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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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Geometry
IstekOlympiadTeam   27
N a minute ago by SimplisticFormulas
Source: All Russian Grade 9 Day 2 P 3
An acute-angled $ABC \ (AB<AC)$ is inscribed into a circle $\omega$. Let $M$ be the centroid of $ABC$, and let $AH$ be an altitude of this triangle. A ray $MH$ meets $\omega$ at $A'$. Prove that the circumcircle of the triangle $A'HB$ is tangent to $AB$. (A.I. Golovanov , A.Yakubov)
27 replies
IstekOlympiadTeam
Dec 12, 2015
SimplisticFormulas
a minute ago
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Incenter and concurrency
jenishmalla   3
N 11 minutes ago by Captainscrubz
Source: 2025 Nepal ptst p3 of 4
Let the incircle of $\triangle ABC$ touch sides $BC$, $CA$, and $AB$ at points $D$, $E$, and $F$, respectively. Let $D'$ be the diametrically opposite point of $D$ with respect to the incircle. Let lines $AD'$ and $AD$ intersect the incircle again at $X$ and $Y$, respectively. Prove that the lines $DX$, $D'Y$, and $EF$ are concurrent, i.e., the lines intersect at the same point.

(Kritesh Dhakal, Nepal)
3 replies
jenishmalla
Mar 15, 2025
Captainscrubz
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Number Theory Chain!
JetFire008   1
N 17 minutes ago by whwlqkd
I will post a question and someone has to answer it. Then they have to post a question and someone else will answer it and so on. We can only post questions related to Number Theory and each problem should be more difficult than the previous. Let's start!

Question 1
1 reply
JetFire008
23 minutes ago
whwlqkd
17 minutes ago
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Collinearity with orthocenter
math163   6
N 29 minutes ago by Nari_Tom
Source: Baltic Way 2017 Problem 11
Let $H$ and $I$ be the orthocenter and incenter, respectively, of an acute-angled triangle $ABC$. The circumcircle of the triangle $BCI$ intersects the segment $AB$ at the point $P$ different from $B$. Let $K$ be the projection of $H$ onto $AI$ and $Q$ the reflection of $P$ in $K$. Show that $B$, $H$ and $Q$ are collinear.

