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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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Goofy FE problem
Bread10   5
N 2 minutes ago by Irreplaceable
Source: Courtesy of ChatGPT
Find all functions $f : \mathbb{R} \rightarrow \mathbb{R}$ such that $f(x+f(y)) = y+f(x)$ over $\mathbb{R}$.
5 replies
Bread10
2 hours ago
Irreplaceable
2 minutes ago
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Serbian selection contest for the BMO 2025 - P6
OgnjenTesic   0
an hour ago
Let $ABCD$ be a tangential and cyclic quadrilateral. Let $S$ be the intersection point of diagonals $AC$ and $BD$ of the quadrilateral. Let $I$, $I_1$, and $I_2$ be the incenters of quadrilateral $ABCD$ and triangles $ACD$ and $BCS$, respectively. Let the ray $II_2$ intersect the circumcircle of quadrilateral $ABCD$ at point $E$. Prove that the points $D$, $E$, $I_1$, and $I_2$ are collinear or concyclic.

Proposed by Teodor von Burg
0 replies
OgnjenTesic
an hour ago
0 replies
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Serbian selection contest for the BMO 2025 - P5
OgnjenTesic   0
an hour ago
In Mexico, there live $n$ Mexicans, some of whom know each other. They decided to play a game. On the first day, each Mexican wrote a non-negative integer on their forehead. On each following day, they changed their number according to the following rule: On day $i+1$, each Mexican writes on their forehead the smallest non-negative integer that did not appear on the forehead of any of their acquaintances on day $i$. It is known that on some day every Mexican wrote the same number as on the previous day, after which they decided to stop the game. Determine the maximum number of days this game could have lasted.

Proposed by Pavle Martinović
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OgnjenTesic
an hour ago
0 replies
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Serbian selection contest for the BMO 2025 - P4
OgnjenTesic   0
an hour ago
Let $a_1, a_2, \ldots, a_8$ be real numbers. Prove that
$$\sum_{i=1}^{8} \left( a_i^2 + a_i a_{i+2} \right) \geq \sum_{i=1}^{8} \left( a_i a_{i+1} + a_i a_{i+3} \right),$$where the indices are taken modulo 8, i.e., $a_9 = a_1$, $a_{10} = a_2$, and $a_{11} = a_3$. In which cases does equality hold?

Proposed by Vukašin Pantelić and Andrija Živadinović
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OgnjenTesic
an hour ago
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cyclic quadrilateral
AndrewTom   9
N Apr 13, 2016 by buzzychaoz
Source: BrMO 2 2016
Let $ABCD$ be a cyclic quadrilateral. The diagonals $AC$ and $BD$ meet at $P$, and $DA$ and $CB$ produced meet at $Q$. The midpoint of $AB$ is $E$. Prove that if $PQ$ is perpendicular to $AC$, then $PE$ is perpendicular to $BC$.

See here: https://bmos.ukmt.org.uk/home/bmo2-2016.pdf
9 replies
AndrewTom
Jan 29, 2016
buzzychaoz
Apr 13, 2016
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cyclic quadrilateral
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Reveal topic tags
geometry
cyclic quadrilateral
BritishMathematicalOlympiad
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Source: BrMO 2 2016
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AndrewTom
12750 posts
AndrewTom
#1 Jan 29, 2016, 8:26 AM • 2 Y
Y by Adventure10, Mango247
Let $ABCD$ be a cyclic quadrilateral. The diagonals $AC$ and $BD$ meet at $P$, and $DA$ and $CB$ produced meet at $Q$. The midpoint of $AB$ is $E$. Prove that if $PQ$ is perpendicular to $AC$, then $PE$ is perpendicular to $BC$.

See here: https://bmos.ukmt.org.uk/home/bmo2-2016.pdf
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Complex2Liu
83 posts
Complex2Liu
#2 Jan 29, 2016, 10:47 AM • 2 Y
Y by AndrewTom, Adventure10
Very nice problem! here is my solution. :)
Let $AB\cap CD\equiv K$, $OP\cap QK\equiv L$, $PE\cap QC\equiv T$ and $AC\cap QK\equiv S$. Define $\Gamma_1\equiv \odot(ABCD)$ and $\Gamma_2\equiv \odot(OLK)$.

Lemma 1. $OP$ is perpendicular to $QK$.
Proof of the lemma. By Brokard's Theorem we have the polar of $Q,K$ both passes through $P$, and the result immediately follows. Since $OE\perp AB$ we can deduce that $E\in \Gamma_2$.

Lemma 2. $P$ lies on the radical axis of $\Gamma_1$ and $\Gamma_2$.
Proof of the lemma. Note that $(A,C;P,S)=-1$ and $OL\perp QK$, which implies that $\angle ALO=\angle CLO$, Since $OA=OC$, so $L,A,O,C$ are concyclic $\implies PA\cdot PC=PL\cdot PO$.

