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k a May Highlights and 2025 AoPS Online Class Information
jlacosta   0
May 1, 2025
May is an exciting month! National MATHCOUNTS is the second week of May in Washington D.C. and our Founder, Richard Rusczyk will be presenting a seminar, Preparing Strong Math Students for College and Careers, on May 11th.

Are you interested in working towards MATHCOUNTS and don’t know where to start? We have you covered! If you have taken Prealgebra, then you are ready for MATHCOUNTS/AMC 8 Basics. Already aiming for State or National MATHCOUNTS and harder AMC 8 problems? Then our MATHCOUNTS/AMC 8 Advanced course is for you.

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[*]May 21st, 4:00pm PT/7:00pm ET, Mathcamp 2025 Qualifying Quiz Part 2 Math Jam, Problems 5 and 6, Canada/USA Mathcamp staff will discuss solutions to Problems 5 and 6 of the 2025 Mathcamp Qualifying Quiz![/list]
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0 replies
jlacosta
May 1, 2025
0 replies
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k i Adding contests to the Contest Collections
dcouchman   1
N Apr 5, 2023 by v_Enhance
Want to help AoPS remain a valuable Olympiad resource? Help us add contests to AoPS's Contest Collections.

Find instructions and a list of contests to add here: https://artofproblemsolving.com/community/c40244h1064480_contests_to_add
1 reply
dcouchman
Sep 9, 2019
v_Enhance
Apr 5, 2023
J
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k i Zero tolerance
ZetaX   49
N May 4, 2019 by NoDealsHere
Source: Use your common sense! (enough is enough)
Some users don't want to learn, some other simply ignore advises.
But please follow the following guideline:


To make it short: ALWAYS USE YOUR COMMON SENSE IF POSTING!
If you don't have common sense, don't post.


More specifically:

For new threads:


a) Good, meaningful title:
The title has to say what the problem is about in best way possible.
If that title occured already, it's definitely bad. And contest names aren't good either.
That's in fact a requirement for being able to search old problems.

Examples:
Bad titles:
- "Hard"/"Medium"/"Easy" (if you find it so cool how hard/easy it is, tell it in the post and use a title that tells us the problem)
- "Number Theory" (hey guy, guess why this forum's named that way¿ and is it the only such problem on earth¿)
- "Fibonacci" (there are millions of Fibonacci problems out there, all posted and named the same...)
- "Chinese TST 2003" (does this say anything about the problem¿)
Good titles:
- "On divisors of a³+2b³+4c³-6abc"
- "Number of solutions to x²+y²=6z²"
- "Fibonacci numbers are never squares"


b) Use search function:
Before posting a "new" problem spend at least two, better five, minutes to look if this problem was posted before. If it was, don't repost it. If you have anything important to say on topic, post it in one of the older threads.
If the thread is locked cause of this, use search function.

Update (by Amir Hossein). The best way to search for two keywords in AoPS is to input
[code]+"first keyword" +"second keyword"[/code]
so that any post containing both strings "first word" and "second form".


c) Good problem statement:
Some recent really bad post was:
[quote]$lim_{n\to 1}^{+\infty}\frac{1}{n}-lnn$[/quote]
It contains no question and no answer.
If you do this, too, you are on the best way to get your thread deleted. Write everything clearly, define where your variables come from (and define the "natural" numbers if used). Additionally read your post at least twice before submitting. After you sent it, read it again and use the Edit-Button if necessary to correct errors.


For answers to already existing threads:


d) Of any interest and with content:
Don't post things that are more trivial than completely obvious. For example, if the question is to solve $x^{3}+y^{3}=z^{3}$, do not answer with "$x=y=z=0$ is a solution" only. Either you post any kind of proof or at least something unexpected (like "$x=1337, y=481, z=42$ is the smallest solution). Someone that does not see that $x=y=z=0$ is a solution of the above without your post is completely wrong here, this is an IMO-level forum.
Similar, posting "I have solved this problem" but not posting anything else is not welcome; it even looks that you just want to show off what a genius you are.

e) Well written and checked answers:
Like c) for new threads, check your solutions at least twice for mistakes. And after sending, read it again and use the Edit-Button if necessary to correct errors.



To repeat it: ALWAYS USE YOUR COMMON SENSE IF POSTING!


Everything definitely out of range of common sense will be locked or deleted (exept for new users having less than about 42 posts, they are newbies and need/get some time to learn).

The above rules will be applied from next monday (5. march of 2007).
Feel free to discuss on this here.
49 replies
ZetaX
Feb 27, 2007
NoDealsHere
May 4, 2019
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4-vars inequality
xytunghoanh   4
N 3 minutes ago by JARP091
For $a,b,c,d \ge 0$ and $a\ge c$, $b \ge d$. Prove that
$$a+b+c+d+ac+bd+8 \ge 2(\sqrt{ab}+\sqrt{bc}+\sqrt{cd}+\sqrt{da}+\sqrt{ac}+\sqrt{bd})$$.
4 replies
xytunghoanh
Yesterday at 2:10 PM
JARP091
3 minutes ago
J
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Functional Equation!
EthanWYX2009   4
N 4 minutes ago by hef4875
Source: 2025 TST 24
Find all functions $f:\mathbb Z\to\mathbb Z$ such that $f$ is unbounded and
\[2f(m)f(n)-f(n-m)-1\]is a perfect square for all integer $m,n.$
4 replies
EthanWYX2009
Mar 29, 2025
hef4875
4 minutes ago
J
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Hard geometry
Lukariman   7
N 16 minutes ago by Captainscrubz
Given circle (O) and chord AB with different diameters. The tangents of circle (O) at A and B intersect at point P. On the small arc AB, take point C so that triangle CAB is not isosceles. The lines CA and BP intersect at D, BC and AP intersect at E. Prove that the centers of the circles circumscribing triangles ACE, BCD and OPC are collinear.
7 replies
Lukariman
May 14, 2025
Captainscrubz
16 minutes ago
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Prove that the triangle is isosceles.
TUAN2k8   0
17 minutes ago
Source: My book
Given acute triangle $ABC$ with two altitudes $CF$ and $BE$.Let $D$ be the point on the line $CF$ such that $DB \perp BC$.The lines $AD$ and $EF$ intersect at point $X$, and $Y$ is the point on segment $BX$ such that $CY \perp BY$.Suppose that $CF$ bisects $BE$.Prove that triangle $ACY$ is isosceles.
0 replies
TUAN2k8
17 minutes ago
0 replies
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Sneaky one
Sunjee   2
N 20 minutes ago by Sunjee
Find minimum and maximum value of following function.
$$f(x,y)=\frac{\sqrt{x^2+y^2}+\sqrt{(x-2)^2+(y-1)^2}}{\sqrt{x^2+(y-1)^2}+\sqrt{(x-2)^2+y^2}} $$
2 replies
Sunjee
37 minutes ago
Sunjee
20 minutes ago
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Simple but hard
Lukariman   2
N 43 minutes ago by Lukariman
Given triangle ABC. Outside the triangle, construct rectangles ACDE and BCFG with equal areas. Let M be the midpoint of DF. Prove that CM passes through the center of the circle circumscribing triangle ABC.
2 replies
Lukariman
Today at 2:47 AM
Lukariman
43 minutes ago
J
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D1033 : A problem of probability for dominoes 3*1
Dattier   1
N an hour ago by Dattier
Source: les dattes à Dattier
Let $G$ a grid of 9*9, we choose a little square in $G$ of this grid three times, we can choose three times the same.

