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k a My Retirement & New Leadership at AoPS
rrusczyk   1571
N Mar 26, 2025 by SmartGroot
I write today to announce my retirement as CEO from Art of Problem Solving. When I founded AoPS 22 years ago, I never imagined that we would reach so many students and families, or that we would find so many channels through which we discover, inspire, and train the great problem solvers of the next generation. I am very proud of all we have accomplished and I’m thankful for the many supporters who provided inspiration and encouragement along the way. I'm particularly grateful to all of the wonderful members of the AoPS Community!

I’m delighted to introduce our new leaders - Ben Kornell and Andrew Sutherland. Ben has extensive experience in education and edtech prior to joining AoPS as my successor as CEO, including starting like I did as a classroom teacher. He has a deep understanding of the value of our work because he’s an AoPS parent! Meanwhile, Andrew and I have common roots as founders of education companies; he launched Quizlet at age 15! His journey from founder to MIT to technology and product leader as our Chief Product Officer traces a pathway many of our students will follow in the years to come.

Thank you again for your support for Art of Problem Solving and we look forward to working with millions more wonderful problem solvers in the years to come.

And special thanks to all of the amazing AoPS team members who have helped build AoPS. We’ve come a long way from here:IMAGE
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rrusczyk
Mar 24, 2025
SmartGroot
Mar 26, 2025
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k a March Highlights and 2025 AoPS Online Class Information
jlacosta   0
Mar 2, 2025
March is the month for State MATHCOUNTS competitions! Kudos to everyone who participated in their local chapter competitions and best of luck to all going to State! Join us on March 11th for a Math Jam devoted to our favorite Chapter competition problems! Are you interested in training for MATHCOUNTS? Be sure to check out our AMC 8/MATHCOUNTS Basics and Advanced courses.

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0 replies
jlacosta
Mar 2, 2025
0 replies
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Inspired by old results
sqing   7
N 2 hours ago by SunnyEvan
Source: Own
Let $ a,b,c> 0 $ and $ abc=1 $. Prove that
$$\frac1{a^2+a+k}+\frac1{b^2+b+k}+\frac1{c^2+c+k}\geq \frac{3}{k+2}$$Where $ 0<k \leq 1.$
7 replies
1 viewing
sqing
Monday at 1:42 PM
SunnyEvan
2 hours ago
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Modular Arithmetic and Integers
steven_zhang123   3
N 2 hours ago by steven_zhang123
Integers \( n, a, b \in \mathbb{Z}^+ \) satisfies \( n + a + b = 30 \). If \( \alpha < b, \alpha \in \mathbb{Z^+} \), find the maximum possible value of $\sum_{k=1}^{\alpha} \left \lfloor \frac{kn^2 \bmod a }{b-k} \right \rfloor $.
3 replies
+1 w
steven_zhang123
Mar 28, 2025
steven_zhang123
2 hours ago
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Polynomials and their shift with all real roots and in common
Assassino9931   4
N 2 hours ago by Assassino9931
Source: Bulgaria Spring Mathematical Competition 2025 11.4
We call two non-constant polynomials friendly if each of them has only real roots, and every root of one polynomial is also a root of the other. For two friendly polynomials \( P(x), Q(x) \) and a constant \( C \in \mathbb{R}, C \neq 0 \), it is given that \( P(x) + C \) and \( Q(x) + C \) are also friendly polynomials. Prove that \( P(x) \equiv Q(x) \).
4 replies
Assassino9931
Mar 30, 2025
Assassino9931
2 hours ago
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2025 Caucasus MO Seniors P7
BR1F1SZ   2
N 2 hours ago by sami1618
Source: Caucasus MO
From a point $O$ lying outside the circle $\omega$, two tangents are drawn touching $\omega$ at points $M$ and $N$. A point $K$ is chosen on the segment $MN$. Let points $P$ and $Q$ be the midpoints of segments $KM$ and $OM$ respectively. The circumcircle of triangle $MPQ$ intersects $\omega$ again at point $L$ ($L \neq M$). Prove that the line $LN$ passes through the centroid of triangle $KMO$.
2 replies
BR1F1SZ
Mar 26, 2025
sami1618
2 hours ago
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No more topics!
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AD is Euler line of triangle IKL
VicKmath7   15
N Sep 15, 2024 by bin_sherlo
Source: IGO 2021 Advanced P5
Given a triangle $ABC$ with incenter $I$. The incircle of triangle $ABC$ is tangent to $BC$ at $D$. Let $P$ and $Q$ be points on the side BC such that $\angle PAB = \angle BCA$ and $\angle QAC = \angle ABC$, respectively. Let $K$ and $L$ be the incenter of triangles $ABP$ and $ACQ$, respectively. Prove that $AD$ is the Euler line of triangle $IKL$.

