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k a June Highlights and 2025 AoPS Online Class Information
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Jun 2, 2025
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0 replies
jlacosta
Jun 2, 2025
0 replies
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Weirdly stated but cool collinearity
Rijul saini   3
N 6 minutes ago by YaoAOPS
Source: LMAO Revenge 2025 Day 1 Problem 2
Let Mary choose any non-degenerate $\triangle ABC$. Let $I$ be its incenter, $I_A$ be its $A$-excenter, $N_A$ be midpoint of arc $BAC$, $M$ is the midpoint of $BC$.

Let $H \neq I$ be the intersection of the line $N_AI$ with $(BIC)$, $F$ be the intersection of the angle bisector of $\angle BAC$ with the line $BC$.

Ana now draws the points $P \neq H$ ,the intersection of line $I_AH$ with $(HIN)$ and $Q$ ,the intersection of $(HIM)$ and $(AN_AI_A)$ such that $I_AH < I_AQ$. Ana wins if the points $A, P, Q$ are collinear. Who has a winning strategy?
3 replies
1 viewing
Rijul saini
Wednesday at 7:09 PM
YaoAOPS
6 minutes ago
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ISI UGB 2025 P8
SomeonecoolLovesMaths   7
N 10 minutes ago by Ilovesumona
Source: ISI UGB 2025 P8
Let $n \geq 2$ and let $a_1 \leq a_2 \leq \cdots \leq a_n$ be positive integers such that $\sum_{i=1}^{n} a_i = \prod_{i=1}^{n} a_i$. Prove that $\sum_{i=1}^{n} a_i \leq 2n$ and determine when equality holds.
7 replies
+1 w
SomeonecoolLovesMaths
May 11, 2025
Ilovesumona
10 minutes ago
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k colorings and triangles
Rijul saini   1
N 15 minutes ago by YaoAOPS
Source: LMAO Revenge 2025 Day 1 Problem 3
In the city of Timbuktu, there is an orphanage. It shelters children from the new mysterious disease that causes children to explode. There are m children in the orphanage. To try to cure this disease, a mad scientist named Myla has come up with an innovative cure. She ties every child to every other child using medicinal ropes. Every child is connected to every other child using one of $k$ different ropes. She then performs a experiment that causes $3$ children, each connected to each other with the same type of rope, to be cured. Two experiments are said to be of the same type, if each of the ropes connecting the children has the same medicine imbued in it. She then unties them and lets them go back home.

We let $f(n, k)$ be the minimum m such that Myla can perform at least $n$ experiments of the same type. Prove that:

$i.$ For every $k \in \mathbb N$ there exists a $N_k \in N$ and $a_k, b_k \in \mathbb Z$ such that for all $n > N_k$, \[f(n, k) = a_kn + b_k.\]
$ii.$ Find the value of $a_k$ for every $k \in \mathbb N$.
1 reply
1 viewing
Rijul saini
Wednesday at 7:11 PM
YaoAOPS
15 minutes ago
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A beautiful Lemoine point problem
phonghatemath   2
N 24 minutes ago by HyperDunteR
Source: my teacher
Given triangle $ABC$ inscribed in a circle with center $O$. $P$ is any point not on (O). $AP, BP, CP$ intersect $(O)$ at $A', B', C'$. Let $L, L'$ be the Lemoine points of triangle $ABC, A'B'C'$ respectively. Prove that $P, L, L'$ are collinear.
2 replies
phonghatemath
3 hours ago
HyperDunteR
24 minutes ago
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No more topics!
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Equal radius
FabrizioFelen   9
N Mar 30, 2025 by ihategeo_1969
Source: Centroamerican Olympiad 2016, Problem 6
Let $\triangle ABC$ be triangle with incenter $I$ and circumcircle $\Gamma$. Let $M=BI\cap \Gamma$ and $N=CI\cap \Gamma$, the line parallel to $MN$ through $I$ cuts $AB$, $AC$ in $P$ and $Q$. Prove that the circumradius of $\odot (BNP)$ and $\odot (CMQ)$ are equal.
9 replies
FabrizioFelen
Jun 20, 2016
ihategeo_1969
Mar 30, 2025
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Equal radius
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Reveal topic tags
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Source: Centroamerican Olympiad 2016, Problem 6
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FabrizioFelen
241 posts
FabrizioFelen
#1 Jun 20, 2016, 7:09 PM • 1 Y
Y by Adventure10
Let $\triangle ABC$ be triangle with incenter $I$ and circumcircle $\Gamma$. Let $M=BI\cap \Gamma$ and $N=CI\cap \Gamma$, the line parallel to $MN$ through $I$ cuts $AB$, $AC$ in $P$ and $Q$. Prove that the circumradius of $\odot (BNP)$ and $\odot (CMQ)$ are equal.
This post has been edited 1 time. Last edited by FabrizioFelen, Jun 20, 2016, 7:10 PM
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Math_CYCR
431 posts
Math_CYCR
#2 Jun 20, 2016, 8:03 PM • 2 Y
Y by Adventure10, Mango247
Let $R_1$ be the radius of $\triangle MQC$. Let $R_2$ be the radius of $\triangle NPB$.

