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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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jlacosta
Apr 2, 2025
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A three-variable functional inequality on non-negative reals
Tintarn   10
N 7 minutes ago by Alidq
Source: Dutch TST 2024, 1.2
Find all functions $f:\mathbb{R}_{\ge 0} \to \mathbb{R}$ with
\[2x^3zf(z)+yf(y) \ge 3yz^2f(x)\]for all $x,y,z \in \mathbb{R}_{\ge 0}$.
10 replies
Tintarn
Jun 28, 2024
Alidq
7 minutes ago
J
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Y2K Game
MithsApprentice   13
N 15 minutes ago by zuat.e
Source: USAMO 1999 Problem 5
The Y2K Game is played on a $1 \times 2000$ grid as follows. Two players in turn write either an S or an O in an empty square. The first player who produces three consecutive boxes that spell SOS wins. If all boxes are filled without producing SOS then the game is a draw. Prove that the second player has a winning strategy.
13 replies
MithsApprentice
Oct 3, 2005
zuat.e
15 minutes ago
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Config geo with the Euler line
a_507_bc   11
N 21 minutes ago by falantrng
Source: BMO SL 2023 G4
Let $O$ and $H$ be the circumcenter and orthocenter of a scalene triangle $ABC$, respectively. Let $D$ be the intersection point of the lines $AH$ and $BC$. Suppose the line $OH$ meets the side $BC$ at $X$. Let $P$ and $Q$ be the second intersection points of the circumcircles of $\triangle BDH$ and $\triangle CDH$ with the circumcircle of $\triangle ABC$, respectively. Show that the four points $P, D, Q$ and $X$ lie on a circle.
11 replies
a_507_bc
May 3, 2024
falantrng
21 minutes ago
J
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Grasshoppers facing in four directions
Stuttgarden   2
N 31 minutes ago by biomathematics
Source: Spain MO 2025 P5
Let $S$ be a finite set of cells in a square grid. On each cell of $S$ we place a grasshopper. Each grasshopper can face up, down, left or right. A grasshopper arrangement is Asturian if, when each grasshopper moves one cell forward in the direction in which it faces, each cell of $S$ still contains one grasshopper.
[list]
[*] Prove that, for every set $S$, the number of Asturian arrangements is a perfect square.
[*] Compute the number of Asturian arrangements if $S$ is the following set:
2 replies
Stuttgarden
Mar 31, 2025
biomathematics
31 minutes ago
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Similarity through arc midpoint in right triangle
cjquines0   10
N Oct 22, 2024 by Tuguldur
Source: Iranian Geometry Olympiad 2016 Medium 4
Let $\omega$ be the circumcircle of right-angled triangle $ABC$ ($\angle A = 90^{\circ}$). The tangent to $\omega$ at point $A$ intersects the line $BC$ at point $P$. Suppose that $M$ is the midpoint of the minor arc $AB$, and $PM$ intersects $\omega$ for the second time in $Q$. The tangent to $\omega$ at point $Q$ intersects $AC$ at $K$. Prove that $\angle PKC = 90^{\circ}$.

Proposed by Davood Vakili
10 replies
cjquines0
May 26, 2017
Tuguldur
Oct 22, 2024
J
Similarity through arc midpoint in right triangle
G H J
Reveal topic tags
geometry
circumcircle
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G H BBookmark kLocked kLocked NReply
Source: Iranian Geometry Olympiad 2016 Medium 4
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cjquines0
510 posts
cjquines0
#1 May 26, 2017, 11:15 AM • 4 Y
Y by itslumi, tony88, Adventure10, Rounak_iitr
Let $\omega$ be the circumcircle of right-angled triangle $ABC$ ($\angle A = 90^{\circ}$). The tangent to $\omega$ at point $A$ intersects the line $BC$ at point $P$. Suppose that $M$ is the midpoint of the minor arc $AB$, and $PM$ intersects $\omega$ for the second time in $Q$. The tangent to $\omega$ at point $Q$ intersects $AC$ at $K$. Prove that $\angle PKC = 90^{\circ}$.

