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k a May Highlights and 2025 AoPS Online Class Information
jlacosta   0
Thursday at 11:16 PM
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.

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0 replies
jlacosta
Thursday at 11:16 PM
0 replies
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A folklore polynomial game
Assassino9931   1
N 15 minutes ago by YaoAOPS
Source: RMM Shortlist 2024 A1, also Bulgaria Regional Round 2016, Grade 12
Fix a positive integer $d$. Yael and Ziad play a game as follows, involving a monic polynomial of degree $2d$. With Yael going first, they take turns to choose a strictly positive real number as the value of one of the coecients of the polynomial. Once a coefficient is assigned a value, it cannot be chosen again later in the game. So the game
lasts for $2d$ rounds, until Ziad assigns the final coefficient. Yael wins if $P(x) = 0$ for some real
number $x$. Otherwise, Ziad wins. Decide who has the winning strategy.
1 reply
Assassino9931
an hour ago
YaoAOPS
15 minutes ago
J
H
Very easy case of a folklore polynomial equation
Assassino9931   0
18 minutes ago
Source: Bulgaria EGMO TST 2025 P6
Determine all polynomials $P(x)$ of odd degree with real coefficients such that $P(x^2 + 2025) = P(x)^2 + 2025$.
0 replies
Assassino9931
18 minutes ago
0 replies
J
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Game on board with gcd and lcm
Assassino9931   0
20 minutes ago
Source: Bulgaria EGMO TST 2025 P3
On the board are written $n \geq 2$ positive integers with least common multiple $K$ and greatest common divisor $1$. It is known that $K$ is not a perfect square and is not among the initially written numbers. Two players $A$ and $B$ play the following game, taking turns alternatingly, with $A$ starting first. In a move the player has to write a number which has not been written so far, by taking two distinct integers $a$ and $b$ from the board and write LCM$(a,b)$ or LCM$(a,b)$/$a$. The player who writes $1$ or $K$ loses. Who has a winning strategy?
0 replies
Assassino9931
20 minutes ago
0 replies
J
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Estimate on number of progressions
Assassino9931   0
an hour ago
Source: RMM Shortlist 2024 C4
Let $n$ be a positive integer. For a set $S$ of $n$ real numbers, let $f(S)$ denote the number of increasing arithmetic progressions of length at least two all of whose terms are in $S$. Prove that, if $S$ is a set of $n$ real numbers, then
\[ f(S) \leq \frac{n^2}{4} + f(\{1,2,\ldots,n\})\]
0 replies
Assassino9931
an hour ago
0 replies
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No more topics!
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Concurrency
Dadgarnia   27
N Apr 23, 2025 by zuat.e
Source: Iranian TST 2020, second exam day 2, problem 4
Let $ABC$ be an isosceles triangle ($AB=AC$) with incenter $I$. Circle $\omega$ passes through $C$ and $I$ and is tangent to $AI$. $\omega$ intersects $AC$ and circumcircle of $ABC$ at $Q$ and $D$, respectively. Let $M$ be the midpoint of $AB$ and $N$ be the midpoint of $CQ$. Prove that $AD$, $MN$ and $BC$ are concurrent.

Proposed by Alireza Dadgarnia
27 replies
Dadgarnia
Mar 12, 2020
zuat.e
Apr 23, 2025
J
Concurrency
G H J
Reveal topic tags
geometry
incenter
circumcircle
Harmonics
homothety
Hi
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G H BBookmark kLocked kLocked NReply
Source: Iranian TST 2020, second exam day 2, problem 4
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Dadgarnia
164 posts
Dadgarnia
#1 Mar 12, 2020, 10:54 AM • 7 Y
Y by Purple_Planet, itslumi, jhu08, mathematicsy, Mango247, Mango247, ItsBesi
Let $ABC$ be an isosceles triangle ($AB=AC$) with incenter $I$. Circle $\omega$ passes through $C$ and $I$ and is tangent to $AI$. $\omega$ intersects $AC$ and circumcircle of $ABC$ at $Q$ and $D$, respectively. Let $M$ be the midpoint of $AB$ and $N$ be the midpoint of $CQ$. Prove that $AD$, $MN$ and $BC$ are concurrent.

Proposed by Alireza Dadgarnia
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GeoMetrix
924 posts
GeoMetrix
#5 Mar 12, 2020, 12:28 PM • 8 Y
Y by mueller.25, amar_04, Mathasocean, Purple_Planet, agwwtl03, IFA, jhu08, sabkx
Nice and easy.
Define $\omega=\odot(CIQ)$ and let $H=\omega \cap \overline{BC}$. Observe that trivially we have that $N \in \overline{AC}$ (just consider the line through $I$ parallel to $BC$). Now since $$\angle NCH=\angle NHC=\angle ABC$$$\implies$ $\overline{NH} \| \overline{AB}$ . Hence by the converse of ceva's theorem we have that $\overline{AH},\overline{BN},\overline{CM}$ are concurrent. Now define $K= \overline{AD} \cap \overline{BC}$ . Observe that to show that $K \in \overline{MN}$ we need to show that $(B,C;H,K)=-1$. But if $\overline{DH} \cap \omega=J$ then we have that $(B,C;H,K)\overset{D}{=}(A,J;B,C)$. Hence we just need to show that $(AJBC)$ is harmonic. For this notice that by reims theorem we have that $\overline{AJ} \| \overline{QH}$. But as $\angle QHC=90^\circ$ we have that $\overline{AJ} \perp \overline{BC}$ by which we have that $J$ is the midpoint of minor $\widehat{BC}$. Done $\blacksquare$.