Using the fact that $NB=NI=NA$, $MC=MI=MA$, and since $NM \parallel PQ$, we get:

$\angle PIB= \angle MIQ = \angle IMN= \angle NCA= \angle NAB= \angle NBA$

$\angle QIC= \angle NIP= \angle INM= \angle MBA= \angle MAC= \angle MCA$

Therefore, by trig ceva in $\triangle NBI$ and $\triangle MIC$, we get:

$\frac{ \sin \angle BNP}{ \sin \angle PNI} = \frac{ \sin \angle IMQ}{ \sin \angle QMC}$

By Two Equal Angles Lemma we get $\angle BNP= \angle IMQ$

We now easily see that $\angle ANP+ \angle AMQ= 180$. And $AP= AQ$.

By law of sines in $\triangle ANP$ and $\triangle AMQ$, we get:

$\frac{NP}{ \sin \angle NAP} = \frac{AP}{ \sin \angle ANP} = \frac{AQ}{ \sin \angle AMQ} = \frac{MQ}{ \sin \angle MAQ}$.

By law of sines in $\triangle MQC$ and $\triangle NPB$ we get:

$2R_1= \frac{MQ}{ \sin \angle MCQ} = \frac{NP}{ \sin \angle NBP} = 2R_2$

$\Longrightarrow R_1=R_2$

Done!
This post has been edited 1 time. Last edited by Math_CYCR, Sep 25, 2016, 2:30 PM
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djmathman
7939 posts
djmathman
#3 Jun 22, 2016, 12:51 AM • 2 Y
Y by Adventure10, Mango247
Let $T = AI\cap\odot(ABC)$. It's well known that $AT\perp MN$, so $AI\perp PQ$.

Recall that by Fact 5 $BN = NI$ and $CM = MI$; combined with the fact that $\angle BNC = \angle BMC$ we get that $\triangle BNI\sim\triangle ICM$. Furthermore, remark that \[\angle API = 90^\circ-\tfrac12A = 180^\circ - \left(90^\circ+\dfrac12\angle A\right) = 180^\circ - \angle BIC = \angle NIB.\]Thus $\angle PBI = \angle NIP$, so $\angle NBP=\angle PIB$. Similar reasoning works for the other triangle $\triangle CMI$, so in fact $P$ and $Q$ are corresponding points in $\triangle BNI$ and $\triangle IMC$ respectively.

As such, \[\dfrac{R_{\odot(MQC)}}{R_{\odot(BPN)}} = \left(\dfrac{R_{\odot(MQC)}}{R_{\odot(MQI)}}\right)\left(\dfrac{CM}{CN}\right) = \left(\dfrac{\sin\angle MCA}{\sin\angle ABN}\right)\left(\dfrac{MA}{AN}\right) = 1,\]where the last equality is from Extended Law of Sines. Done. $\blacksquare$
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Packito
37 posts
Packito
#4 Jun 22, 2016, 2:23 AM • 2 Y
Y by edfearay123, Adventure10
1) $\angle NBP=\angle NAP$ And since $\triangle BNP$ shares $NP$ with $\triangle NPA$, they have both the same circumradius. Analogously $\triangle CQM$ and $\triangle AQM$ have the same circumradius.
So its enough to prove $\triangle AQM$ and $\triangle NPA$ have the same circumradius.

2) It´s known that $NI=NA$ and $MI=MA \Rightarrow MN\perp AI\Rightarrow PQ\perp AI$
Since $AI$ its the angle bisector of $\angle BAC\Rightarrow AP=AQ$ So its enough to prove that $\angle ANP=180-\angle AMQ \Leftrightarrow NP\cap MQ$ is on $\Gamma$