Lemma 3. $L$ is the Miquel point of complete quadrilateral $ABCD$.
Proof of the lemma. In fact the Miquel point of complete quadrilateral $ABCD$ lies on $\overline{QK}$ if and only if $A,B,C,D$ are concyclic. It's easy to verify by angle-chasing.

Back to the main problem, by lemma 3 we get \[ A,L,Q,B \quad \text{are concyclic} \ \ \ (1)\]and $L,K,D,A$ are concyclic as well. Which amounts to $QL\cdot QK=QA\cdot QD=QB\cdot QC\implies P$ lies on the radical axis of $\Gamma_1$ and $\Gamma_2$. Thus $QP\perp OK \implies OK\parallel AC$. At last just angle-chasing!

We have $\angle BAC=\angle EKO=\widehat{EO}=\angle ELP \implies L,A,P,E$ are concyclic $\implies \angle TEB=\angle AEP=\angle PLA$. From $(1)$ we get $\angle KLA=\angle QBE$, hence $\angle TEB+\angle TBE=\angle PLA+\angle ALK=90^\circ$, as desired.

[asy] /* Geogebra to Asymptote conversion, documentation at artofproblemsolving.com/Wiki, go to User:Azjps/geogebra */ import graph; size(10.8cm); real labelscalefactor = 0.5; /* changes label-to-point distance */ pen dps = linewidth(0.7) + fontsize(10); defaultpen(dps); /* default pen style */ pen dotstyle = black; /* point style */ real xmin = -7., xmax = -1., ymin = -0.5, ymax = 5.; /* image dimensions */ pen qqwuqq = rgb(0.,0.39215686274509803,0.); pen ffqqff = rgb(1.,0.,1.); /* draw figures */ draw(circle((-3.630340855945256,1.2854794023018563), 1.3422638712342856), linetype("2 2") + red); draw((-2.2895930863161498,1.34925806844838)--(-4.6390163108481905,2.1710561221275353)); draw((-3.3760718699651213,4.031502565581776)--(-4.831975245369217,1.883599034294118)); draw((-4.831975245369217,1.883599034294118)--(-2.6231631477288944,2.1727591575610923)); draw((-4.6390163108481905,2.1710561221275353)--(-2.6231631477288944,2.1727591575610923)); draw((-2.2895930863161498,1.34925806844838)--(-4.831975245369217,1.883599034294118)); draw((-3.3760718699651213,4.031502565581776)--(-2.2895930863161498,1.34925806844838)); draw((-3.3760718699651213,4.031502565581776)--(-4.093568269703736,1.9802654063828646), qqwuqq); draw((-6.193441300789991,2.1697429109844273)--(-4.831975245369217,1.883599034294118)); draw((-6.193441300789991,2.1697429109844273)--(-4.6390163108481905,2.1710561221275353)); draw((-6.193441300789991,2.1697429109844273)--(-3.3760718699651213,4.031502565581776)); draw((-4.823474249709048,3.075037529405646)--(-3.630340855945256,1.2854794023018563)); draw((-3.630340855945256,1.2854794023018563)--(-3.6310897292885427,2.1719076398443136)); draw((-3.630340855945256,1.2854794023018563)--(-6.193441300789991,2.1697429109844273)); draw((-4.823474249709048,3.075037529405646)--(-4.6390163108481905,2.1710561221275353)); draw((-3.630340855945256,1.2854794023018563)--(-2.2895930863161498,1.34925806844838)); draw(circle((-4.913703296061345,1.7223583152318123), 1.3556851910615484), linetype("2 2") + red); draw((-2.767733042548745,2.5296660853975985)--(-4.823474249709048,3.075037529405646)); draw((-4.823474249709048,3.075037529405646)--(-2.6231631477288944,2.1727591575610923)); draw((-4.823474249709048,3.075037529405646)--(-3.6310897292885427,2.1719076398443136)); draw(circle((-4.132057055324496,2.745311536163152), 0.7660136861116484), blue); draw((-4.093568269703736,1.9802654063828646)--(-2.767733042548745,2.5296660853975985)); draw((-5.654128020523374,2.5261291539113877)--(-4.6390163108481905,2.1710561221275353), linetype("2 2")); draw(circle((-3.0474492062947496,2.966626406904497), 1.7793307523663835), linetype("0 3 4 3") + ffqqff); /* dots and labels */ dot((-2.6231631477288944,2.1727591575610923),linewidth(3.pt) + dotstyle); label("$B$", (-2.562235718544708,2.165444675871056), NE * labelscalefactor); dot((-2.2895930863161498,1.34925806844838),linewidth(3.pt) + dotstyle); label("$C$", (-2.1614127020753733,1.2260157310210618), NE * labelscalefactor); dot((-3.3760718699651213,4.031502565581776),linewidth(3.pt) + dotstyle); label("$Q$", (-3.4014589092773777,4.094405442629711), NE * labelscalefactor); dot((-4.6390163108481905,2.1710561221275353),linewidth(3.pt) + dotstyle); label("$A$", (-4.679082274273383,1.9399817291070574), NE * labelscalefactor); dot((-4.093568269703736,1.9802654063828646),linewidth(3.pt) + dotstyle); label("$P$", (-4.228156380745381,1.8021988171957248), NE * labelscalefactor); dot((-4.831975245369217,1.883599034294118),linewidth(3.pt) + dotstyle); label("$D$", (-4.829390905449383,1.7145187823430588), NE * labelscalefactor); dot((-3.6310897292885427,2.1719076398443136),linewidth(3.pt) + dotstyle); label("$E$", (-3.651973294570712,2.265650429988389), NE * labelscalefactor); dot((-3.630340855945256,1.2854794023018563),linewidth(3.pt) + dotstyle); label("$O$", (-3.626921856041379,1.0757070998450626), NE * labelscalefactor); dot((-2.767733042548745,2.5296660853975985),linewidth(3.pt) + dotstyle); label("$T$", (-2.687492911191375,2.541216253811054), NE * labelscalefactor); dot((-6.193441300789991,2.1697429109844273),linewidth(3.pt) + dotstyle); label("$K$", (-6.420157252062056,2.102816079547723), NE * labelscalefactor); dot((-4.823474249709048,3.075037529405646),linewidth(3.pt) + dotstyle); label("$L$", (-4.979699536625384,3.205079374838383), NE * labelscalefactor); dot((-5.654128020523374,2.5261291539113877),linewidth(3.pt) + dotstyle); label("$S$", (-5.75629413103472,2.5662676923403867), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]
This post has been edited 1 time. Last edited by Complex2Liu, Jan 29, 2016, 11:03 AM
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TelvCohl
2312 posts
TelvCohl
#3 Jan 29, 2016, 12:51 PM • 9 Y
Y by rkm0959, Complex2Liu, AndrewTom, Re1gnover, HoseynHeydari, Med_Sqrt, enhanced, Adventure10, Mango247
Let $ X, $ $ Y $ be the midpoint of $ AQ, $ $ AP $, respectively. Since $ \measuredangle PXE $ $ = $ $ \measuredangle (PX,QP) $ $ + $ $ \measuredangle (QP, BC) $ $ = $ $ \measuredangle PQC $ $ - $ $ \measuredangle AQP $ $ = $ $ \measuredangle PAQ $ $ - $ $ \measuredangle QCP $ $ = $ $ \measuredangle CAD $ $ - $ $ \measuredangle BDA $ $ = $ $ \measuredangle CPB $ $ = $ $ \measuredangle PYE $, so $ E, $ $ P, $ $ X, $ $ Y $ are concyclic $ \Longrightarrow $ $ \measuredangle XEP $ $ = $ $ 90^{\circ} $, hence we conclude that $ PE $ is perpendicular to $ BC $.
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FabrizioFelen
241 posts
FabrizioFelen
#4 Jan 29, 2016, 8:02 PM • 3 Y
Y by AndrewTom, songssari, Adventure10
My solution:
Let $E'$ be a point in $AB$ such that $PE'\perp BC$ and let $X=\odot (PAE')\cap PQ$ $\Longrightarrow$ by angle-chasing we get $\triangle XQA\sim \triangle E'PB$ and by law of sines in $\triangle BPC$ and $\triangle QAC$ we get $\frac{BP}{PC}=\frac{QA}{QC}$. Also that $\triangle XAE'\sim \triangle QCP$ $\Longrightarrow$ $\frac{XA}{AE'}=\frac{QC}{CP}$ but $\frac{XA}{E'B}=\frac{QA}{BP}$ since $\triangle XQA\sim \triangle E'PB$ $\Longrightarrow$ $\frac{XA}{AE'}=\frac{QC}{CP}=\frac{QA}{BP}=\frac{XA}{E'B}$ $\Longrightarrow$ $AE'=E'B$ $\Longrightarrow$ $E'=E$ $\Longrightarrow$ $PE\perp BC$... :no:
This post has been edited 1 time. Last edited by FabrizioFelen, Jan 31, 2016, 9:13 PM
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rkm0959
1721 posts
rkm0959
#5 Jan 30, 2016, 2:25 AM • 4 Y
Y by AndrewTom, songssari, Adventure10, Mango247
Vectors. It suffices to show that $\vec{PE} \cdot \vec{BC}=0$. Using $\vec{PE}=\frac{1}{2}(\vec{PA}+\vec{PB})$, we get $$\vec{PE} \cdot \vec{BC} = \frac{1}{2}(\vec{PA}+\vec{PB})\cdot \vec{BC}$$$$= -\frac{1}{2} \cdot PA \cdot BC \cdot \cos \angle BCA + \frac{1}{2}\cdot PB \cdot BC \cdot \cos \angle QBP$$$$= \frac{1}{2} \cdot BC \cdot ( -PA \cos \angle BCA + PB \cos \angle QBP)$$
Note that $\angle QAP = 180-\angle PAD = 180-\angle PBC = \angle QBP$, so we have $$\frac{1}{2} \cdot BC \cdot ( -PA \cos \angle BCA + PB \cos \angle QBP)$$$$= -\frac{1}{2}BC \cdot (PA \cdot \frac{PC}{QC} - PB \cdot \cos \angle QAP)$$$$=-\frac{1}{2}BC \cdot PA \cdot (\frac{PC}{QC}-\frac{BP}{QA})$$
It now suffices to show that $\frac{PC}{QC}=\frac{BP}{QA}$, which is true since $$\frac{BP}{QA}=\frac{BP}{PQ} \cdot \frac{PQ}{QA} = \frac{\sin \angle PQC}{\sin \angle PBC} \cdot \sin \angle QAP = \sin \angle PQC = \frac{PC}{QC} \text{ }\blacksquare$$
This post has been edited 4 times. Last edited by rkm0959, Jan 30, 2016, 10:03 AM
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AndrewTom
12750 posts
AndrewTom
#6 Jan 30, 2016, 9:08 PM • 1 Y
Y by Adventure10
Thanks Complex2Liu, TelvCohl, FabrizioFelen and rkm0959 for your interesting solutions.