[asy] /* Geogebra to Asymptote conversion, documentation at artofproblemsolving.com/Wiki go to User:Azjps/geogebra */ import graph; size(14cm); 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 = -10.006881897432205, xmax = 25.634412731501875, ymin = -8.577795838543958, ymax = 14.83226710342647; /* image dimensions */ pen ffqqff = rgb(1,0,1); pen wvvxds = rgb(0.396078431372549,0.3411764705882353,0.8235294117647058); pen dtsfsf = rgb(0.8274509803921568,0.1843137254901961,0.1843137254901961); pen qqffff = rgb(0,1,1); pen wrwrwr = rgb(0.3803921568627451,0.3803921568627451,0.3803921568627451); /* draw figures */ draw((1.5534973808986277,9.160392608982256)--(-3.5857910956748746,-1.8868970241407366), linewidth(0.8)); draw((1.5534973808986277,9.160392608982256)--(7.796798634472622,-1.3026893337662244), linewidth(0.8)); draw((-3.5857910956748746,-1.8868970241407366)--(7.796798634472622,-1.3026893337662244), linewidth(0.8)); draw((1.5534973808986277,9.160392608982256)--(1.9295955015644004,1.832569513956508), linewidth(0.4) + ffqqff); draw(circle((5.807241390273251,2.031588419358404), 3.8827498197705226), linewidth(0.4) + wvvxds); draw(circle((1.9067865071150452,2.276975553541132), 6.892477317034895), linewidth(0.4) + dtsfsf); draw(circle((3.5081332893469326,4.891548128823499), 4.6950649335634775), linewidth(0.4) + wvvxds); draw((8.19899262334367,5.090227365365952)--(5.807241390273251,2.031588419358404), linewidth(0.4) + qqffff); draw((3.8176841460738786,5.365866172483034)--(8.19899262334367,5.090227365365952), linewidth(0.4) + qqffff); draw((8.19899262334367,5.090227365365952)--(7.796798634472622,-1.3026893337662244), linewidth(0.4) + wrwrwr); draw((3.8176841460738786,5.365866172483034)--(1.9295955015644004,1.832569513956508), linewidth(0.4) + ffqqff); draw((1.9295955015644004,1.832569513956508)--(7.796798634472622,-1.3026893337662244), linewidth(0.4) + qqffff); draw((3.8176841460738786,5.365866172483034)--(4.169500681742824,-1.488859213336944), linewidth(0.4) + qqffff); draw((5.807241390273251,2.031588419358404)--(4.169500681742824,-1.488859213336944), linewidth(0.4) + qqffff); draw((1.9295955015644004,1.832569513956508)--(2.2600756333314593,-4.606441501899994), linewidth(0.4) + ffqqff); draw((2.2600756333314593,-4.606441501899994)--(8.19899262334367,5.090227365365952), linewidth(0.4) + green); draw((-1.0161468573881236,3.63674779242076)--(17.798762343332783,-0.7893418218123583), linewidth(0.4) + linetype("4 4") + blue); draw((1.5534973808986277,9.160392608982256)--(17.798762343332783,-0.7893418218123583), linewidth(0.4) + linetype("4 4") + blue); draw((1.9295955015644004,1.832569513956508)--(5.807241390273251,2.031588419358404), linewidth(0.4) + wrwrwr); draw((7.796798634472622,-1.3026893337662244)--(17.798762343332783,-0.7893418218123583), linewidth(0.4) + linetype("4 4") + blue); /* dots and labels */ dot((1.5534973808986277,9.160392608982256),dotstyle); label("$A$", (1.6396828828887742,9.383171533517269), NE * labelscalefactor); dot((-3.5857910956748746,-1.8868970241407366),dotstyle); label("$B$", (-3.4819992193005715,-1.6553396638953617), NE * labelscalefactor); dot((7.796798634472622,-1.3026893337662244),dotstyle); label("$C$", (7.88392544583195,-1.0706727572527435), NE * labelscalefactor); dot((1.9295955015644004,1.832569513956508),linewidth(4pt) + dotstyle); label("$I$", (2.0138697031400508,2.01636850982028), NE * labelscalefactor); dot((5.807241390273251,2.031588419358404),linewidth(4pt) + dotstyle); label("$N$", (5.896057963247044,2.2268485962116227), NE * labelscalefactor); dot((3.8176841460738786,5.365866172483034),linewidth(4pt) + dotstyle); label("$Q$", (3.9081904806621375,5.547756625941694), NE * labelscalefactor); dot((8.19899262334367,5.090227365365952),linewidth(4pt) + dotstyle); label("D", (8.28149894234893,5.267116510753237), NE * labelscalefactor); dot((-1.0161468573881236,3.63674779242076),linewidth(4pt) + dotstyle); label("$M$", (-0.9328515063387511,3.8171425822795437), NE * labelscalefactor); dot((17.798762343332783,-0.7893418218123583),linewidth(4pt) + dotstyle); label("Q", (17.893422887553594,-0.602939231938649), NE * labelscalefactor); dot((4.675148007685625,3.928851637608016),linewidth(4pt) + dotstyle); label("$F$", (4.773497502493214,4.121169373733705), NE * labelscalefactor); dot((4.169500681742824,-1.488859213336944),linewidth(4pt) + dotstyle); label("$H$", (4.258990624647709,-1.3045395199097907), NE * labelscalefactor); dot((2.2600756333314593,-4.606441501899994),linewidth(4pt) + dotstyle); label("$J$", (2.3646698471256222,-4.414967463248519), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]
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Mathematicsislovely
245 posts
Mathematicsislovely
#7 Mar 26, 2020, 9:56 PM • 3 Y
Y by Purple_Planet, jhu08, PRMOisTheHardestExam
CLAIM: $N$ is the centre of $\omega=\odot(CIQ)$.
Proof: If $N'$ is the centre of $\omega$ then $N'C=N'I$ and $\angle N'IA=90^\circ$ implies $N'I$ and $BC$ are parallel .Let $IN'$ cut $AC$ at $N''$.Then $$\angle N''IC=\angle ICB=\angle ICN''$$.It means $N''C=N''I$.So $N''\equiv N'$.Now the circle centre at $N''$ and with radius $N''C=N''I$ is the unique circle tangent to $AI$ at $I$.So $N''=N$..
$\square$

Now let $\omega=\odot(CIQ)$ cut $BC$ at $X$ then $NX=NC$ implies $\angle NXH=\angle NXC=\angle ABC$ so $NX$ and $AB$ are parallel.So the line joining $C$ and the intersection of $BN$ and $AX$ passes through midpoint of $AB$.In other words $AX$,$BN$,$CM$ are concurrent at a point.So let $F$ is the intersection of $MN$ and $BC$.So $(B,C;X,F)=-1$ and let M be the midpoint of $BC$.Then $FC.FB=FX.FM$ [since $F$ is the inverse image of $X$ w.r.t circle with diameter $BC$].