Proposed by Mads Christensen, Denmark
6 replies
math163
Nov 11, 2017
Nari_Tom
29 minutes ago
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Intersection of a cevian with the incircle
djb86   24
N Mar 30, 2025 by Ilikeminecraft
Source: South African MO 2005 Q4
The inscribed circle of triangle $ABC$ touches the sides $BC$, $CA$ and $AB$ at $D$, $E$ and $F$ respectively. Let $Q$ denote the other point of intersection of $AD$ and the inscribed circle. Prove that $EQ$ extended passes through the midpoint of $AF$ if and only if $AC = BC$.
24 replies
djb86
May 27, 2012
Ilikeminecraft
Mar 30, 2025
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Intersection of a cevian with the incircle
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Source: South African MO 2005 Q4
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djb86
445 posts
djb86
#1 May 27, 2012, 9:23 AM • 6 Y
Y by megarnie, mathematicsy, jhu08, centslordm, Adventure10, Mango247
The inscribed circle of triangle $ABC$ touches the sides $BC$, $CA$ and $AB$ at $D$, $E$ and $F$ respectively. Let $Q$ denote the other point of intersection of $AD$ and the inscribed circle. Prove that $EQ$ extended passes through the midpoint of $AF$ if and only if $AC = BC$.
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v_Enhance
6871 posts
v_Enhance
#2 May 27, 2012, 6:14 PM • 7 Y
Y by HamstPan38825, jhu08, megarnie, centslordm, Adventure10, Mango247, Sedro
Solution
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r1234
462 posts
r1234
#3 May 28, 2012, 3:41 AM • 4 Y
Y by jhu08, megarnie, centslordm, Adventure10
Let $EF\cap AD=X$.Then $E(A,Q,X,D)=-1$. If $EQ$ passes through the midpoint of $AF$, then $E(A,Q,X,\infty)=-1\Longrightarrow ED\parallel AB\Longrightarrow AC=BC$.
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algebra_star1234
2467 posts
algebra_star1234
#4 Jun 13, 2020, 11:34 PM • 2 Y
Y by megarnie, centslordm
let $M = AF \cap EQ$ and $P = ED \cap AB$. We know $EDQF$ is harmonic, so $-1 = (EF;QD) \stackrel E = (AF;MP)$. If $M$ is the midpoint, then $(AF;M \infty) = -1$, so $ED || AB$, from which it is clear that $AC = BC$. If $AC = BC$, then $DE || AB$, and we have $(AF;M\infty)=-1$, so $M$ is the midpoint of $AF$. Therefore, we are done.
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Stormersyle
2785 posts
Stormersyle
#5 Sep 28, 2020, 5:49 AM • 1 Y
Y by centslordm
Let $M=EQ\cap AF$; note $AM=MF \iff (A, F; M, P_{\infty})=-1$, but we have $(A, F; M, P_{\infty})\overset{E}=(E, F; Q, EP_{\infty}\cap \omega)$. Thus, since $(E, F; D, Q)=-1$, it's equivalent to $EP_{\infty}\cap \omega=D$, or $DE||AB$, which in turn is equivalent to $CA=CB$.
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pad
1671 posts
pad
#6 Dec 29, 2020, 6:59 AM • 4 Y
Y by centslordm, Mango247, Mango247, Mango247
Let $\omega$ be the incricle. Define $Y\in \omega$ such that $\overline{EY}\parallel \overline{AB}$. Then $-1=(AF;X\infty)\stackrel{E}{=}(EF;QY)$. But $(EF;QD)=-1$ since $A=\overline{EE}\cap \overline{FF}\cap \overline{QD}$. Hence $Y=D$, so $\overline{ED} \parallel \overline{AB}$. Therefore, $1=CE/CD=CA/CB$, so $CA=CB$. The opposite direction is very similar.
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HamstPan38825
8857 posts
HamstPan38825
#7 Sep 5, 2021, 2:51 AM • 1 Y
Y by centslordm
$$-1 = (A, F; \overline{QE} \cap \overline{AF}, P_\infty) \stackrel E= (A, \overline{EF} \cap \overline{AD}; Q, \overline{EP_\infty} \cap \overline{AD}).$$But $(A, \overline{EF} \cap \overline{AD}, Q, D)=-1$, so $\overline{DE} \parallel \overline{AB}$ and $AC=BC$.
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bever209
1522 posts
bever209
#8 Sep 23, 2021, 11:07 PM • 1 Y
Y by centslordm
First, we have $(E,F;Q,D)=-1$. Now we assume $EQ$ passes through the midpoint $M$ of $AF$. Now if $P_\infty$ is the point at infinity along line $AB$, we have $(A,B;F,P_\infty)=-1$. Projecting through $E$ gives $(E,F;Q,EP_\infty \cap AD)=-1$, which is only possible if the final point is $D$, i.e. $ED||AB$ which implies the problem.
This post has been edited 2 times. Last edited by bever209, Sep 23, 2021, 11:08 PM
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BVKRB-
322 posts
BVKRB-
#9 Sep 24, 2021, 11:44 AM • 1 Y
Y by centslordm
Let $EQ \cap AF =M$
I have used the Incircle Polars Lemma (EGMO Lemma 9.27) and the Midpoints and Parallels Lemma (EGMO Lemma 9.8)
$$-1 = (E,F;Q,D)\stackrel{E}{=}(A,F;M,ED \ \cap \ AB) \ \text{but} \ AM=MF \iff ED \ \cap \ AB = P_\infty \iff AC=BC \ \ \blacksquare$$
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Mogmog8
1080 posts
Mogmog8
#10 Dec 5, 2022, 3:56 AM • 1 Y
Y by centslordm
Let $P=\overline{QE}\cap\overline{AB}.$ Notice \[-1=(Q,D;E,F)\stackrel{E}=(P,\overline{DE}\cap\overline{AB};A,F)\]so $P$ is the midpoint of $\overline{AF}$ if and only if $\overline{DE}\parallel\overline{AB}.$ But $CD=CE$ so $\overline{DE}\parallel\overline{AB}$ is equivalent to $CA=CB,$ as desired. $\square$
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john0512
4176 posts
john0512
#11 Feb 2, 2023, 3:16 AM • 1 Y
Y by centslordm
Note that due to tangents at $A$, $EDFQ$ is harmonic. Let $EQ$ intersect $AB$ at $K$.

