 Solving sub problem 1
We’re going to prove that $TH,MH$ are isogonal conjugate wrt. $\angle BHC$
Recall the well known lemma which is used in 2005 G6, $AK$ bisects $BC$. We deduce that $M$ is the midpoint of $BC$.
Thus, our goal is to show that $HT$ is H-symmedian of $\triangle BHC$ which is equivalent to showing that $(S,T;B,C)=-1$.
Let $SL$ intersects $AB,AC$ at $P,Q$. Consider tangential quadrilateral $PQCB$, it is well known that $PC,QB,LD,EF$ are concurrent. So, $P,L’,C$ are collinear and $Q,L’,B$ are collinear.
By well known harmonic configuration, we conclude that $(S,T;B,C)=-1$, as desired.

Part 4 Solving sub problem 2
We’re going to prove that $HY$ bisects $\angle BHC$
Let the line through $H$ parallel to $EF$ intersects $BC$ at $R$.
First, we’ll show that our goal is equivalent to showing that $DJ \perp RI$
Suppose we’ve already shown that $DJ \perp RI$, we conclude that polar of point $R$ wrt. $(I)$ is $DJ$
We then apply the same trick as Part 3. Let $RX$ intersects $AB,AC$ at $R_1,R_2$, respectively.
Consider the tangential quadrilateral $R_1R_2CB$ and recall the well known harmonic configuration, we can conclude that $(R,Y;B,C)=-1$.
By trivial angle chasing, we know that $HR$ externally bisects $\angle BHC$. Thus, $HY$ internally bisects $\angle BHC$, we’re done.

Now, we focus on our goal proving that $DJ \perp RI$.
This is equivalent to $\angle IDJ =\angle IRD$. Let $H’,I’$ be the reflections of $H,I$ wrt. $BC$, respectively.
Observe that $\angle IDJ = \angle II’H = \angle HH’I = \angle AH’I$. So, our new goal is to show that $\angle IRD =\angle AH’I$
It is well known that $H’$ lies on $(ABC)$ and $A’=AI \cap (ABC)$ is the circumcenter of $\triangle BIC$.
Note that $A’$ is midpoint of arc $BC$ not containing $A$ and $H’$ lies on $(ABC)$, we can easily show that $A’H$ externally bisects $\angle BH’C$.
Since we already have that $RH$ externally bisects $\angle BHC$, we deduce that $RH’$ externally bisects $\angle BH’C$. Thus, $R,H’,A’$ are collinear.
Finally, consider an inversion $\phi$ wrt. $(BIC)$ centered at $A’$.
Let $AI$ intersects $BC$ at $Z$. We know that $\phi$ swaps $H’\leftrightarrow R$ and $Z \leftrightarrow A$.
Note that $$\angle IRD = \angle IRA’ - \angle H’RZ =\angle H’IA’ - \angle H’AZ = \angle H’IA’ - \angle H’AI = \angle AH’I $$Thus, we’re done. $\blacksquare$
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aidenkim119
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aidenkim119
#30 Apr 8, 2025, 11:44 AM
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That is very interestuung!!
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pingupignu
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pingupignu
#31 Apr 9, 2025, 3:33 PM
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Nice problem! Here's another solution using DDIT and trigonometry. Firstly we can delete $S$ and $T$ as follows:
Let $Z = BC \cap AX$ and $S' \in BC$ such that $S'T$ is the other tangent from $T$ to $(I)$. From Dual of Desargues Involution theorem we have the following reciprocal pairs on the pencil through $T$:
$$(T \infty_{BC}, TS'), (TB, TC), (TA, TD)$$Projecting it to $BC$ gives
$$(S', \infty_{BC}), (B, C), (Z, D)$$are reciprocal pairs of some involution on $BC$, so that $S'B \cdot S'C = S'Z \cdot S' D$. We need to show $S'H$ is tangent to $(BHC)$ $\iff$ $(BHC), (ZHD)$ are tangent $\iff$ $\frac{BZ}{ZC} \cdot \frac{BD}{BC} = (\frac{BH}{CH})^2$ $\iff$ $\frac{c}{b} \cdot \frac{\sin \angle BAX}{\sin \angle XAC} \cdot \frac{s-b}{s-c} = (\frac{\cos B}{\cos C})^2$.

From the solution from #29, if we let $Q = DX \cap EF$, then $AQ$ passes through the foot of internal angle bisector of $\angle BHC$ onto $BC$. Hence we deduce (letting $Y$ be said foot)
$$\frac{BY}{YC} = \frac{BH}{HC} \implies \frac{c}{b} \cdot \frac{\sin \angle BAQ}{\sin \angle QAC} = \frac{\cos B}{\cos C}$$
We can see that $$\frac{\sin \angle FAX}{\sin \angle EAX} = (\frac{FX}{EX})^2 = (\frac{FQ}{QE})^2 \cdot (\frac{ED}{DF})^2 = (\frac{\sin \angle BAQ}{\sin \angle QAC})^2 \cdot (\frac{\cos \frac{C}{2}}{\cos \frac{B}{2}})^2 = (\frac{b \cos B \cos \frac{C}{2}}{c \cos C \cos \frac{B}{2}})^2$$
And
$$\frac{c}{b} \cdot \frac{\sin \angle BAX}{\sin \angle XAC} \cdot \frac{s-b}{s-c} = \frac{c}{b} \cdot (\frac{b \cos B \cos \frac{C}{2}}{c \cos C \cos \frac{B}{2}})^2 \cdot \frac{BI}{CI} \cdot \frac{\sin \angle BID}{\sin \angle DIC}$$$$= (\frac{\cos B}{\cos C})^2 \cdot \frac{b}{c} \cdot \frac{\sin \frac{C}{2}}{\sin \frac{B}{2}} \cdot \frac{\cos \frac{B}{2}}{\cos \frac{C}{2}} \cdot (\frac{\cos \frac{C}{2}}{\cos \frac{B}{2}})^2 = \frac{b}{c} \cdot \frac{\sin C}{\sin B} \cdot (\frac{\cos B}{\cos C})^2 = (\frac{\cos B}{\cos C})^2,$$as desired. $\blacksquare$
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luutrongphuc
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luutrongphuc
#33 Apr 9, 2025, 11:23 PM
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Thank you everyone for your contribution
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ItzsleepyXD
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ItzsleepyXD
#34 Apr 10, 2025, 6:23 AM
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Maybe non DDIT solution but a lot of projective spam.
Define point - Redefine point

Lemma

Claim 1

Claim 2

Claim 3

Claim 4

Finished
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