Now assume $Y= XN \cap AD$.We claim that $XYDC$ is cyclic.Indeed, as $XN$ and $AB$ are parallels so $\angle XYD=\angle BAD=180^\circ-\angle XCD$.
Now as $XY$ passes through center $N$ of $omega=\odot(CIQ)$ so $\angle ADX=\angle XDY=90^\circ$ and together with $\angle AMXY=90^\circ$ We get $AMXD$ is cyclic.
Let $F'= BC\cap AD$.So $F'D.F'A=F'C.F'B$ and $F'D.F'A=F'X.F'M$. So we have $F'C.F'B=F'X.F'M$.But we have previously proved that $FC.FB=FX.FM$ so $F \equiv F'$. So $BC,AD,MN$ concur at a point $F$.
This post has been edited 1 time. Last edited by Mathematicsislovely, Mar 26, 2020, 9:58 PM
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AlastorMoody
2125 posts
AlastorMoody
#8 Apr 12, 2020, 8:48 AM • 7 Y
Y by GeoMetrix, Purple_Planet, SenatorPauline, Aryan-23, Muaaz.SY, jhu08, PRMOisTheHardestExam
Solution
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Aryan-23
558 posts
Aryan-23
#9 Jun 30, 2020, 12:24 PM • 5 Y
Y by AlastorMoody, Siddharth03, Muaaz.SY, jhu08, PRMOisTheHardestExam
Solution
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AwesomeYRY
579 posts
AwesomeYRY
#10 May 17, 2021, 8:37 PM • 2 Y
Y by jhu08, PRMOisTheHardestExam
Claim: N is the circumcenter of (CIQ)
Proof:
Note that $IN\perp, AI, BC\perp AI \Longrightarrow NI\parallel BC$. Thus, \[\angle NIC = \angle BCI = \angle ICA = \angle ICN\]Thus, $NI=NC$, so the circle with center $N$ and radius $NI$ is both tangent to $AI$ at $I$ and passes through $C$, so we have sufficiently redefined $\omega$. $\square$

Now, define $X=\omega \cap BC$ and $Y=\omega \cap AD$

Claim 1: $NX\parallel AB$
This clearly follows from
\[\angle CNX = \angle NCX = \angle ACB=\angle ABC\]$\square$

Claim 2: $XY\parallel AB$
We angle chase (basically a rederivation of Reim's)
\[\angle DAB = \angle DCB = \angle DCX = \angle DYX\]$\square$