Proposed by Le Viet An, Vietnam
15 replies
VicKmath7
Dec 30, 2021
bin_sherlo
Sep 15, 2024
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AD is Euler line of triangle IKL
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Reveal topic tags
geometry
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Source: IGO 2021 Advanced P5
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VicKmath7
1386 posts
VicKmath7
#1 Dec 30, 2021, 5:24 PM • 1 Y
Y by amar_04
Given a triangle $ABC$ with incenter $I$. The incircle of triangle $ABC$ is tangent to $BC$ at $D$. Let $P$ and $Q$ be points on the side BC such that $\angle PAB = \angle BCA$ and $\angle QAC = \angle ABC$, respectively. Let $K$ and $L$ be the incenter of triangles $ABP$ and $ACQ$, respectively. Prove that $AD$ is the Euler line of triangle $IKL$.

Proposed by Le Viet An, Vietnam
This post has been edited 4 times. Last edited by VicKmath7, Oct 16, 2023, 5:55 PM
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Project_Donkey_into_M4
136 posts
Project_Donkey_into_M4
#2 Dec 30, 2021, 5:59 PM
Y by
I was really really rude

Sorry @Vickmath
This post has been edited 1 time. Last edited by Project_Donkey_into_M4, Oct 13, 2022, 2:06 PM
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Project_Donkey_into_M4
136 posts
Project_Donkey_into_M4
#4 Dec 30, 2021, 6:06 PM
Y by
VicKmath7 wrote:
Yes, of course I know, but I believe that everyone who knows what IGO is will understand what A means in this case. Anyways, I will correct it.

Yes but even I got confused at first sight,it's reccomendable to write the full form cuz there are a lot of people who don't know abt IGO
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MP8148
888 posts
MP8148
#5 Dec 31, 2021, 2:09 AM • 2 Y
Y by leon.tyumen, MS_asdfgzxcvb
Not the best solution, but I guess it works. Ignore config issues (I don't think there are any but who knows).

diagram

Let $O,H,G$ denote the circumcenter, orthocenter, and centroid of $\triangle IKL$, respectively. We will show that
  • $A$, $O$, $H$ are collinear
  • $A$, $G$, $D$ are collinear
which imply the conclusion.