Proposed by Davood Vakili
This post has been edited 1 time. Last edited by cjquines0, May 26, 2017, 11:15 AM
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iliyash
600 posts
iliyash
#2 May 26, 2017, 11:44 AM • 2 Y
Y by Adventure10, Mango247
Here's the full problems and solution link:
http://igo-official.ir/wp-content/uploads/2016/12/igo_2016_-_problems__solutions_-_english.pdf
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aleksam
101 posts
aleksam
#3 May 26, 2017, 11:45 AM • 5 Y
Y by Pluto1708, GeoKing, Adventure10, Mango247, redred123
We will use the well-known fact that the tangent to the circumcircle of the triangle $ABC$ divides the side $BC$ in ratio $-\frac {AB^2}{AC^2}$. Before applying it, let note a Lemma.
Lemma:$\frac{AQ}{CQ}=\frac{AB}{AC}$.
Proof: This can be proven considering the inversion with center $P$ and radius $PA$, and as the circle of inversion is orthogonal to $\omega$, $(M, Q)$ and $(B,C)$ are excanging places. So, by applying the inverison distance formula, we get $\frac{AQ}{CQ}=\frac{AM\times BP}{BM\times AP}=\frac{BP}{AP}=\frac{AB}{AC}$.
Further, we easily compute the ratios $\frac{AK}{KC}=\frac{AQ^2}{CQ^2}=\frac{AB^2}{AC^2}=\frac{BP}{CP}$, and by Thales, we have the conclusion.
This post has been edited 2 times. Last edited by aleksam, May 26, 2017, 11:47 AM
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Euler365
142 posts
Euler365
#4 Sep 15, 2019, 8:48 AM • 2 Y
Y by tony88, Adventure10
I too have inversion solution but it is different.
Let $K'$ be on $AC$ such that $\angle PK'C = 90^{\circ}$. Let $N$ be midpoint of $BC$. We shall prove that $K'Q$ is tangent to $\omega$.
Perform an inversion with centre $P$ and radius $PA$.
Then $\omega$ gets mapped to $\omega$ itself. $K'$ goes to $PK' \cap AN$ say $L$ and $Q$ goes to $M$. So line $K'Q$ gets mapped to $\odot (PLM)$.
Now note that $MN$ is perpendicular bisector of $AB$ and hence $MN$ is perpendicular bisector of $PL$.
However circumcentre of $\odot (PLM)$ lies on perpendicular bisector of $PL$.
Also $N$ is circumcentre of $\omega$.
$\therefore$ The centres of $\omega , \odot (PLM)$ and their intersection pts. are collinear.
So $\omega$ and $\odot (PLM)$ are tangent to each other. $\therefore$ before inversion $K'Q$ and $\omega$ must have been tangent to each other as desired.
This post has been edited 4 times. Last edited by Euler365, Sep 15, 2019, 9:29 AM
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ShinyDitto
63 posts
ShinyDitto
#5 Aug 4, 2020, 5:24 PM • 5 Y
Y by Jafarly8097, itslumi, shalomrav, popdit, Professor33
I am not sure if this works for $AB>AC$ but I hope it does.

Let $AQ$ and $MC$ meet at $R$. Pascal on $AQQMCA$ shows that $R$, $K$ and $P$ are collinear. Pascal on $ABCMMQ$ shows that $PR$ is parallel to $AB$. Thus $PK$ is parallel to $AB$ and $\angle PKC=90^{\circ}$.
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JustKeepRunning
2958 posts
JustKeepRunning
#6 Jun 12, 2021, 9:49 PM
Y by
@above, how can you use pascal if the lines $AB$ and $MM$ do not even intersect? I have not learned about this use of pascal before, so could you explain?
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Mahdi_Mashayekhi
689 posts
Mahdi_Mashayekhi
#7 Dec 27, 2021, 7:41 AM
Y by
we have to prove PK || AB or PB/PC = KA/KC.
first note that PMA and PAQ are similar. PMB and PCQ are similar. PBA and PAC are similar.

PB/PC = (AB/AC)^2 and KA/KC = (QA/QC)^2
so we have to prove AB/AC = QA/QC.
AB/AC = PB/PA
PA/PQ = AM/AQ and PQ/PB = QC/BM so PB/PA = QA/QC.
we're Done.
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tony88
5 posts
tony88
#8 Apr 26, 2022, 8:47 AM
Y by
Euler365 wrote:
I too have inversion solution but it is different.

Thank you for your very good inversion solution!!
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lian_the_noob12
173 posts
lian_the_noob12
#9 Jul 22, 2023, 10:13 PM • 2 Y
Y by Rounak_iitr, LeYohan
Finally Solved With $\textbf{Pascal's Theorem}$ :)

$\color{red} \boxed{\textbf{SOLUTION}}$

Let, $AQ \cap MC \equiv X, AB \cap AC \equiv Y$

By $\textbf{Pascal's Theorem}$ on $Q,Q,A,A,C,M$ We get $QQ \cap AC \equiv K, QA \cap CM \equiv X, AA \cap MQ \equiv P$
So, $P,X,K$ are collinear.

We need to show $PK \equiv PX \parallel AB$
As $M$ is the midpoint of minor arc $AB, CM$ is the angle bisector of $\angle ACB$
Let, $\angle ACM=\angle BCM=\alpha \implies \angle ABC=90-2\alpha$
Now,
$$\angle PQX=\angle AQM=\angle ACM=\angle BCM=\angle PCX$$$\implies PQCX$ cyclic
Therefore,
$$\angle CXK=\angle PQC=\angle PQX + \angle XQC = \alpha + \angle ABC=\alpha + 90- 2\alpha=90-\alpha$$So,
$$\angle AYC=90- \alpha= \angle CXK=\angle YXK \implies AY \parallel PX \implies AB \parallel PX \implies AB \parallel PK \implies \angle PKC=\angle BAC=90 \blacksquare$$
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ACGNmath
327 posts
ACGNmath
#11 Dec 7, 2023, 4:46 PM
Y by
It suffices to show that $PK\parallel AB$. This can be done with 3 applications of Pascal's Theorem. Let $T=MA\cap QB$ and $X=QA\cap CM$.

Pascal's on $QQMACB$ yields $K, P, T$ are collinear.

Pascal's on $ABCMMQ$ yields $PX\parallel AB$ (since $MM$ intersects $AB$ at the point at infinity along that line)

Pascal's on $QQAACM$ yields $K,X,P$ are collinear.

Therefore, $K,P,T,X$ are collinear and these lie on a line parallel to $AB$, so we are done.
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Tuguldur
19 posts
Tuguldur
#12 Oct 22, 2024, 4:52 AM
Y by
It's just angle chasing
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