Combining these, we have that $N,X,Y$ are collinear. Since, $X,Y\in \omega$ and $N$ is the center of $\omega$, we have that $N$ is the midpoint of $XY$. Since $M$ is the midpoint of $AB$, combined with $YX\parallel AB$, we have that $AY,MN,BX$ are concurrent which finishes $\blacksquare$
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SatisfiedMagma
458 posts
SatisfiedMagma
#11 Aug 13, 2021, 3:04 PM • 2 Y
Y by jhu08, PRMOisTheHardestExam
[asy] /* Geogebra to Asymptote conversion, documentation at artofproblemsolving.com/Wiki go to User:Azjps/geogebra */ import graph; size(15.929898374381239cm); 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 = 1.7630505196437911, xmax = 17.69294889402503, ymin = -4.7304, ymax = 4.139286318662105; /* image dimensions */ pen ffxfqq = rgb(1.,0.4980392156862745,0.); pen xfqqff = rgb(0.4980392156862745,0.,1.); pen ffqqff = rgb(1.,0.,1.); pen qqwuqq = rgb(0.,0.39215686274509803,0.); filldraw((6.775903779376068,3.721548042371603)--(3.38614791445706,-2.12)--(9.796305353838916,-2.3192551065540985)--cycle, invisible, linewidth(1.) + blue); filldraw((6.944386092416243,-0.3160792577621652)--(6.9535157076039695,-0.022374008615092755)--(6.659810458456897,-0.013244393427366385)--(6.65068084326917,-0.30694964257443885)--cycle, invisible, linewidth(1) + qqwuqq); filldraw((6.884931883295061,-2.2287571684647753)--(6.894061498482787,-1.935051919317703)--(6.600356249335714,-1.9259223041299767)--(6.591226634147988,-2.219627553277049)--cycle, invisible, linewidth(0.4) + qqwuqq); filldraw((9.62150852293415,1.5152303300388892)--(9.612378907746429,1.2215250808918166)--(9.9060841568935,1.2123954657040958)--(9.915213772081222,1.5061007148511685)--cycle, invisible, linewidth(0.4) + qqwuqq); filldraw((8.026350584687354,-2.264237343034512)--(8.03548019987508,-1.9705320938874396)--(7.741774950728007,-1.9614024786997133)--(7.732645335540281,-2.2551077278467857)--cycle, invisible, linewidth(0.4) + qqwuqq); /* draw figures */ draw(circle((6.656692229708716,-0.11355970054063641), 3.8369600979576926), linewidth(0.4) + ffxfqq); draw((6.775903779376068,3.721548042371603)--(3.38614791445706,-2.12), linewidth(0.4) + blue); draw((3.38614791445706,-2.12)--(9.796305353838916,-2.3192551065540985), linewidth(0.4) + blue); draw((9.796305353838916,-2.3192551065540985)--(6.775903779376068,3.721548042371603), linewidth(0.4) + blue); draw((6.65068084326917,-0.30694964257443885)--(9.796305353838916,-2.3192551065540985), linewidth(0.4)); draw((6.775903779376068,3.721548042371603)--(6.591226634147988,-2.219627553277049), linewidth(0.4)); draw(circle((8.823929553810784,-0.37450350649783165), 2.1742983885386487), linewidth(0.4) + red); draw((8.823929553810784,-0.37450350649783165)--(6.65068084326917,-0.30694964257443885), linewidth(0.4)); draw((7.85155375378265,1.5702480935584389)--(7.732645335540281,-2.2551077278467857), linewidth(0.4) + green); draw((10.230134161477556,1.2838577580577875)--(9.796305353838916,-2.3192551065540985), linewidth(0.4)); draw((7.732645335540281,-2.2551077278467857)--(10.230134161477556,1.2838577580577875), linewidth(0.4)); draw((7.85155375378265,1.5702480935584389)--(10.230134161477556,1.2838577580577875), linewidth(0.4)); draw((6.65068084326917,-0.30694964257443885)--(10.230134161477556,1.2838577580577875), linewidth(0.4)); draw((6.65068084326917,-0.30694964257443885)--(7.85155375378265,1.5702480935584389), linewidth(0.4) + xfqqff); draw((6.65068084326917,-0.30694964257443885)--(7.732645335540281,-2.2551077278467857), linewidth(0.4) + xfqqff); draw((6.537480680041361,-3.9486674434528757)--(7.732645335540281,-2.2551077278467857), linewidth(0.4)); draw((6.537480680041361,-3.9486674434528757)--(6.591226634147988,-2.219627553277049), linewidth(0.4)); draw((9.915213772081222,1.5061007148511685)--(7.85155375378265,1.5702480935584389), linewidth(0.4) + blue); draw((9.915213772081222,1.5061007148511685)--(9.796305353838916,-2.3192551065540985), linewidth(0.4) + green); draw((7.732645335540281,-2.2551077278467857)--(9.915213772081222,1.5061007148511685), linewidth(0.4) + blue); draw(circle((7.254274557458178,0.7332201572624102), 3.026374423339594), linewidth(0.4) + ffqqff); draw((5.081025846916564,0.8007740211858014)--(15.591017496944685,-2.4993795413193407), linewidth(0.4) + linetype("4 4") + blue); draw((6.775903779376068,3.721548042371603)--(15.591017496944685,-2.4993795413193407), linewidth(0.4) + blue); draw((9.796305353838916,-2.3192551065540985)--(15.591017496944685,-2.4993795413193407), linewidth(0.4) + blue); /* dots and labels */ dot((6.775903779376068,3.721548042371603),dotstyle); label("$A$", (6.832913828359907,3.862244607803299), NE * labelscalefactor); dot((3.38614791445706,-2.12),dotstyle); label("$B$", (2.98,-2.3434897154339724), NE * labelscalefactor); dot((9.796305353838916,-2.3192551065540985),dotstyle); label("$C$", (9.880372647806754,-2.620531426292779), NE * labelscalefactor); dot((6.65068084326917,-0.30694964257443885),linewidth(4.pt) + dotstyle); label("$I$", (6.445055433157582,-0.3349373117076234), NE * labelscalefactor); dot((6.591226634147988,-2.219627553277049),linewidth(4.pt) + dotstyle); label("$X$", (6.261,-2.5097147419492565), NE * labelscalefactor); dot((5.081025846916564,0.8007740211858014),linewidth(4.pt) + dotstyle); label("$M$", (4.693,0.8978983016140666), NE * labelscalefactor); dot((8.823929553810784,-0.37450350649783165),linewidth(4.pt) + dotstyle); label("$N$", (8.744501633285656,-0.08559977193469738), NE * labelscalefactor); dot((10.230134161477556,1.2838577580577875),linewidth(4.pt) + dotstyle); label("$D$", (10.282083128552019,1.3965733811599186), NE * labelscalefactor); dot((7.85155375378265,1.5702480935584389),linewidth(4.pt) + dotstyle); label("$Q$", (7.8441160729945425,1.7567276052763674), NE * labelscalefactor); dot((7.732645335540281,-2.2551077278467857),linewidth(4.pt) + dotstyle); label("$K$", (7.705595217565141,-2.5651230841210175), NE * labelscalefactor); dot((9.915213772081222,1.5061007148511685),linewidth(4.pt) + dotstyle); label("$E$", (9.77,1.618206749846964), NE * labelscalefactor); dot((6.537480680041361,-3.9486674434528757),linewidth(4.pt) + dotstyle); label("$F$", (6.33423874881406,-4.28), NE * labelscalefactor); dot((15.591017496944685,-2.4993795413193407),linewidth(4.pt) + dotstyle); label("$G$", (15.64284023366988,-2.3850459720627932), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]
Remarks
Attachments:
This post has been edited 1 time. Last edited by SatisfiedMagma, Aug 13, 2021, 3:06 PM
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MrOreoJuice
594 posts
MrOreoJuice
#12 Aug 13, 2021, 4:35 PM • 4 Y
Y by jhu08, SatisfiedMagma, PRMOisTheHardestExam, vrondoS
$\angle QIA = \angle QCI = \angle ICB = 90^\circ - \angle (IC , \text{angle bisector}) \implies \angle QIC = 90^\circ \implies N$ is the circumcenter of $\omega$.
Let $E=BC \cap \omega$ and $F=AD \cap \omega$.
$$\angle FEC = 180^\circ - \angle FDC = \angle ABC = \angle NCE = \angle NEC$$Thus $\overline{E-N-F}$ are collinear also $EF \parallel AB$ so by homothety we are done.
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srisainandan6
2811 posts
srisainandan6
#13 Sep 25, 2021, 5:05 PM • 2 Y
Y by PRMOisTheHardestExam, jhu08
To begin, note that it is easy to see that $N$ is the circumcenter of $\omega$ as $\triangle NIC$ is isosceles.

Denote $X= BC \cap AD$. We desire to show that $M,N,X$ are collinear. Denote $E = \omega \cap AD$ and $F = \omega \cap BC$. By Reim's Theorem, we get that $EF \parallel AB$. To finish, take a homotethy centered at $X$ that maps $\triangle XEF$ to $\triangle XAB$ which yields $X,N,M$ collinear. $\blacksquare$
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RM1729
63 posts
RM1729
#14 Nov 9, 2021, 6:13 PM • 2 Y
Y by PRMOisTheHardestExam, jhu08
Consider $P$ as $AI \cap BC$.