If $CA=CB$, then $ED$ is parallel to $AB$, so projecting through $E$ we have $$-1=(EF;QD)=(AF;K\infty),$$so $K$ must be the midpoint of $AF.$

On the other hand, if $CA\neq CB$, then $ED$ is not parallel to $AB$. Therefore, in this case let $ED$ and $AB$ intersect at $P$. We would then have $$-1=(EF;QD)=(AF;KP),$$but since $P$ is a finite point, $K$ is not the midpoint of $AF$ in this case, so we are done.
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eibc
598 posts
eibc
#12 Aug 10, 2023, 2:37 AM • 1 Y
Y by centslordm
Let $M' = EQ \cap AF$.. Then since $EF$ is the polar of $A$ wrt the incircle, we have $(A, EF\cap QD;Q, D) = -1$. Taking perspectivity at $E$ gives
$$-1 = (A, EF\cap QD;Q, D) \overset{E}{=} (A, F; M', DE \cap AB).$$Thus, since $(A, F; M, P\infty) = -1$, where $M$ is the midpoint of $\overline{AF}$ and $P\infty$ is the point at infinity along line $AB$, we have $M = M'$ iff $DE \parallel AB \iff AC = BC$.
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IAmTheHazard
5001 posts
IAmTheHazard
#13 Aug 15, 2023, 5:17 PM • 1 Y
Y by centslordm
Let $\overline{EQ} \cap \overline{AF}=T$ and $P \neq Q$ be the point on the incircle such that $\overline{PQ} \parallel \overline{AB}$. Then $T$ is the midpoint iff $(A,F;T,P_\infty)=-1$. We have $(A,F;T,P_\infty)\stackrel{Q}{=}(D,F;E,P)$, so this is equivalent to $\overline{EP}$ passing through the intersection of the tangents through $D$ and $F$, which is just $B$. If $AC=BC$ this is clearly true by symmetry. Otherwise, note that since $DEPQ$ is cyclic, by Reim's $DEAB$ should be as well, hence by power of a point $CE\cdot CA=CD\cdot CB$, but since $CD=CE$ this is a contradiction. $\blacksquare$
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YaoAOPS
1502 posts
YaoAOPS
#14 Aug 30, 2023, 2:03 AM
Y by
Note that $QFED$ is harmonic. Let $M$ be the midpoint of $AF$.
As such, $E$, $Q$, $M$ are collinear if and only if \[ (EF;QD) \overset{E}= (A,F;M,\overline{ED} \cap \overline{AB}) = -1. \]This in turn in only holds if $ED \parallel AB$ which holds when \[ \frac{AC}{BC} = \frac{EC}{DC} = 1. \]
Attachments:
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Batsuh
152 posts
Batsuh
#15 Aug 30, 2023, 10:04 AM
Y by
First we prove that if $AC=BC$, then $EQ$ passes through the midpoint of $AF$.
Let $P$ be the intersection of $AD$ and $EF$. Also let line $EQ$ intersect $AF$ at $M$. It is clear that $QFDE$ is harmonic. Projecting through
$F$ onto $AB$ gives $(A,P;Q,D)=1$. Thus $(EA,EP;EQ,ED)=(EA,EF;EM,ED)$ is a harmonic pencil. On the other hand $ED$ is parallel to $AF$. This means that $M$ is the midpoint of $AF$.
For the converse direction, assume that $M$ is the midpoint of $AF$. Note that it's enough to show that $ED$ is parallel to $AB$. Again, $(A,P;Q,D)=1$ and $(EA,EP;EQ,ED)=(EA,EF;EM,ED)$ is a harmonic pencil. But $M$ is the midpoint of $AF$. Thus $ED$ is parallel to $AB$. We're done.
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kamatadu
465 posts
kamatadu
#16 Dec 30, 2023, 6:27 PM
Y by
Let $M=EQ\cap AF$.