proof that A-O-H
proof that A-G-D

Additional fact: $\overline{KL}$, $\overline{OX}$, $\overline{BC}$ seem to concur, although I didn't use/prove it.
This post has been edited 1 time. Last edited by MP8148, Dec 31, 2021, 2:14 AM
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MatteD
90 posts
MatteD
#6 Dec 31, 2021, 10:52 AM • 4 Y
Y by Acrylic2005, SerdarBozdag, toilaDang, PHSH
[asy] /* Geogebra to Asymptote conversion, documentation at artofproblemsolving.com/Wiki go to User:Azjps/geogebra */ import graph; size(12.cm); 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 = 4.4, xmax = 9.2, ymin = 0.8, ymax = 4.; /* image dimensions */ pen xdxdff = rgb(0.49019607843137253,0.49019607843137253,1.); pen ubqqys = rgb(0.29411764705882354,0.,0.5098039215686274); pen xfqqff = rgb(0.4980392156862745,0.,1.); /* draw figures */ draw((6.109430702956201,3.762535441352023)--(4.520861536062415,0.9952229780472427), linewidth(1.2) + xdxdff); draw((9.,1.)--(6.109430702956201,3.762535441352023), linewidth(1.2) + xdxdff); draw((6.109430702956201,3.762535441352023)--(6.793968020425234,0.9976472566588956), linewidth(1.2) + xdxdff); draw((6.109430702956201,3.762535441352023)--(5.430792468160217,0.9961934236079506), linewidth(1.2) + xdxdff); draw((6.109430702956201,3.762535441352023)--(5.001628488792055,0.9957357182328481), linewidth(1.2) + ubqqys); draw((6.109430702956201,3.762535441352023)--(7.711717014885521,0.9986260402193841), linewidth(1.2) + ubqqys); draw((5.001628488792055,0.9957357182328481)--(6.6393827585556835,1.9451703298270977), linewidth(1.2) + xfqqff); draw((5.827852937434829,1.7529086067332473)--(7.711717014885521,0.9986260402193841), linewidth(1.2) + xfqqff); draw((6.109430702956201,3.762535441352023)--(6.356672751838788,0.9971808792261161), linewidth(1.2) + ubqqys); draw((6.111695185347248,1.639260673316434)--(6.355540510643266,2.0588182632439107), linewidth(1.2) + green); draw((4.520861536062415,0.9952229780472427)--(5.001628488792055,0.9957357182328481), linewidth(1.2) + xdxdff); draw((5.001628488792055,0.9957357182328481)--(7.711717014885521,0.9986260402193841), linewidth(1.2) + ubqqys); draw((9.,1.)--(7.711717014885521,0.9986260402193841), linewidth(1.2) + xdxdff); draw((4.520861536062415,0.9952229780472427)--(5.827852937434829,1.7529086067332473), linewidth(1.2) + xdxdff); draw((5.827852937434829,1.7529086067332473)--(6.355540510643266,2.0588182632439107), linewidth(1.2) + green); draw((6.355540510643266,2.0588182632439107)--(6.6393827585556835,1.9451703298270977), linewidth(1.2) + green); draw((6.6393827585556835,1.9451703298270977)--(9.,1.), linewidth(1.2) + xdxdff); /* dots and labels */ dot((6.109430702956201,3.762535441352023),linewidth(3.pt) + dotstyle); label("$A$", (6.128176663628198,3.7891605035276705), NE * labelscalefactor); dot((4.520861536062415,0.9952229780472427),linewidth(3.pt) + dotstyle); label("$B$", (4.539303375246712,1.019140670079517), NE * labelscalefactor); dot((9.,1.),linewidth(3.pt) + dotstyle); label("$C$", (9.015890814734231,1.0233440385672987), NE * labelscalefactor); dot((6.355540510643266,2.0588182632439107),linewidth(3.pt) + dotstyle); label("$I$", (6.371972035919536,2.082592897488292), NE * labelscalefactor); dot((6.793968020425234,0.9976472566588956),linewidth(3.pt) + dotstyle); label("$P$", (6.809122358648834,1.0233440385672987), NE * labelscalefactor); dot((5.430792468160217,0.9961934236079506),linewidth(3.pt) + dotstyle); label("$Q$", (5.447230968607561,1.0233440385672987), NE * labelscalefactor); dot((6.356672751838788,0.9971808792261161),linewidth(3.pt) + dotstyle); label("$D$", (6.371972035919536,1.0233440385672987), NE * labelscalefactor); dot((5.827852937434829,1.7529086067332473),linewidth(3.pt) + dotstyle); label("$K$", (5.8465509749468225,1.7799503663680083), NE * labelscalefactor); dot((6.6393827585556835,1.9451703298270977),linewidth(3.pt) + dotstyle); label("$L$", (6.657801093088692,1.9691019483181857), NE * labelscalefactor); dot((7.711717014885521,0.9986260402193841),linewidth(3.pt) + dotstyle); label("$M$", (7.729660057473027,1.0233440385672987), NE * labelscalefactor); dot((5.001628488792055,0.9957357182328481),linewidth(3.pt) + dotstyle); label("$N$", (5.018487382853826,1.019140670079517), NE * labelscalefactor); dot((6.111695185347248,1.639260673316434),linewidth(3.pt) + dotstyle); label("$H$", (6.128176663628198,1.666459417197902), NE * labelscalefactor); dot((6.274258735544592,1.918965733268085),linewidth(3.pt) + dotstyle); label("$G$", (6.300514771627247,1.8850345785625513), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]
Let $M,N$ denote the reflections of $A$ with respect to $BI,CI$ respectively, and let $G,H$ be the centroid and orthocenter of $\triangle AMN$.
First, notice that by symmetry $IM=IA=IN$, so $I$ is the circumcenter of $\triangle AMN$ and $D$ is the midpoint of $MN$.
Since $\triangle BAC \sim \triangle BPA$, we have $\frac{BK}{BI}=\frac{BA}{BC}=\frac{BM}{BC}$, so $MK$ is parallel to $CI$. Since $CI \perp AN$, we also have $MK \perp AN$, and $NL \perp AM$ similarly, so $H=NL \cap MK$. $KILH$ is a parallelogram, and it is well-known that $\frac{IG}{IH}=\frac{1}{3}$, so $G$ is the centroid of $\triangle IKL$. The similarity of $\triangle BAC$ and $\triangle BPA$ also gives $\angle AKI = \angle AKB = \angle BIC$, and similarly we have $\angle BIC= \angle ILA$, which is enough to know that $A$ lies on the Euler line of $\triangle IKL$. Since $G \in AD$, we have that $AD$ is the Euler line of $\triangle IKL$. $\blacksquare$
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buratinogigle
2320 posts
buratinogigle
#7 Dec 31, 2021, 2:08 PM • 4 Y
Y by parmenides51, PHSH, hakN, MS_asdfgzxcvb
Here is my simple proof using barycentric coordinates.
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alinazarboland
168 posts
alinazarboland
#8 Jan 7, 2022, 7:10 PM
Y by
Here's a solution me and my friends found at our 3 A.M :alien:
Claim 1.In $\triangle ABC$ ,let $P$ be a point such that $\angle PBA=\angle PCA=180-A$. Then $P$ is on the Euler line of $\triangle ABC$.
Proof.It's well-known that the locus of points $X$ such that $\angle XBA=\angle XCA$ is a hyperbola passing through $A,B,C,H,A'$ where $H$ is the orthocenter of $ABC$ and $A'$ is the antipod of $A$ in $(ABC)$ . So $P$ is on this hyperbola. Also, by the definition of $P$, we have $PC \cap AB$ lies on the perpendicular bisector of $AC$ . Now , applying Pascal on the hyperbola $AA'CPHBA$ we'll get that a line through $PC \cap AB$ and $HP \cap AA'$ is perpendicular to $AC$ and since $PC \cap AB$ lies on the perpendicular bisector of $AC$, $HP \cap AA'$ is in fact the circumcenter of $(ABC)$ . So $H,O,P$ are collinear and we're done.