Claim
$N$ is the centre of the circle $\omega$


Proof
We angle chase.

Note that since $ \angle IQC = \angle PIC = 90^{\circ} - \angle ICP = 90^{\circ} - \angle C/2 $ and $\angle QCI = \angle C/2$

We have that $\angle QIC = 90^{\circ}$ and thus $QC$ is a diameter

But since $N$ is the midpoint of $QC$ it must be the centre of the circle



We now define $X$ as $AD\cap \omega (\neq D)$ and $Y$ as $BC\cap \omega (\neq C)$

Note that $\angle NXC = \angle NCX$ but $\angle NCX = \angle ABC$ since the triangle is isosceles. Thus $\angle NXC = \angle ABC$ and so $NX||AB$

However we also have that $XY||AB$ by Reim's Theorem. Combining these we have that $ABXY$ is a trapezium and $M$ and $N$ are the midpoints of its parallel sides. A simple homothety argument proves that $AY, BX,MN$ that is $AD,BC,MN$ are concurrent.
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mohamad021
1 post
mohamad021
#15 Dec 6, 2021, 5:30 AM • 1 Y
Y by jhu08
srisainandan6 wrote:
To begin, note that it is easy to see that $N$ is the circumcenter of $\omega$ as $\triangle NIC$ is isosceles.

Denote $X= BC \cap AD$. We desire to show that $M,N,X$ are collinear. Denote $E = \omega \cap AD$ and $F = \omega \cap BC$. By Reim's Theorem, we get that $EF \parallel AB$. To finish, take a homotethy centered at $X$ that maps $\triangle XEF$ to $\triangle XAB$ which yields $X,N,M$ collinear. $\blacksquare$

Can you explain Reim's theorem please?
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DottedCaculator
7345 posts
DottedCaculator
#16 Dec 23, 2021, 3:34 PM
Y by
Solution
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guptaamitu1
656 posts
guptaamitu1
#17 Feb 14, 2022, 4:19 PM • 2 Y
Y by PRMOisTheHardestExam, Lantien.C
Here's a solution with radical axes ($\overline{MN}$ will become radical axes of two circles)
Let $\Omega = \odot(ABC)$ and $A',C'$ be antipode of $A,C$ wrt $\Omega$. $\angle QIC = \angle AIC - \angle ACI = 90^\circ$. Thus $\overline{QC}$ is a diameter of $\omega$, consequently $N$ is its center. So $\overline{CO},\overline{QD}$ intersect at $C'$. Let $T = \overline{AD} \cap \overline{BC}$, $\Gamma = \odot(BIC)$ and $X$ be a point of $\overline{AC}$ such that $\overline{QD}$ bisects $\angle ADX$, let $\gamma = \odot(AXD)$. hand drawn figure
[asy] size(250); pair A=dir(90),B=dir(-130),C=dir(-50),O=(0,0),I=incenter(A,B,C),N=extension(A,C,I,I+C-B),Q=2*N-C,Cp=-C,D=foot(C,Cp,Q),T=extension(A,D,B,C),M=1/2*(A+B),Ap=-A,X=foot(I,A,C); draw(unitcircle^^circumcircle(C,I,Q),cyan); draw(CP(circumcenter(A,X,D),X,-210,-60 ),purple); draw(CP(Ap,I,-10,190 ),purple); dot("$A$",A,dir(110)); dot("$B$",B,dir(B)); dot("$C$",C,dir(C)); dot("$O$",O,dir(0)); dot("$I$",I,dir(130)); dot("$N$",N,dir(-120)); dot("$Q$",Q,dir(50)); dot("$C'$",Cp,dir(Cp)); dot("$D$",D,dir(D)); dot("$M$",M,dir(M)); dot("$T$",T,dir(T)); dot("$A'$",Ap,dir(Ap)); dot("$X$",X,dir(50)); draw(C--A--B--T^^A--Ap,red); draw(M--T,purple); draw(T--A^^Cp--D--X,green); draw(C--Cp,green); [/asy]
Claim: Points $M,N,T$ lie on radical axes $\ell$ of $\Gamma,\gamma$.
Proof: $T \in \ell$ is direct. For $M$: Note $\Gamma$ is tangent to $\overline{BC}$ as it has center $A'$. Note $$\angle OAC = \angle OCA = \angle C'CA = \angle C'DA = \angle QDA$$As $\angle BAC = 2 \angle OAC = 2 \angle QDA = \angle XDA$, so $\gamma$ is tangent to $\overline{AB}$. Hence power of $M$ wrt both $\Gamma,\gamma$ equals $MB^2 = MA^2$. For $N$: We will mostly focus of $\triangle ADX$. Observe
$$ \angle NDX = \angle NDQ - \angle XDQ = \angle NQD - \angle ADQ = \angle QAD = \angle NAD $$So $\overline{ND}$ is tangent to $\gamma$ (experts may also directly note that $N$ is the center of $D$-appolonius circle wrt $\triangle ADX$). Hence $NX \cdot NA = ND^2 = NC^2$. Laslty, recall $\overline{NC}$ is tangent to $\Gamma$ (as $A'$ is its center). This proves our Claim. $\square$

It follows points $M, N,T$ are collinear, solving our problem. $\blacksquare$

Motivation
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BarisKoyuncu
577 posts
BarisKoyuncu
#18 Mar 7, 2022, 8:24 AM • 1 Y
Y by teomihai
Simple angle chasing gives us that $N$ is the center of $(IDC)$.
Let $AD\cap BC=S$. We have
$$\angle ASC=\angle ACB-\angle CAD=\angle ABC-\angle CAD=\angle ACD$$Hence, $NC$ is tangent to $(DCS)$. Since $|NC|=|ND|$, we know that $ND$ is tangent to $(DCS)$ as well. Then, $SN$ is symmedian in $DSC$. Since $DC$ and $AB$ are antiparallels wrt $DSC$, we find that $SN$ bisects $AB$, done.
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BarisKoyuncu
577 posts
BarisKoyuncu
#19 Mar 7, 2022, 8:36 AM
Y by
A kind of generalization
This post has been edited 1 time. Last edited by BarisKoyuncu, Mar 7, 2022, 8:36 AM
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JAnatolGT_00
559 posts
JAnatolGT_00
#20 Mar 7, 2022, 10:27 AM • 1 Y
Y by MrOreoJuice
BarisKoyuncu wrote:
A kind of generalization