What the probability of cover with 3*1 dominoes this grid removed by theses little squares (one, two or three) ?
1 reply
Dattier
Yesterday at 12:29 PM
Dattier
an hour ago
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Please I need help
yaybanana   2
N an hour ago by yaybanana
Source: Samin Riasat Handout
Please can someone help me, I'm bad at inequalities and I have no clue on how to solve this :

Let $a,b,c$ be positive reals, s.t $a+b+c=1$, prove that :

$\frac{a}{\sqrt{a+2b}}+\frac{b}{\sqrt{b+2c}}+\frac{c}{\sqrt{c+2a}}<\sqrt{\frac{3}{2}}$
2 replies
yaybanana
an hour ago
yaybanana
an hour ago
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LCM genius problem from our favorite author
MS_Kekas   2
N an hour ago by AshAuktober
Source: Kyiv City MO 2022 Round 2, Problem 8.1
Find all triples $(a, b, c)$ of positive integers for which $a + [a, b] = b + [b, c] = c + [c, a]$.

Here $[a, b]$ denotes the least common multiple of integers $a, b$.

(Proposed by Mykhailo Shtandenko)
2 replies
MS_Kekas
Jan 30, 2022
AshAuktober
an hour ago
J
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How many residues modulo p are sums of two squares?
Tintarn   8
N 2 hours ago by thaiquan2008
Source: Austrian MO 2024, Final Round P6
For each prime number $p$, determine the number of residue classes modulo $p$ which can
be represented as $a^2+b^2$ modulo $p$, where $a$ and $b$ are arbitrary integers.

(Daniel Holmes)
8 replies
Tintarn
Jun 1, 2024
thaiquan2008
2 hours ago
J
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Interesting inequalities
sqing   2
N 2 hours ago by sqing
Source: Own
Let $a,b,c \geq 0 $ and $ab+bc+ca- abc =3.$ Show that
$$a+k(b+c)\geq 2\sqrt{3 k}$$Where $ k\geq 1. $
Let $a,b,c \geq 0 $ and $2(ab+bc+ca)- abc =31.$ Show that
$$a+k(b+c)\geq \sqrt{62k}$$Where $ k\geq 1. $
2 replies
sqing
6 hours ago
sqing
2 hours ago
J
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abc = 1 Inequality generalisation
CHESSR1DER   7
N 2 hours ago by CHESSR1DER
Source: Own
Let $a,b,c > 0$, $abc=1$.
Find min $ \frac{1}{a^m(bx+cy)^n} + \frac{1}{b^m(cx+ay)^n} + \frac{1}{c^m(cx+ay)^n}$.
$1)$ $m,n,x,y$ are fixed positive integers.
$2)$ $m,n,x,y$ are fixed positive real numbers.
7 replies
CHESSR1DER
Yesterday at 6:40 PM
CHESSR1DER
2 hours ago
J
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Old problem
kwin   2
N 2 hours ago by lbh_qys
Let $ a, b, c > 0$ . Prove that:
$$(a^2+b^2)(b^2+c^2)(c^2+a^2)(ab+bc+ca)^2 \ge 8(abc)^2(a^2+b^2+c^2)^2$$
2 replies
kwin
Today at 3:44 AM
lbh_qys
2 hours ago
J
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IMO Solution mistake
CHESSR1DER   0
3 hours ago
Source: Mistake in IMO 1982/1 4th solution
I found a mistake in 4th solution at IMO 1982/1. It gives answer $660$ and $661$. But right answer is only $660$. Should it be reported somewhere in Aops?
0 replies
CHESSR1DER
3 hours ago
0 replies
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J
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Tilted Students Thoroughly Splash Tiger part 2
DottedCaculator   19
N Wednesday at 2:12 PM by ihatemath123
Source: ELMO 2024/5
In triangle $ABC$ with $AB<AC$ and $AB+AC=2BC$, let $M$ be the midpoint of $\overline{BC}$. Choose point $P$ on the extension of $\overline{BA}$ past $A$ and point $Q$ on segment $\overline{AC}$ such that $M$ lies on $\overline{PQ}$. Let $X$ be on the opposite side of $\overline{AB}$ from $C$ such that $\overline{AX} \parallel \overline{BC}$ and $AX=AP=AQ$. Let $\overline{BX}$ intersect the circumcircle of $BMQ$ again at $Y \neq B$, and let $\overline{CX}$ intersect the circumcircle of $CMP$ again at $Z \neq C$. Prove that $A$, $Y$, and $Z$ are collinear.