Now $-1 = (E,F;Q,D) \overset{E}{=}(A,F;M,ED\cap AB)$.

So now, $M$ is midpoint of $AF \iff ED\parallel AB$ and we are done. :yoda:
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Om245
163 posts
Om245
#17 Jan 1, 2024, 7:26 PM
Y by
Let $M = \overline{AF} \cap \overline{EQ}$ As its given $MF = MA$ by POP we get


$$ \angle FAD = \angle AEQ \implies 2\angle BAC = 2\angle EQD = \angle DIE$$hence $\angle C = 180 - \angle A \implies CA=CB$. $\blacksquare$
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shendrew7
793 posts
shendrew7
#18 Jan 13, 2024, 7:57 PM
Y by
Oops.

Let $M = QE \cap AF$ and $P$ as the intersection of the incircle with the line through $Q$ parallel to $AB$. Then
\begin{align*} MA = MF &\iff (AF;M \infty) = -1 \iff (DF;EP) = -1 \\ &\iff B, P, E \text{ collinear} \iff ABDE \text{ cyclic} \iff AC = BC. \quad \blacksquare. \end{align*}
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cursed_tangent1434
569 posts
cursed_tangent1434
#19 Jan 14, 2024, 3:51 AM
Y by
Quite trivial. Let $M=\overline{QE} \cap \overline{AB}$.

We first make the following observation. Since $AE,AF$ are tangents and $A-Q-D$ we have that,
\[(QD;EF)=-1\]Now, if $CA=CB$, then $ED \parallel AB$ since $2\measuredangle CED = \measuredangle ECD = 2\measuredangle CAB$. Thus,
\[(AF;MP_\infty) \overset{E}{=}(EF;QD)=-1\]This means that $M$ is in fact the midpoint of $AF$ as desired.

If $M$ is the midpoint of $AF$, then note that
\[-1=(EF;QD) \overset{E}{=} (AF;MP)\]where $P= \overline{ED} \cap \overline{AB}$. But, it is well known that $(AF;MP_\infty)=-1$ which implies that $P=P_\infty$ and thus, $ED \parallel AB$ which inturn implies that $\triangle CAB$ is isoceles with $CA=CB$ as desired.
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Scilyse
387 posts
Scilyse
#20 Feb 8, 2024, 10:30 AM
Y by
[asy] import olympiad; import cse5; defaultpen(fontsize(10pt)); usepackage("amsmath"); usepackage("amssymb"); usepackage("gensymb"); usepackage("textcomp"); size(8cm); pair MRA (pair B, pair A, pair C, real r, pen q=anglepen) { r=r/2; pair Bp=unit(B-A)*r+A; pair Cp=unit(C-A)*r+A; pair P=Bp+Cp-A; D(Bp--P--Cp,q); return A; } pointpen=black+linewidth(2); pen polyline=linewidth(pathpen)+rgb(0.6,0.2,0); pen polyfill=polyline+opacity(0.1); pen angleline=linewidth(pathpen)+rgb(0,0.4,0); pen anglefill=angleline+opacity(0.4); markscalefactor=0.01; size(12cm); pair A=dir(180+50),B=dir(-50),C=dir(90); // filldraw(A--B--C--cycle,polyfill,polyline); D(A--B--C--cycle,polyline); pair I=incenter(A,B,C); pair D=foot(I,B,C),E=foot(I,C,A),F=foot(I,A,B); pair Q=2*foot(I,A,D)-D; pair M=(A+F)/2; D(CP(I,D)); D(A--D); D(E--M,pathpen+dashed); D("A",D(A),A); D("B",D(B),B); D("C",D(C),C); D("I",D(I),dir(90)); D("D",D(D),unit(D-I)); D("E",D(E),unit(E-I)); D("F",D(F),unit(F-I)); D("Q",D(Q),dir(174)); D("M",D(M),S); [/asy]