Proof. All angles are oriented. From $\angle ADB=\angle ACB=\angle CBA=\angle SBA$ we obtain $$\angle CDN=\angle NCD=\angle ABD=\angle CBS.$$Therefore $SN$ is a symmedian in $CDS$ and so bisects $AB.$
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dusicheng20080513
36 posts
dusicheng20080513
#21 Mar 7, 2022, 11:09 AM
Y by
GeoMetrix wrote:
Nice and easy.
Define $\omega=\odot(CIQ)$ and let $H=\omega \cap \overline{BC}$. Observe that trivially we have that $N \in \overline{AC}$ (just consider the line through $I$ parallel to $BC$). Now since $$\angle NCH=\angle NHC=\angle ABC$$$\implies$ $\overline{NH} \| \overline{AB}$ . Hence by the converse of ceva's theorem we have that $\overline{AH},\overline{BN},\overline{CM}$ are concurrent. Now define $K= \overline{AD} \cap \overline{BC}$ . Observe that to show that $K \in \overline{MN}$ we need to show that $(B,C;H,K)=-1$. But if $\overline{DH} \cap \omega=J$ then we have that $(B,C;H,K)\overset{D}{=}(A,J;B,C)$. Hence we just need to show that $(AJBC)$ is harmonic. For this notice that by reims theorem we have that $\overline{AJ} \| \overline{QH}$. But as $\angle QHC=90^\circ$ we have that $\overline{AJ} \perp \overline{BC}$ by which we have that $J$ is the midpoint of minor $\widehat{BC}$. Done $\blacksquare$.

[asy] /* Geogebra to Asymptote conversion, documentation at artofproblemsolving.com/Wiki go to User:Azjps/geogebra */ import graph; size(14cm); 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 = -10.006881897432205, xmax = 25.634412731501875, ymin = -8.577795838543958, ymax = 14.83226710342647; /* image dimensions */ pen ffqqff = rgb(1,0,1); pen wvvxds = rgb(0.396078431372549,0.3411764705882353,0.8235294117647058); pen dtsfsf = rgb(0.8274509803921568,0.1843137254901961,0.1843137254901961); pen qqffff = rgb(0,1,1); pen wrwrwr = rgb(0.3803921568627451,0.3803921568627451,0.3803921568627451); /* draw figures */ draw((1.5534973808986277,9.160392608982256)--(-3.5857910956748746,-1.8868970241407366), linewidth(0.8)); draw((1.5534973808986277,9.160392608982256)--(7.796798634472622,-1.3026893337662244), linewidth(0.8)); draw((-3.5857910956748746,-1.8868970241407366)--(7.796798634472622,-1.3026893337662244), linewidth(0.8)); draw((1.5534973808986277,9.160392608982256)--(1.9295955015644004,1.832569513956508), linewidth(0.4) + ffqqff); draw(circle((5.807241390273251,2.031588419358404), 3.8827498197705226), linewidth(0.4) + wvvxds); draw(circle((1.9067865071150452,2.276975553541132), 6.892477317034895), linewidth(0.4) + dtsfsf); draw(circle((3.5081332893469326,4.891548128823499), 4.6950649335634775), linewidth(0.4) + wvvxds); draw((8.19899262334367,5.090227365365952)--(5.807241390273251,2.031588419358404), linewidth(0.4) + qqffff); draw((3.8176841460738786,5.365866172483034)--(8.19899262334367,5.090227365365952), linewidth(0.4) + qqffff); draw((8.19899262334367,5.090227365365952)--(7.796798634472622,-1.3026893337662244), linewidth(0.4) + wrwrwr); draw((3.8176841460738786,5.365866172483034)--(1.9295955015644004,1.832569513956508), linewidth(0.4) + ffqqff); draw((1.9295955015644004,1.832569513956508)--(7.796798634472622,-1.3026893337662244), linewidth(0.4) + qqffff); draw((3.8176841460738786,5.365866172483034)--(4.169500681742824,-1.488859213336944), linewidth(0.4) + qqffff); draw((5.807241390273251,2.031588419358404)--(4.169500681742824,-1.488859213336944), linewidth(0.4) + qqffff); draw((1.9295955015644004,1.832569513956508)--(2.2600756333314593,-4.606441501899994), linewidth(0.4) + ffqqff); draw((2.2600756333314593,-4.606441501899994)--(8.19899262334367,5.090227365365952), linewidth(0.4) + green); draw((-1.0161468573881236,3.63674779242076)--(17.798762343332783,-0.7893418218123583), linewidth(0.4) + linetype("4 4") + blue); draw((1.5534973808986277,9.160392608982256)--(17.798762343332783,-0.7893418218123583), linewidth(0.4) + linetype("4 4") + blue); draw((1.9295955015644004,1.832569513956508)--(5.807241390273251,2.031588419358404), linewidth(0.4) + wrwrwr); draw((7.796798634472622,-1.3026893337662244)--(17.798762343332783,-0.7893418218123583), linewidth(0.4) + linetype("4 4") + blue); /* dots and labels */ dot((1.5534973808986277,9.160392608982256),dotstyle); label("$A$", (1.6396828828887742,9.383171533517269), NE * labelscalefactor); dot((-3.5857910956748746,-1.8868970241407366),dotstyle); label("$B$", (-3.4819992193005715,-1.6553396638953617), NE * labelscalefactor); dot((7.796798634472622,-1.3026893337662244),dotstyle); label("$C$", (7.88392544583195,-1.0706727572527435), NE * labelscalefactor); dot((1.9295955015644004,1.832569513956508),linewidth(4pt) + dotstyle); label("$I$", (2.0138697031400508,2.01636850982028), NE * labelscalefactor); dot((5.807241390273251,2.031588419358404),linewidth(4pt) + dotstyle); label("$N$", (5.896057963247044,2.2268485962116227), NE * labelscalefactor); dot((3.8176841460738786,5.365866172483034),linewidth(4pt) + dotstyle); label("$Q$", (3.9081904806621375,5.547756625941694), NE * labelscalefactor); dot((8.19899262334367,5.090227365365952),linewidth(4pt) + dotstyle); label("D", (8.28149894234893,5.267116510753237), NE * labelscalefactor); dot((-1.0161468573881236,3.63674779242076),linewidth(4pt) + dotstyle); label("$M$", (-0.9328515063387511,3.8171425822795437), NE * labelscalefactor); dot((17.798762343332783,-0.7893418218123583),linewidth(4pt) + dotstyle); label("Q", (17.893422887553594,-0.602939231938649), NE * labelscalefactor); dot((4.675148007685625,3.928851637608016),linewidth(4pt) + dotstyle); label("$F$", (4.773497502493214,4.121169373733705), NE * labelscalefactor); dot((4.169500681742824,-1.488859213336944),linewidth(4pt) + dotstyle); label("$H$", (4.258990624647709,-1.3045395199097907), NE * labelscalefactor); dot((2.2600756333314593,-4.606441501899994),linewidth(4pt) + dotstyle); label("$J$", (2.3646698471256222,-4.414967463248519), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]