Tiger Zhang
19 replies
DottedCaculator
Jun 21, 2024
ihatemath123
Wednesday at 2:12 PM
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Tilted Students Thoroughly Splash Tiger part 2
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Reveal topic tags
geometry
Elmo
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ilostthegame
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G H BBookmark kLocked kLocked NReply
Source: ELMO 2024/5
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DottedCaculator
7355 posts
DottedCaculator
#1 Jun 21, 2024, 4:17 PM • 9 Y
Y by NO_SQUARES, centslordm, crazyeyemoody907, bjump, Rounak_iitr, nmoon_nya, ehuseyinyigit, chirita.andrei, MS_asdfgzxcvb
In triangle $ABC$ with $AB<AC$ and $AB+AC=2BC$, let $M$ be the midpoint of $\overline{BC}$. Choose point $P$ on the extension of $\overline{BA}$ past $A$ and point $Q$ on segment $\overline{AC}$ such that $M$ lies on $\overline{PQ}$. Let $X$ be on the opposite side of $\overline{AB}$ from $C$ such that $\overline{AX} \parallel \overline{BC}$ and $AX=AP=AQ$. Let $\overline{BX}$ intersect the circumcircle of $BMQ$ again at $Y \neq B$, and let $\overline{CX}$ intersect the circumcircle of $CMP$ again at $Z \neq C$. Prove that $A$, $Y$, and $Z$ are collinear.

Tiger Zhang
This post has been edited 1 time. Last edited by DottedCaculator, Jun 21, 2024, 4:17 PM
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YaoAOPS
1541 posts
YaoAOPS
#2 Jun 21, 2024, 4:17 PM • 4 Y
Y by centslordm, crazyeyemoody907, Rounak_iitr, MS_asdfgzxcvb
Quite shrimple?

Claim: $BC = CQ$, and similarly $BP = BC$.
Proof. By directed lengths, we get that $BQ = b \cdot \frac{\frac{a}{2}}{a \cdot \frac{b}{b+c}} = \frac{b+c}{2}$. $\blacksquare$

Claim: $BQ, PC, AX$ concur on $(XPQ)$.
Proof. Note that $\measuredangle (AX, QB) = \measuredangle CBQ = \measuredangle BQC = \measuredangle (BQ, QA)$. This implies that $W = BQ \cap AX$ lies on $(XPQ)$. By symmetry, we similarly get $W$ lies on $PC$. $\blacksquare$
As such, it follows that $\measuredangle QBM + \measuredangle BCP = \measuredangle QWP$ which implies that the circles $(BMQ), (CMP), (PXQ)$ concur at some point $D$. Now, by triangle Miquel on $BXC$ we get that $(XYZD)$ is cyclic.

Claim: $AX, AD$ are tangents to $(XYZD)$.
Proof. Since $\measuredangle MDQ = \measuredangle MBW = \measuredangle XWQ = \measuredangle XDQ$ we get that $M$ lies on $XD$.
Note that since $\measuredangle AXD = \measuredangle AXM = \measuredangle DMB = \measuredangle DYB = \measuredangle DYX$, it follows that $AX$ is a tangent.
By orthogonality it follows that $AD$ must also be a tangent. $\blacksquare$
As such, since \[ (BC;M\infty) \overset{X}= (YZ;DX) = -1 \]this implies $A$ lies on $YZ$.
This post has been edited 1 time. Last edited by YaoAOPS, Jun 21, 2024, 4:19 PM
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CyclicISLscelesTrapezoid
372 posts
CyclicISLscelesTrapezoid
#3 Jun 21, 2024, 4:20 PM • 11 Y
Y by centslordm, CT17, khina, crazyeyemoody907, iamnotgentle, v4913, Rounak_iitr, cosdealfa, Yiyj1, Sedro, mrtheory
My problem!

[asy] // ELMO 2024/5 size(9cm); defaultpen(0.8); defaultpen(fontsize(9pt)); dotfactor*=0.6; pen greenfill,greendraw,lightbluedraw,bluedraw,purpledraw,pinkdraw; greenfill = RGB(204,255,204); greendraw = RGB(0,187,0); lightbluedraw = RGB(85,187,255); bluedraw = RGB(0,102,255); purpledraw = RGB(170,34,255); pinkdraw = RGB(255,17,255); pair A,B,C,M,P,Q,X,Y,Z,R; path c,d,e; A = (-4/5,3*sqrt(7)/5); B = (-1,0); C = (1,0); M = (B+C)/2; c = circle(A,(distance(A,C)-distance(A,B))/2); P = intersectionpoints(c,A--2*A-B)[0]; Q = intersectionpoints(c,A--C)[0]; X = intersectionpoints(c,A--A+B-C)[0]; d = circumcircle(B,M,Q); e = circumcircle(C,M,P); Y = intersectionpoints(d,B--X)[0]; Z = intersectionpoints(e,C--X)[0]; R = intersectionpoints(d,e)[0]; filldraw(c,greenfill,greendraw); draw(d,purpledraw); draw(e,purpledraw); draw(circumcircle(X,Y,Z),pinkdraw); draw(P--A--B--C--A,bluedraw); draw(M--P,lightbluedraw); draw(A--X,lightbluedraw); draw(A--R,lightbluedraw); draw(A--Y,lightbluedraw); draw(B--X,lightbluedraw); draw(C--X,lightbluedraw); draw(M--X,lightbluedraw); dot("$A$",A,dir(40)); dot("$B$",B,dir(230)); dot("$C$",C,dir(290)); dot("$M$",M,dir(275)); dot("$P$",P,dir(110)); dot("$Q$",Q,1.7*dir(25)); dot("$X$",X,dir(130)); dot("$Y$",Y,dir(320)); dot("$Z$",Z,dir(190)); dot("$R$",R,1.6*dir(245)); [/asy]

Let $\measuredangle$ denote directed angles modulo $180^\circ$.

By Menelaus, we have
\[\frac{BP}{PA} \cdot \frac{AQ}{QC} \cdot \frac{CM}{MB}=1,\]and since $BM=CM$ and $AP=AQ$, this gives $BP=CQ$. If we let $BP=CQ=x$ and $AP=AQ=y$, then we have $x-y=AB$ and $x+y=AC$, so $x=\tfrac{AB+AC}{2}=BC$.

Let circle centered at $A$ through $X$, $P$, and $Q$ intersect $\overline{XM}$ again at $R$.