Let $M$ be the midpoint of $\overline{AF}$. Now \[-1 = (DQ; EF) \stackrel{E}{=} (DE \cap AB, EQ \cap AF; AF)\text{.}\]Now if $AC = BC$ then $DE \parallel AB$ so $EQ \cap AF$ must necessarily be $M$. Conversely, if $EQ \cap AF = M$ then $DE \cap AB = \infty_{AB}$ and so $AC = BC$.
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dolphinday
1318 posts
dolphinday
#21 Feb 8, 2024, 6:23 PM
Y by
Let $M$ be the midpoint of $AF$.
If $AC = BC$ then it follows that $DE \parallel AB$ so we have $-1 = (P_{\infty}, M; F, A)$. Since $QEDF$ is a harmonic quadrilateral, we have $-1 = (Q, D; E, F) \overset{E} = (\overline{EQ} \cap \overline{AB}, P_{\infty}; F, A)$ so $\overline{EQ} \cap \overline{AB} = M$.
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Markas
105 posts
Markas
#22 Jun 16, 2024, 7:52 PM
Y by
Let $EQ\cap AF = M$. If we have AM = MF, then $(A, F; M, P_{\infty}) = -1$, but also $(A, F; M, P_{\infty})\stackrel{E}{=}(E, F; Q, EP_{\infty}\cap \omega) = -1$. Now from AF and AE tangents and A, Q, D being collinear we have that EQFD is a harmonic quadrilateral $\Rightarrow$ $(E, F; Q, D) = -1$ and from $(E, F; Q, EP_{\infty}\cap \omega) = (E, F; Q, D) = -1$ $\Rightarrow$ $EP_{\infty} \cap \omega = D$, or $DE \parallel AB$, which is equivalent to CA = CB, since CE = CD $\Rightarrow$ we are ready.
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bebebe
985 posts
bebebe
#23 Aug 15, 2024, 1:50 PM
Y by
We know $(E,F;Q,D)=-1$ (from tangents at $A$). Taking perspectivity from $E$ onto line $AB$ gives $(A,F;EQ\cap AB,ED\cap AB)=-1.$ Thus, $EQ\cap AB$ is the midpoint of $AF$ iff $ED \cap AB = P_{\infty}$. Since $CE=CD,$ we know by similar triangles $ED \parallel AB$ iff $AC=BC$, and we are done.
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N3bula
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N3bula
#24 Dec 7, 2024, 6:20 AM
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Let $EF\cap AD$ be $P$, we let $ED\cap AB$ be $T$ and we let $EQ\cap AF$ be $M$, we get $-1=(A,P;Q,D)\overset{\mathrm{E}}{=}(A,F;M,T)$ as $M$ is the midpoint
of $AF$ we get that $T$ is the point at infinity so $ED$ is parallel to $AB$ so $AC=BC$.
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Ilikeminecraft
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Ilikeminecraft
#25 Mar 30, 2025, 5:29 PM
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\[-1 = (A, F; \overline{QE} \cap \overline{AF}, P_\infty) \stackrel E= (A, \overline{EF} \cap \overline{AD}; Q, \overline{EP_\infty} \cap \overline{AD}).\]But $(A, \overline{EF} \cap \overline{AD}, Q, D)=-1$, so $\overline{DE} \parallel \overline{AB}$ and $AC=BC$.
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