When you use Geogebra-Asymptote conversion, how did you doit. Why did mine have an error?
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guptaamitu1
656 posts
guptaamitu1
#22 Mar 7, 2022, 11:31 AM
Y by
Firstly you have convert it from Geogebra Classic and not Geogebra Geometry. If you find easier to draw in Geogebra Geomtery (as I also do), then save it and reopen it in Geogebra Classic. After the conversion, you have to do some slight edits. Like changing the size and defaultpen.
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IAmTheHazard
5001 posts
IAmTheHazard
#23 Apr 14, 2022, 4:02 PM • 1 Y
Y by Lantien.C
We begin with the following key claim.

Claim: $N$ is the center of $\omega$.
Proof: Let $N'$ be the intersection of the perpendicular to $\overline{AI}$ at $I$ with $\overline{AC}$. Then we have
$$\angle N'IC=\angle ICB=\angle ICA=\angle ICN',$$so $N'I=N'C$ and thus $N'$ is the center of $\omega$. Then $Q$ is the reflection of $C$ over $N'$, hence $N'$ is the midpoint of $\overline{CQ}$ and we have $N=N'$, which implies the desired result.

Now let $P \neq D$ be the intersection of $\omega$ with $\overline{AD}$, $R \neq C$ be the intersection of $\omega$ with $\overline{BC}$, and $X=\overline{AD} \cap \overline{BC}$. By Reim's, we have $\overline{AB} \parallel \overline{PR}$, so
$$\angle QPR=\angle QCR=\angle ABC=\angle PRC,$$so we have $\overline{PQ} \parallel \overline{CR}$ as well. Then we have $90^\circ=\angle QPC=\angle PCR$, so $CPQR$ is a rectangle, and $N$ is the midpoint of $\overline{PR}$. But triangles $\triangle XAB$ and $\triangle XPR$ are homothetic, which implies that $\overline{MN}$ passes through $X$ as well, hence $\overline{AD}$, $\overline{MN}$, and $\overline{BC}$ concur. $\blacksquare$
This post has been edited 1 time. Last edited by IAmTheHazard, Apr 14, 2022, 4:02 PM
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Lantien.C
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Lantien.C
#24 Jun 5, 2023, 3:37 PM
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mohamad021 wrote:
srisainandan6 wrote:
To begin, note that it is easy to see that $N$ is the circumcenter of $\omega$ as $\triangle NIC$ is isosceles.

Denote $X= BC \cap AD$. We desire to show that $M,N,X$ are collinear. Denote $E = \omega \cap AD$ and $F = \omega \cap BC$. By Reim's Theorem, we get that $EF \parallel AB$. To finish, take a homotethy centered at $X$ that maps $\triangle XEF$ to $\triangle XAB$ which yields $X,N,M$ collinear. $\blacksquare$

Can you explain Reim's theorem please?
JI//FH,as the picture says
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ihatemath123
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ihatemath123
#25 Sep 8, 2023, 3:03 AM
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By angle chasing, $\angle QIC = 90^{\circ}$, hence $\angle QDC = 90^{\circ}$, hence $\angle ADQ = 90 - \angle B$, hence $(ADQ)$ is tangent to $\overline{AI}$.

If we extend $AB$ to $B'$ and $AC$ to $C'$ such that $BB' = CC' = AQ$, then $M$ and $N$ have equal powers WRT $(AQD)$ and $(BCC'B')$, hence $\overline{MN}$ is their radical axis. Then, obviously $\overline{BC}$ is the radical axis of $(ABC)$ and $(BCC'B')$, and $\overline{AD}$ is the radical axis of $(AQD)$ and $(ABC)$, hence they all concur by the radical axis theorem.
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trk08
614 posts
trk08
#26 Oct 16, 2023, 6:45 PM
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Claim:
$N$ is the center of $(CIQ)$
Proof:
By angle-chasing, we can see that:
\[\angle CQI=\angle CIF=90^{\circ}-\angle ICF=90^{\circ}-\angle ICQ.\]Therefore, $\angle QIC=90^{\circ}$, or $N$ is the center $\blacksquare$

Claim:
The line parallel to $AB$ that passes through $N$ goes through $E$ and $F$.
Proof:

Denote $E=(CQD)\cap BC$ and $F=(CQD)\cap AD$. By Reim's theorem, $EF$ is parallel to $AB$.

Also, $\triangle{NEC}$ is isosceles, so it is similar to $\triangle{ABC}$. As a result, $NE\parallel AB$. Therefore, $N,E,F$ are all collinear and parallel to $AB$ $\blacksquare$

As a result, we can take a homothety at $T=AD\cap BC$, which sends $N$ to $M$, implying the desired result $\square$
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asdf334
7585 posts
asdf334
#27 Oct 29, 2023, 1:54 AM
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Note that $N$ is the center of $\omega$. Let $E$ be the other intersection of $\omega$ with $BC$ and let $E'$ be its antipode wrt $\omega$. Let $F$ be the midpoint of $BC$. It suffices to show that $AFED$ is cyclic as this implies $A,E',D$ collinear.