Claim: $R$ lies on the circumcircles of $BMQ$ and $CMP$.
Proof: We have
\[\angle MRQ=180^\circ-\angle XRQ=\frac{\angle XAQ}{2}=\frac{180^\circ-\angle ACB}{2}=\angle MBQ,\]so $BMQR$ is cyclic. Analogously, $CMRP$ is cyclic. $\square$

Claim: $XYRZ$ is cyclic and its circumcircle is tangent to $\overline{AX}$.
Proof: We have
\[\measuredangle XYR=\measuredangle BYR=\measuredangle BMR=\measuredangle AXR,\]so the circumcircle of $XRY$ is tangent to $\overline{AX}$. Analogously, the circumcircle of $XRZ$ is tangent to $\overline{AX}$, so the circle through $X$ and $R$ tangent to $\overline{AX}$ passes through $Y$ and $Z$, as desired. $\square$

Let $\infty_{BC}$ be the point at infinity on $\overline{BC}$. We have $(X,R;Y,Z)\overset{X}{=}(\infty_{BC},M;B,C)=-1$, so $XRYZ$ is harmonic. Since $\overline{AX}$ is tangent to its circumcircle, we know that $\overline{AR}$ is tangent as well, so $A$, $Y$, and $Z$ are collinear by the symmedian configuration. $\blacksquare$
This post has been edited 7 times. Last edited by CyclicISLscelesTrapezoid, Sep 2, 2024, 10:04 PM
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DottedCaculator
7355 posts
DottedCaculator
#4 Jun 21, 2024, 4:23 PM • 3 Y
Y by centslordm, parola, mrtheory
By lengths, $AP=AQ=\frac{b-c}2$ so $BP=CQ=a$, which gives $P=(2a:c-b:0)$ and $Q=(2a:0:b-c)$. We get $X=(2a:b-c:c-b)$. The circumcircle of $BMQ$ is $-a^2yz-b^2zx-c^2xy+(x+y+z)\left(\frac{(2b-a)(b-c)}4x+\frac12a^2z\right)=0$ so line $BX$ intersects this at $(2a:y:c-b)$, implying
$$y(-a^2(c-b)-2ac^2)-2ab^2(c-b)+\frac14(2a+c-b+y)((2b-a)(b-c)2a+2a^2(c-b))=0$$or
$$y=\frac{(b-c)(c-2b)}{(b-2c)}.$$
Similarly, $CX$ intersects this at $(2a:b-c:z)$ where $z=\frac{(c-b)(b-2c)}{c-2b}$, so $A$, $Y$, and $Z$ collinear is equivalent to $\frac y{c-b}=\frac{b-c}z$, or $yz=-(b-c)^2$, which is true.
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NO_SQUARES
1133 posts
NO_SQUARES
#5 Jun 21, 2024, 4:25 PM • 1 Y
Y by centslordm
Nice problem!
First we will prove that $BP=BC=CQ$. Note that by Menelaus's theorem we have \[ 1=\frac{BM}{MC} \cdot \frac{CQ}{QA} \cdot \frac{AP}{PB} = \frac{CQ}{PB},\]so $CQ=PB$. Also $CQ+PB=(CQ+QA)+(PB-PA)=AC+AB=2BC \Rightarrow CQ=PB=BC.$

Let $D=(BMQ) \cap (CMP)$. Now we will prove that $AD=AP=AQ$. Note that this condition is equivalent to condition that $A$ is center of circle $(PQD)$. Since $AP=AQ$, it's enough to prove that $\angle PAQ=2 \angle PDQ$. Note that $D$ is center of spiral similarity of segments $PQ$ and $CB$, so $\angle PQD=\angle BCD$ and $\angle PCD=\angle QBD$, so $\angle BDC=180^\circ-\angle DBC-\angle DCB=180^\circ - (\angle CBQ + \angle BCP)=180^\circ-(90^\circ - \frac{1}{2}\angle BCA + 90^\circ - \frac{1}{2}\angle CBA)=\frac{1}{2} (\angle ABC + \angle ACB)=\frac{1}{2}\angle QAP.$ So, really $\angle PAQ=2 \angle PDQ$ and $AP=AQ=AD$.

Note that if $BQ \cap AX=E$, then $\angle AEQ=\angle CBQ=\angle CQB=\angle AQE$ and so $AQ=AE \Rightarrow E \in (PQD).$ Now note that since $AD=AE=AP=AQ=AX$, $PEQDX$ is cyclic and then $\angle AXD = \angle DQB = \angle DMB$ and so $M,D,X$ are collinear. By PoP we get $XY \cdot XB = XD\cdot XM = XC \cdot XZ$, so $BYZC$ is cyclic.

We have $\angle DYX = \angle BMD = \angle CZD$, so $XYDZ$ is cyclic. Now $\angle AXZ = \angle XCB = \angle ZYX$, so $AX$ is tangent to circle $(XYDZ)$. Since $AD=AX$, line $AD$ is also tangent to circle $(XYDZ)$. By this reason it is enough to prove that $XYDZ$ is harmonic quadrilateral.

Note that $\Delta XZD \sim \Delta XMC$ and $\Delta XDY \sim \Delta XBM$, so \[ \frac{XZ}{ZD}=\frac{XM}{MC}=\frac{XM}{MB}=\frac{XY}{YD} \Rightarrow XZ \cdot DY = XY \cdot ZD\]and so we are done!
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MarkBcc168
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MarkBcc168
#6 Jun 21, 2024, 4:27 PM • 4 Y
Y by centslordm, Number_theory060222, GeoKing, Muaaz.SY
First, notice that $P$ and $Q$ both lie on line through $M$ parallel to the angle bisector of $\angle BAC$. Thus, if $P_1 = 2P-B$ and $Q_1=2Q-C$, then $AP_1=AC$ and $AQ_1=AB$. Thus, $BP = CQ = \tfrac{AB+AC}2 = BC$

Now, let $XM$ intersect $\odot(XPQ)$ at $T$. We have
$$\angle QTM = 180^\circ - \angle QTX = \frac{\angle QAX}2 = 90^\circ - \frac{\angle C}2 = \angle QBM,$$so $T\in\odot(BMQ)$. Similarly, $T\in\odot(CMP)$. By power of point from $X$, we get $BCYZ$ concyclic. Moreover, by Miquel's theorem, we get $XYZT$ concyclic.

Finally, notice that since $XM$ is median of $\triangle XBC$, we get that $XT$ is symmedian of $\triangle XYZ$. Thus, $XYZT$ is harmonic quadriltaral. Since we have $XA$ tangent to $\odot(XYZ)$ and $AX=AT$, it follows that $A\in YZ$, done.
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math_comb01
662 posts
math_comb01
#7 Jun 21, 2024, 4:38 PM • 4 Y
Y by centslordm, Number_theory060222, Rounak_iitr, ehuseyinyigit
Nice Problem! Looks like I over-complicated lol.
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If $I_A$ is the excenter of $\triangle ABC$ and $W$ is reflection of $I_A$ in $M$. Let $BW \cap AC = Q'$ and $CW \cap AB = P'$

$\textbf{Claim 1:}$ $P' \equiv P$ and $Q' \equiv Q$.