3) Consider $NP\cap \Gamma=D$ and $MD\cap AC=Q'$
From Pascal we get $AB\cap ND=P$ , $BM\cap CN=I$ and $AC\cap MD=Q'$ are collinear but $P, I, Q$ are collinear $\Rightarrow Q'=Q$
$Q.E.D$
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doxuanlong15052000
269 posts
doxuanlong15052000
#5 Jun 22, 2016, 3:44 AM • 5 Y
Y by phantranhuongth, Ghost_rider, Adventure10, Mango247, AlexCenteno2007
My solution:
Let $NP$ cut $MQ$ at $R$. From Pascal's theorem, we have $R$ lies on $(O)$. We have $\angle RNB=\angle RMB$ and $\angle NBP=\angle NMI=\angle MIQ$$\Longrightarrow $$\triangle NPB\sim \triangle MQI$$\Longrightarrow $$\frac {NP}{MQ}=\frac {NB}{MI}=\frac {NI}{MI}=\frac {sin\frac {\angle C}{2}}{sin\frac {\angle B}{2}}$ $\Longrightarrow $the circumradius of $\odot (BNP)$ and $\odot (CMQ)$ are equal
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PROF65
2016 posts
PROF65
#6 Jun 22, 2016, 2:43 PM • 2 Y
Y by Adventure10, Mango247
@doxuanlong1505 apart from some typos that you can rectify, nice solution.
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Ghost_rider
35 posts
Ghost_rider
#7 Jun 25, 2016, 4:19 AM • 2 Y
Y by Adventure10, Mango247
Let $\odot (CMQ)$ $\cap$ $NC$ = $D$. $\angle NBP$ = $\angle$ $ICA$ . It´s easy to see: $AP$ = $AQ$ $\longrightarrow$ $PI$ = $IQ$. If prove $NP$ = $QD$ the circumradius of $\odot (BNP)$ and $\odot (CMQ)$ are equal. Let $NP$ $\cap$ $(O)$ = $E$. It´s easy to see $IPBE$ is cyclic. By angle chasing $IQCE$ is cyclic $\longrightarrow$ $E$, $Q$ and $M$ are collinear. Then: $\angle$ $PNI$ = $\angle$ $IDQ$. $\triangle$ $NPI$ $\cong$ $\triangle$ $IDQ$ $\longrightarrow$ $NP$ = $QD$, done.
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Ilove_mathematics
188 posts
Ilove_mathematics
#8 Nov 4, 2018, 4:45 AM • 2 Y
Y by Adventure10, Mango247
Math_CYCR wrote:
Let $R_1$ be the radius of $\triangle MQC$. Let $R_2$ be the radius of $\triangle NPB$.

Using the fact that $NB=NI=NA$, $MC=MI=MA$, and since $NM \parallel PQ$, we get:

$\angle PIB= \angle MIQ = \angle IMN= \angle NCA= \angle NAB= \angle NBA$

$\angle QIC= \angle NIP= \angle INM= \angle MBA= \angle MAC= \angle MCA$

Therefore, by trig ceva in $\triangle NBI$ and $\triangle MIC$, we get:

$\frac{ \sin \angle BNP}{ \sin \angle PNI} = \frac{ \sin \angle IMQ}{ \sin \angle QMC}$

By Two Equal Angles Lemma we get $\angle BNP= \angle IMQ$

We now easily see that $\angle ANP+ \angle AMQ= 180$. And $AP= AQ$.

By law of sines in $\triangle ANP$ and $\triangle AMQ$, we get:

$\frac{NP}{ \sin \angle NAP} = \frac{AP}{ \sin \angle ANP} = \frac{AQ}{ \sin \angle AMQ} = \frac{MQ}{ \sin \angle MAQ}$.

By law of sines in $\triangle MQC$ and $\triangle NPB$ we get:

$2R_1= \frac{MQ}{ \sin \angle MCQ} = \frac{NP}{ \sin \angle NBP} = 2R_2$

$\Longrightarrow R_1=R_2$

Done!

OMG MY FRIEND, I THOUGHT SAME THING! My solution is identical, so it would be useless post my solution...
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jbaca
225 posts
jbaca
#9 Nov 18, 2018, 4:53 PM • 2 Y
Y by Adventure10, AlexCenteno2007
It's easy to infer that $AI$ bisects $\overline{PQ}$. Let $E$ be the second intersection point of $BI$ and $(CQM$) and $D$ the second intersection of $CI$ and $(CQM)$. Note that $$\angle IEQ=\angle MCA=\angle IBP\therefore PB\parallel EQ$$so $BI=IE$ and hence $BPEQ$ is a parallelogram, thus $EQ=PB$. Observe that $$\angle IED=\angle MCI=\angle NBI\therefore NB\parallel ED$$therefore $\frac{IN}{ID}=\frac{BI}{IE}=1$ which implies $NI=ID$, then $NB=ED$. Finally, since $DN$ and $PQ$ bisect each other at $I$, so $NQDP$ is a parallelogram with $NP=QD$, then $\bigtriangleup NPB\cong \bigtriangleup DQE$, which gives the required result.
This post has been edited 3 times. Last edited by jbaca, Jul 16, 2022, 4:51 AM
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ihategeo_1969
247 posts
ihategeo_1969
#10 Mar 30, 2025, 8:42 PM
Y by
Obviously $\overline{AI} \perp \overline{PQ}$. Let $T=\overline{MQ} \cap \overline{NP} \cap (ABC)$ be the $A$-Mixtilinear intouch point by the Shooting Lemma. Now since $\measuredangle NBP=\measuredangle NBA=\measuredangle BAN=\measuredangle PAN$, the corresponding $\widehat{PN}$ arcs are equal in measure so $R(NBP)=R(NAP)$. Similarly $R(CQM)=R(AQM)$. Let $K=(AQM) \cap (NAP)$ and $\measuredangle AKQ=\measuredangle AMT=\measuredangle ANT=\measuredangle AKP$ and so $K \in \overline{PQ}$. To finish just see that $\measuredangle APK=\measuredangle KQA$ and again the corresponding $\widehat{AK}$ arcs are equal in measure so $R(ANP)=R(AMQ)$ and done.
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