Are there other ways of doing this question?
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mitevski169
2 posts
mitevski169
#7 Jan 31, 2016, 9:30 PM • 3 Y
Y by AndrewTom, Adventure10, Mango247
There is actually,
Let $PE\cap BC$ = $F$.
Miquel's point $M$ is the second intersection of circumcircles of $\triangle BPC$ and $\triangle APD$.
Then $Q$ is radical centar of circumcircles of $BPC$ , $APD$ and $ABCD$ $ \Longrightarrow $ $Q$, $P$ and $M$ are collinear.
Because of $ \measuredangle CPM $ = $ 90^{\circ} $ $ \Longrightarrow $ $ \measuredangle CBM $ = $ 90^{\circ} $.
Let $G$ be midpoint of $AM$ and ray $GP$ $\cap$ $QC$ = $F_1$.
By Brahmagupta Theorem on cyclic $AQCM$ $\Longrightarrow $ $GF_1\perp QC$ $ \Longrightarrow $ $GF_1\parallel BM$$ (1)$.
Because $EG$ is midsegment of $\triangle ABM$ $ \Longrightarrow $ $EG\parallel BM$$(2)$. By $(1)$ and $(2)$ $ \Longrightarrow $ $P$, $E$ and $F_1$ are collinear.
This means $F_1$ = $F$ $ \Longrightarrow $ $PF \perp BC$.
$Q.E.D$.
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AndrewTom
12750 posts
AndrewTom
#8 Feb 3, 2016, 10:08 PM • 2 Y
Y by Adventure10, Mango247
Thanks mitevski169: your solution looks amazing. Unfortunately, I don't understand lines 2 and 3, nor do I follow the line on Brahmagupta's theorem.
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mitevski169
2 posts
mitevski169
#9 Feb 7, 2016, 2:47 PM • 1 Y
Y by Adventure10
Ok, a clarification without radical axes mentioning.
Let $BCMP$ be cyclic and $Q$, $P$, $M$ are collinear.
By power of a point $QP\cdot QM$ = $QB\cdot QC$. Also we have $QB\cdot QC$ = $QA\cdot QD$.
So $QA\cdot QD$ = $QP\cdot QM$ $ \Longrightarrow $ $APMD$ is cyclic. So $M$ is miquel's point on $ABCD$.
And for Brahmagupta see https://en.wikipedia.org/wiki/Brahmagupta_theorem.
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buzzychaoz
178 posts
buzzychaoz
#10 Apr 13, 2016, 2:31 PM • 3 Y
Y by chenguk2001, oolite, Adventure10
Let the reflection of $A$ across $P$ be $F$, then $PE\parallel FB$. Since $\angle PAD=\angle PBC$ $\implies \angle QFP=\angle QAP=\angle QBP$ $\implies F,P,Q,B$ cyclic$\implies \angle FBC=90^{\circ}$, hence $PE\perp BC$.
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