$\textbf{Proof:}$ By reflection $\measuredangle Q'CB = 90 - \frac{C}{2}$ so $BC = CQ' = BP'$; $$AP = BC-AB = AC-BC = AQ$$and by converse of menelaus : $$\frac{BM}{MC} \cdot \frac{BP}{AP} \cdot \frac{AQ}{CQ} = 1$$, we get $M,P,Q$ are collinear which implies the claim as there exists an unique choice of $P,Q$.

$\textbf{Claim 2:}$ $AW \parallel BC$, $AW = AP=AQ$

$\textbf{Proof:}$ let $M_A$ denote the arc midpoint of arc $BC$, by ptolemy $M_AB(AB+AC) = AM_A(BC)$ so $2M_AB=AM_A$ which implies $M_AI_A=M_AI=AI$ by incenter-excenter lemma.Let $AI \cap BC = D$, then it is well known that $$-1=(BA,BD;BI,BI_A) = (AD;II_A) = \frac{IA}{ID} \cdot \frac{I_AD}{I_AA} = \frac{3 \cdot ID}{I_AD}$$, therefore $AD = I_AD$, now reflect $I_A$ about $B,C$ to get $I_A'$ and $I_A''$ then $\overline{AI_A'I_A''}$ is collinear and parallel to $BC$ as $I_AD=AD$ so we conclude $AW \parallel BC$, now for $AW=AP$ consider homothety of half at $I_A$ to get $AW = 2MD = BC-AC=AP=AQ$

Let $L = CW \cap MM_A$, let $D \in (ABC)$ such that $AD \parallel BC$, let $T = PQ \cap AD$, let $S = AD \cap MM_A$.

$\textbf{Claim 3:}$ $L \in (CMPY)$ and $\overline{LPX}$ are collinear.

$\textbf{Proof:}$ $$\measuredangle CLM = \measuredangle C/2 = \measuredangle (90- A/2 - B/2) = \measuredangle BPC - \measuredangle APQ = \measuredangle CPM $$. $$90^{\circ}= \measuredangle CPL = \measuredangle (90-B/2) + \measuredangle (B/2) = \measuredangle CPB + \measuredangle BPX = \measuredangle CPX $$
$\textbf{Claim 4:}$ $APQSM_{BC}$ is cyclic where $M_{BC}$ is arc midpoint of $BC$ containing $A$.

$\textbf{Proof:}$ $APQM_{BC}$ is cyclic as $M_{BC}QC \equiv M_{BC}PB$, notice that $\overline{MPQ}$ is simson line of $M_{BC}$ as $\measuredangle AQM_{BC} = 180-\measuredangle (90-A/2)-\measuredangle A/2 = 90 $ so $(APQ)$ is circle with diameter $M_{BC}A$ which implies $S \in (APQ)$ as well.

$\textbf{Claim 5:}$ $PXYT$ is cyclic.

$\textbf{Proof:}$ $$\measuredangle TPY = \measuredangle MPY = \measuredangle MCY = \measuredangle MCX = \measuredangle TXY $$
$\textbf{Claim 6:}$ $STYZM$ is cyclic.

$\textbf{Proof:}$ It suffices to prove that $STYM$ is cyclic and the conclusion follows by symmetry.
$$\measuredangle MYT = \measuredangle MYP - \measuredangle PYT = 180- \measuredangle MCP $$$$- \measuredangle PXA = 180-\measuredangle (90-B/2) - \measuredangle (B/2) = 90^{\circ} = \measuredangle MST $$
$\textbf{Claim 7:}$ $BCYZ$ is cyclic.

$\textbf{Proof:}$ $$\measuredangle YSW = \measuredangle YST = \measuredangle YMP = \measuredangle YCW$$so $CSWY$ is cyclic, and similarly $SQZB$ is cyclic, so $XC \cdot XY = XS \cdot XW =XB \cdot XZ$

$\textbf{Claim 8:}$ $AX$ is tangent to $(XYZ)$

$\textbf{Proof:}$ $$\measuredangle AXY = \measuredangle YCB = \measuredangle XZY$$
Now we note that $S,T$ are inverses WRT $(APQ)$ because $A,S,T$ are collinear and $S \in (APQ)$ so $$AS \cdot AT = AX^2$$so $A$ lies on radical axes of $(STYZM)$ and $(XYZ)$, that is $YZ$, hence we're done. $\blacksquare$
This post has been edited 1 time. Last edited by math_comb01, Jun 21, 2024, 4:50 PM
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VicKmath7
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VicKmath7
#8 Jun 21, 2024, 5:02 PM • 1 Y
Y by Rounak_iitr
Solution
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OronSH
1745 posts
OronSH
#9 Jun 21, 2024, 6:43 PM • 2 Y
Y by ihatemath123, Jack_w
Very nice, just add the reflection $T$ of $X$ over $A,$ the reflection of $A$ over $T,$ the midpoint of $AT,$ the reflection of $B$ over $C,$ the intersections of the perpendicular bisector of $BC$ with lines $BQ$ and $CP,$ the foot from $A$ to $BC,$ the intouch point, the extouch point, the incenter, the orthocenter, the centroid, the circumcenter and the nagel point and now it is trivial (what I did in contest)
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ddami
10 posts
ddami
#10 Jun 21, 2024, 9:55 PM
Y by
Similarly to others we can prove that lines BQ and CP meet at a point D at the circumcircle of XPQ. Here is another way to finish

Let T be the intersection of PQ with AX.
Let A' and X' be the reflections of A and X through D, respectively
Let W be the reflection of X through A'.