Here's the interesting part.

Claim: Let $ABCD$ be a cyclic quadrilateral. Let $F$ and $E$ be points where $B,F,E,C$ are on $BC$ in that order. If $\angle BAF=\angle CDE$ then $AFED$ is cyclic.
Proof: Angle chase.

Now we're done; just apply the claim here.
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bjump
1013 posts
bjump
#28 Nov 24, 2023, 2:32 PM
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Claim:$N$ is the center of $\omega$.
Proof Let $O$ denote the center of $\omega$. $\angle ICQ= \angle ICB = \tfrac{1}{2} \angle QOI$. Since $OI \perp AI$, then $OI \parallel BC$. Since $\angle QOI = \angle ICQ + \angle ICB= \angle BCA$, $O$ lies on $AC$. Since $OQ=OC$, then $O$ is the midpoint of $CQ$. So $O= N$. $\square$

By Reims on $\omega$ and $(ABC)$ with lines $AD$ and $BC$ we get that the line through $D$ parallel to $AB$ intersects $BC$ on $\omega$ at a point we will call $P$ then let $DP\cap MN= Q$ then by homothety $BP$, $AD$, $MQ$ are concurrent so $MN$, $BC$, and $AD$ are concurrent.
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LuciferMichelson
18 posts
LuciferMichelson
#29 Nov 24, 2023, 5:01 PM
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Define $R$ as midpoint of $BC$
Easy to see $N$ is center of $DQIC$.
After that define $S=(DIQ) \cap BC$
Angle chasing shows $SN//AB$ so $AS,BN,CM$ concurrent.
Now we should show that $(B,C;S,AD \cap BC)=-1$
Let $AD \cap BC= K'$ so $(B,C;S,AD \cap BC)=-1$ is equal to $KD.KA=KS.KR$ and from angle chasing it is easy that show $ADSR$ is cyclic.
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shendrew7
794 posts
shendrew7
#30 Dec 23, 2023, 9:18 PM
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If $N'$ is the intersection of $AC$ with the line through $I$ parallel $BC$, we know $N'I \perp AI$ and
\[\angle ACI = \angle ICB = \angle NIC,\]
so $N'$ is the center of $\omega$. Therefore $N'$ is the midpoint of $CQ$, so $N' = N$.

Next we define the intersections of $AC$ and $BC$ with $\omega$ as $K$ and $L$. Looking at $CD$, Reim's tells us that $AB \parallel KL$, which then gives
\[\angle LKQ = \angle LCQ = \angle ABC = \angle KLC,\]
so $KQ \parallel BC$ as well. As a result, $\angle KCL = \angle QKC = \angle QLC = 90$, so $KL$ is a diameter of $\omega$, and hence passes through $M$. We finish by noting the homothety which maps $KL$ to $AB$ also maps corresponding midpoints $N$ to $M$.
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joshualiu315
2533 posts
joshualiu315
#31 Mar 15, 2025, 12:38 AM
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We begin with a simple, but important claim.

Claim: $N$ is the center of $\omega$.

Proof: Let $\angle IAC = \alpha$. Note that $\angle ICA = 90-\tfrac{\alpha}{2}$, and we also have $\angle ICA = \angle AIQ$ from the tangency condition. Therefore,

\[\angle CQI = \angle IAQ+\angle AIQ = \alpha + \left(90-\frac{\alpha}{2} \right) = 90+\frac{\alpha}{2},\]
which means $\angle CQI + \angle ICQ = 90^\circ$, or $\angle CIQ = 90^\circ$. This means that $\overline{CQ}$ is a diameter of $\omega$, and the midpoint of $\overline{CQ}$ is the center of $\omega$, which is $N$. $\square$

Let $C' \neq C = \overline{AC} \cap \omega$ and $D' \neq D = \overline{AD} \cap \omega$. Note that lines $\overline{AB}$ and $\overline{CD}$ are antiparallel and $\overline{CD}$ and $\overline{C'D'}$ are also antiparallel. By Reim's Theorem, we have $\overline{AB} \parallel \overline{C'D'}$.

It suffices to show that $N$ is the midpoint of $\overline{C'D'}$; if so, the three lines will concur at the center of the homothety that maps $\overline{AB}$ to $\overline{D'C'}$. However, we simply angle chase to find

\[\angle NC'C = \angle NCC' = \angle ACB = \angle ABC,\]
so $\overline{NC'} \parallel \overline{AB}$. This means $N$ lies on $\overline{C'D'}$, and $N$ is the center of $\omega$, which implies $N$ bisects $\overline{C'D'}$. $\blacksquare$
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zuat.e
55 posts
zuat.e
#32 Apr 23, 2025, 3:22 PM
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First, let $N'$ be the center of $(CQDI)$. Note that $IN'\parallel BC$, therefore $\measuredangle N'CI=\measuredangle CIN'=\measuredangle ICB$, hence $N'$ lies on $AC$ and consequently $N'\equiv N$.

Let $R = AD\cap BC$ and let $E,F = BC, AD\cap (CQDI)$. We will prove that $R-N-M$ are collinear. The main claim is the following:
Claim: $EF$ is a diameter of $(CQID)$ and parallel to $AB$
Proof: $\measuredangle CEN=\measuredangle NCE=\measuredangle ACB=\measuredangle CBA$ and if we define $F'=EN\cap AD$, $\measuredangle EFD=\measuredangle BAR=\measuredangle RCD$, from which it follows $F=F'$ and $EF$ is a diameter of $(CQID)$ parallel to AB.

Now consider the homothety centered at $R$ sending $\triangle RFE$ to $\triangle RAB$. As both $RM$ and $RN$ are the respective medians of $\triangle RFE$ and $\triangle RAB$,
\[X_R: N\mapsto M\]hence $R-N-M$ are collinear, as desired.
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