After a few computations we can get A'M perpendicular to BC. Thus DX'CB is a trapezoid.
Note that XYQT and XZTP are cyclic
Then angles CZT, XPT, XDQ and the supplementary of DX'C are equal. Hence TZCX' is cyclic
Then XZ * XC = XT * XX' = XA * XW and thus angles XAZ and WCX are equal
Likewise we obtain angles XAY and WBX are equal.
Since XBCW is a trapezoid we get that angles WCX and WBX are equal, thus angles XAZ and XAY are equal. Conclusion follows

Note: The computations I did to get A'M perpendicular to BC involve the hypothesis AC + AB = 2BC. Thus if the tangency point of BC with the incircle of ABC divides BC in two segments of lenghts 2b < 2c, then AB = 3b + c, AC = b + 3c, AA' = 2c - 2b, and from there we may compute AM and the altitude from A to BC
This post has been edited 1 time. Last edited by ddami, Jun 21, 2024, 9:58 PM
Reason: misspelled
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Ywgh1
139 posts
Ywgh1
#11 Jun 22, 2024, 9:54 AM • 1 Y
Y by Sedro
Any explanation to the title ? :)
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r00tsOfUnity
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r00tsOfUnity
#12 Jun 23, 2024, 3:08 AM
Y by
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X.Allaberdiyev
104 posts
X.Allaberdiyev
#13 Jun 23, 2024, 1:14 PM • 1 Y
Y by Rounak_iitr
Let me also add one sol. without details)
One can easily observe that $PB=BC=CQ$(by Menelaus th). Let $BQ \cap PC=T$, by cheva we have $X - A - T$ and simply we have $(XPQT)$ is cyclic. Next step is proving $(BYZC)$ is cyclic. Take the miquel point of $BMCTPQ$ and call that point $R$. By angle chasing we have $\angle XRT=\angle TRM=90$, so $X - R - M$. Then by PoP $(BYZC)$ is cyclic, then $AX$ is tangent to $(XYZ)$. Since $AX=AQ$, it is enough to prove that $\angle AQZ=\angle ZYQ$(because by proving this, we will prove that $A$ lies on radical axes of circles $(XYZ)$ and $(YZQ)$, which means $A - Y - Z$). Let $PM \cap XT=F$ and $PM \cap CX=G$, then $(PFZX)$ and $(YZQG)$ are cyclic, and rest follows from angle chasing, so we are done:).
This post has been edited 1 time. Last edited by X.Allaberdiyev, Jun 23, 2024, 1:16 PM
Reason: Typo
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Awesome3.14
1733 posts
Awesome3.14
#14 Jul 5, 2024, 8:03 PM • 2 Y
Y by ehuseyinyigit, Rounak_iitr
CyclicISLscelesTrapezoid wrote:
My problem!

Let $\measuredangle$ denote directed angles modulo $180^\circ$.

By Menelaus, we have
\[\frac{BP}{PA} \cdot \frac{AQ}{QC} \cdot \frac{CM}{MB}=1,\]and since $BM=CM$ and $AP=AQ$, this gives $BP=CQ$. If we let $BP=CQ=x$ and $AP=AQ=y$, then we have $x-y=AB$ and $x+y=AC$, so $x=\tfrac{AB+AC}{2}=BC$.

Let $T$ be the reflection of $X$ over $A$. Notice that $APT \sim BPC$ and $AQT \sim CQB$ by SAS, so $\overline{BQ}$ and $\overline{CP}$ intersect at $T$. Let the circumcircles of $BMQ$ and $CMP$ intersect again at $R$.

Claim: $R$ lies on the circle centered at $A$ through $P$, $Q$, $X$, and $T$.
Proof: We have
\[\measuredangle PRQ=\measuredangle PRM+\measuredangle MRQ=\measuredangle PCM+\measuredangle MBQ=\measuredangle CTB=\measuredangle PTQ,\]so $PTQR$ is cyclic, as desired.

Since $\measuredangle BMR=\measuredangle BQR=\measuredangle TQR=\measuredangle TXR$, we obtain that $X$, $R$, and $M$ are collinear.

Claim: $XYRZ$ is cyclic and its circumcircle is tangent to $\overline{AX}$.
Proof: We have
\[\measuredangle XYR=\measuredangle BYR=\measuredangle BMR=\measuredangle AXR,\]so the circumcircle of $XRY$ is tangent to $\overline{AX}$. Analogously, the circumcircle of $XRZ$ is tangent to $\overline{AX}$, so the circle through $X$ and $R$ tangent to $\overline{AX}$ passes through $Y$ and $Z$, as desired.

Let $\infty_{BC}$ be the point at infinity on $\overline{BC}$. We have $(X,R;Y,Z)\overset{X}{=}(\infty_{BC},M;B,C)=-1$, so $XRYZ$ is harmonic. Since $\overline{AX}$ is tangent to its circumcircle, we know that $\overline{AR}$ is tangent as well, so $A$, $Y$, and $Z$ are collinear by the symmedian configuration.

ADMITS
*throws water balloon*
i didnt see anyone throw water balloons at MOP this year, can someone confirm that tiger was hit with a water balloon?
This post has been edited 1 time. Last edited by Awesome3.14, Jul 5, 2024, 8:15 PM
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GrantStar
821 posts
GrantStar
#15 Sep 2, 2024, 10:37 PM
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Define $K$ and $L$ such that
  • $LB=LC$ and $KB=KC$,
  • $A,K,L$ lie on the same side of $BC$,
  • $\angle BLC=\angle ABC$ and $\angle BKC=\angle ACB$.

Claim: $CQ=BC=BP$.
Proof. By menelaus on $ABC$ and $P,Q,M$, \[1=\frac{BM}{MC}\cdot \frac{CQ}{QA}\cdot \frac{AP}{PB}=\frac{CQ}{PB}\]so $CQ=PB=y$ since $BM=MC$, $AP=AQ=x$. Now, $AB=BP-AP=y-x$ and $AC=y+x$ so $AB+AC=2y=2BC$ so $y=BC$. $\blacksquare$

Claim: $K$ lies on $XP, BQ$, and $(PMC)$.
Proof. Since $\angle QBA=90^{\circ} - \angle \frac{\angle C}{2}$ from $CQ=CB$, $K$ lies on $BQ$ as $\angle KBC=90^{\circ} - \frac{\angle C}{2}$. Now, $\angle MQC=\frac{\angle A}{2}$ as $AP=AQ$. Thus $\angle CMP = \angle CMQ = 180^{\circ} - \frac{\angle A}{2}-\angle C$. As $\angle PCM=90^{\circ} - \frac{\angle B}{2}$, \[\angle MPC=180^{\circ} - \angle CMP - \angle PCM = \frac{\angle C}{2}\]But since $\angle MKC = \frac{\angle C}{2}$, $K$ lies on $(CMP)$.
Now, as $A$ is the circumcenter of $XPQ$ and $\angle XAQ=180^{\circ} - \angle C$, we get $\angle XPQ=90^{\circ} - \frac{\angle C}{2}$. But \[\angle MPK=180^{\circ} - \angle KMC = 180 ^{\circ} - \left(90^{\circ} - \frac{\angle C}{2}\right) = 180 ^{\circ} - \angle XPQ,\]so $K$ lies on $XP$. $\blacksquare$

Similar results hold for $L$, so since \[\measuredangle QLK=\measuredangle QLM=\measuredangle QBM=\measuredangle KBC=\measuredangle MCK=\measuredangle MPK=\measuredangle QPK,\]$PKQL$ is cyclic, so by radical axis, $X$ lies on the radical axis of $(PCM)$, $(BMQ)$, $(PKQL)$.

Now, invert at $X$ with radius $\sqrt{\operatorname{pow}_{(PKQL)}X}$ which fixes $(PCM)$, $(BMQ)$, $(PKQL)$. It sends $Y$ to $B$, $Z$ to $C$, and $(XPQ)$ to $KL$, the perpendicular bisector of $BC$. As $A$ is the circumcenter of $XPQ$, $A$ goes to $X'$, the reflection of $X$ over $KL$. Thus $AYZ$ inverts to $XBCX'$, an isosceles trapezoid, so inverting back we conclude.
This post has been edited 1 time. Last edited by GrantStar, Sep 2, 2024, 10:38 PM
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Muaaz.SY
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Muaaz.SY
#16 Nov 9, 2024, 4:41 PM
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Let $E=\overline{XQ}\cap (BMQ)$ , $F=\overline{XP}\cap (CMP)$
note that $\overline{PQ}\parallel \overline{AD}$ where $D$ is the intersection of $\angle BAC$ bisector and $BC$
from $\frac{CQ}{CA}=\frac{CM}{CD}$ we can get $CQ=BC=BP$
some angle chase shows that $M$, $E$, $F$ are collinear, $BYZC$ is cyclic and $\overline{BEF} \perp \overline{BC}$
Now let $R$ be the reflection of $X$ over $\overline {ME}$, abviously $XBCR$ is cyclic.
$\angle QER=\angle XER=2\angle XEF=2\angle QBM=180-\angle QAX$
so $XA.XR=XY.XB$
To finish note that he inversion centered at $X$ with radius $\sqrt{XY.XB}$ sends $(XBCR)$ to a line $\overline{YZA}$ as needed.
This post has been edited 1 time. Last edited by Muaaz.SY, Nov 9, 2024, 4:44 PM
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awesomeming327.
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awesomeming327.
#18 Jan 27, 2025, 5:28 AM
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Claim 1: $BP=BC=QC$.
By Menelaus, we have
\[\frac{AP}{BP}\cdot \frac{BM}{CM}\cdot \frac{CQ}{AQ}=1\]But since $AP=AQ$ and $BM=CM$, we must have $BP=CQ$. Then note that
\[BP+CQ=BA+AP+CA-CQ=BA+CA=2BC\]so our claim is proved.
Let $D$ be the reflection of $X$ across $A$, which is on $(XPQ)$. Then $\triangle PAD$ and $\triangle PBC$ are similar and $AD\parallel BC$ so $D$ lies on $CP$. Similarly, it lies on $BQ$. Then, by Miquel Point on complete quadrilateral $PDCMBQ$: $(BQM)$, $(CMP)$, $(DPQ)$, $(DBC)$ concur at a point, call it $S$. We have
\[\angle SYX=\angle SMB=\angle SZC\]so $(XYZ)$ also passes through $S$.

Claim 2: $BCZY$ cyclic.
Note that since
\[\angle DXS=\angle CPS=\angle BMS\]we have $S$ lies on $XM$. Thus by radical axis we are done.
Claim 3: $AX$ and $AS$ are tangent to $(XYZ)$.
We have $\angle AXZ=\angle XCB=\angle XYZ$, so $AX$ is tangent. Since $AX=AS$, $AS$ is also tangent.
Claim 4: $XYSZ$ is harmonic.
Note that since $\tfrac{XY}{XZ}=\tfrac{XC}{XB}$ it suffices to show that $SZ\cdot CX=SY\cdot BX$. This is clear:
\[SZ\cdot CX=[SXC]\csc(\angle SZX)=[SXB]\csc(\angle SYX)=SY\cdot BX\]because $XS$ is the median and because $\angle SZX$ and $\angle SYX$ are supplements.
Since $XYSZ$ is harmonic, $YZ$ passes through $A$. We are done.
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HoRI_DA_GRe8
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HoRI_DA_GRe8
#20 Apr 10, 2025, 3:00 PM
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It's not all over , we are not rusted to dust :wallbash_red:
ELMO 2024 P5 wrote:
In triangle $ABC$ with $AB<AC$ and $AB+AC=2BC$, let $M$ be the midpoint of $\overline{BC}$. Choose point $P$ on the extension of $\overline{BA}$ past $A$ and point $Q$ on segment $\overline{AC}$ such that $M$ lies on $\overline{PQ}$. Let $X$ be on the opposite side of $\overline{AB}$ from $C$ such that $\overline{AX} \parallel \overline{BC}$ and $AX=AP=AQ$. Let $\overline{BX}$ intersect the circumcircle of $BMQ$ again at $Y \neq B$, and let $\overline{CX}$ intersect the circumcircle of $CMP$ again at $Z \neq C$. Prove that $A$, $Y$, and $Z$ are collinear.

Tiger Zhang

Note that if $I$ is the Incentre ,then $PQ \parallel AI$, using angle bisector theorem and parallel ratios we get $AP=AQ=AX=AX'=c-b$, where $A$ is the midpoint of $XX'$.This also gives $BP=BC=CQ$

Claim : $\overline{B-X'-Q}$ and $\overline{C-X'-P}$
Proof : Note that,
$$\angle BQC=\frac{180^{\circ}-\angle ACB}{2}=90^{\circ}-\frac{\angle QCB}{2}=90^{\circ}-\frac{\angle QAX'}{2}=\angle AX'Q \implies B-X'-Q$$Similarly we also have $C-X'-P$ and hence our claim is proved $\square$

Now using miquel on complete quadrilateral $QX'CM$ we have that $\odot(\triangle BMQ),\odot(\triangle CMP),\odot(PX'QX)$ meet at a certain point.Call it $D$.

Now we observe that ,
$$\angle XDP=\angle XX'P=\angle MCP=180^{\circ}-\angle PDM \implies X \in MD$$From here using power of point gives, $XZ\cdot XC=XD \cdot XM=XY \cdot XB \implies BYZC$ is cyclic.

Claim : $XYDZ$ is cyclic and $AX$ is tangent to the circle.
Proof : We can angle chase both the parts;
$$\angle XYD=\angle BMD=\angle CZD=180^{\circ}-\angle XZD \implies \text{ Part 1 }$$$$\angle AXD=\angle XMB=\angle DMB=\angle XYD \implies \text{ Part 2 } \square $$Note that since $AX=AD$ ($A$ is the centre of $(PX'QDX)$) , we get that $AD$ is tangent to $(XYDZ)$ . So it suffices to prove that the quadrilateral $XYDZ$ is harmonic. That directly follows from ,
$$(Y,Z;X,D) \stackrel{X}=(B,C;M, \infty_{BC})=-1 \text{ } \blacksquare$$
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MathLuis
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MathLuis
#21 May 1, 2025, 7:05 PM
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Let $H$ the orthocenter of $\triangle BIC$ where $I$ is the incenter of $\triangle ABC$, let $HI \cap BC=D$ and let $D'$ reflection of $D$ over $I$, redefine $IM \cap AH=X$, also let altitude from $A$ to $BC$ hit $IM, BC$ at $G, L$ while letting $AI \cap BC=K$ and also let $AD' \cap BC=T$, and let $I_A$ the A-excenter.
Claim 1: $AH \parallel BC$.
Proof: First notice that from homothety $I_AT \perp BC$ so $-1=(A, K; I, I_A) \overset{\infty_{BC}}{=} (L, K; D, T)$ but we also have that $\frac{LD}{DK}=\frac{AI}{IK}=2$ so from the cross ratio we have $LK=KT$ thus from homothety also trivially notice $IM \parallel AT$ so $AGID'$ is a parallelogram where $AK$ bisects $GD'$ too which means that $GD' \parallel BC$ and thus from parallelograms we have $LD=GD'=TM$ and thus $DK=KM$ which gives that $MD' \parallel AI$ also remember it is well known that $ID, EF, AM$ are concurren at $J$ (you can drop parallel from $J$ to $BC$ and angle chase to win) and in addition since we now have $AD'MI$ is a parallelogram it happens that $J$ is the intersection of its diagonals and thus $AJ=JM$ and $IJ=JD$ however this means that $J$ lies on the A-midbase which from Iran Lemma spam is well-known to be the polar of $H$ w.r.t. incircle and we are done as by La'Hire it means $AH$ is polar of $J$ w.r.t. incircle and as seen to lie on $ID$ you can conclude $AH \perp ID$ so $AH \parallel BC$ as desired.
Claim 2: $BH \cap AC=Q$ and $CH \cap AB=P$.
Proof: Define those points as seen above, then it is clear that $BP=BC=CQ$ by reflections and however from thales we can also have $AP=AQ=AH$ and now to finish you simply throw menelaus to see that $P,Q,M$ are colinear and in fact $D'$ lies on this line too as seen above.
The finish: Now just note that since $DK=KM$ from thales we have $XA=AH$ so $X$ is also the one from the problem statement and now if you let $N$ to be the H-queue point of $\triangle BHC$ then as $\angle XNH=90$ we have $AN=AH=AX$ too but also notice that $N$ is miquelpoint of $BPQC$ as a result and thus it lies on both $(CMP), (BMQ)$ and also on $IM$ too.
So now just notice from Miquelpoint theorem and PoP that $BYNM, MNZC, BYZC, XYNZ$ are all cyclic so we also have that $AX$ is tangent to $(XYNZ)$ but also $-1=(B, C: M, \infty_{BC}) \overset{X}{=} (Y, Z; N, X)$ which shows that not only $AN$ is tangent to $(XYNZ)$ it now also with this shows that $Y,Z,A$ are colinear as desired thus we are done :cool:.
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ihatemath123
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ihatemath123
#22 Wednesday at 2:12 PM
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Nice problem :love:

By Ceva's theorem, we have $PB = BC = CQ$ (see 2022 AIME I P14).

Let $R$ be the intersection of lines $BQ$ and $CP$equivalently, $R$ is the orthocenter of $\triangle BIC$. By angle chasing, $R$ lies on $(PQX)$. Let $W$ be the second intersection of $(MBQ)$ and $(MCP)$, so $W$ is the Miquel point of $PQBC$. In particular, $W$ lies on $(PQX)$ and $(BRC)$.

Claim: $W$ is the $R$-queue point in $\triangle RBC$.
Proof: Let $Q'$ and $P'$ be the midpoint of $\overline{BQ}$ and $\overline{CP}$, respectively. Then, since $W$ is the Miquel point of quadrilateral $PQBC$, it is also the Miquel point of quadrilateral $P'Q'BC$. But $P'$ and $Q'$ are the feet from $B$ and $C$ to opposite sides in $\triangle RBC$, so by definition $W$ is the $R$-queue point.

Claim: Points $W$, $X$ and $M$ are collinear.
Proof: From the above claim, it follows that $W$, $I$ and $M$ are collinear. So, it suffices to show that $M$, $I$ and $X$ are collinear. Let $N$ be the circumcenter of $\triangle BIC$. Point $R$ lies on line $AX$ because $IR = 2MN$ and then some dumb $AB + AC = 2BC$ stuff. So, $R$ and $X$ are reflections about $A$. Some dumb mass point stuff probably finishes.

Claim: We have that $(XYZ)$ is tangent to $\overline{AX}$.
Proof: We have $\measuredangle XYZ = \measuredangle BCX = \measuredangle AXZ$.

Point $W$ lies on $(XYZ)$ by Miquel's theorem on $\triangle XBC$. Projecting $BMC \infty$ through $X$ onto $(XYZ)$ gives us that $XYWZ$ is harmonic. Since $\overline{XA}$ is tangent to $(XYZ)$ and $AX = AW$, it follows that $\overline{WA}$ is also tangent to $(XYZ)$. The collinearity follows.

remark
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