Claim2 .In $\triangle ABC$ with incenter $I$ , If a circle with center $I$ intersects $AB,BC,CA$ at $X,{Y,Z},T$ , then $XY,ZT,AD$ are concurrent.
Proof. Let the lines through $D$parallel to $AB,AC$ intersects $XY,ZT$ at $E,F$ respectively. Since $CT=CZ$ and $DF||AC$ , we have $DZ=DF$, and similarly , $DE=DF$ . On the other hand , since $IY=IZ$ ,it follows that $DY=DZ$ . So $DE=DF$ and $\triangle DEF$ is an isosceles triangle. Also , with a little angle chasing , $AXY$ is an isosceles to , so since $DE||AB$ and $DF||AC$ , $\triangle AXY$ and $\triangle DEF$ are homothetic. the conclusion follows.


Back to the problem.

By Claim 1 , Since $\angle AKI = \angle ALI = 90 - \angle A /2 = 180 - \angle KIL$ , $A$ lies on the Euler line of $\triangle KIL$.

Now , let the perpendicular bisector of $AI$ intersects $AC,AB$ at $M,N$ respectively. Since $MI=MA$ and $\angle AMI = 2\angle ALI$ , $M$ is the circumcenter of $\triangle ALI$. Similarly , $N$ is the circumcenter of $\triangle AKI$ . Now , let $M',N'$ be the reflection of $M,N$ to $IL,IK$ respectively . Since $MI=MK$ , $M'I = M'L$ and similar for $N$ . But $M',N'$ lie on $BC$ . So since $I$ is the center of $(MNM'N')$ , and since $MM',NN'$ are the perpendicular bisectors of $IL,IK$ respectively , by claim 2 , the circumcenter of $\triangle IKL$ lies on $AD$.

So $AD$ is the Euler line of $\triangle IKL$ and we're done.
This post has been edited 1 time. Last edited by alinazarboland, Jan 11, 2022, 8:25 PM
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Fedor Bakharev
181 posts
Fedor Bakharev
#9 Jan 8, 2022, 12:59 PM • 1 Y
Y by amar_04
Proposed by Le Viet An -Vietnam
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LoloChen
477 posts
LoloChen
#11 Jan 24, 2022, 4:46 AM • 1 Y
Y by buratinogigle
It seems that this one is not hard to bash.
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PHSH
60 posts
PHSH
#12 Jul 14, 2022, 12:42 PM
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motivation

We have that $APB$ is opositive similar to $CAB,$ hence ${KB}{/IB} = {AB}{/BC}.$ Hence, if we define $X$ as the reflection of $A$ over line $BI,$ we will have $KX \parallel IC.$ Similarly, $Y$ is the reflection of $A$ with respect to $CI,$ and $L$ is the intersection of $CI$ and the parallel of $BI$ through $Y.$ We are going to take this redefinition later on.

[asy] import olympiad; import graph; import geometry; size(250); pair A,B,C,O,I,D,X,Y,K,L,H,I,Bt,Mt,Ct,Nt; A = dir(-240.54); B = dir(-170.37); C = dir(-10.43); O = (0,0); I = incenter(A,B,C); D = foot(I,B,C); X= 2*foot(A,B,I) - A; Y = 2*foot(A,C,I) - A; Bt= B*0.5 + I*0.5; Mt = extension(I,Y,C,Bt); L =extension(B,Mt,C,I); Ct= C*0.5 + I*0.5; Nt = extension(I,X,B,Ct); K = extension(C,Nt,B,I); dot("$K$",K,dir(120)); dot("$L$",L, dir(60)); dot("$Y$", Y, dir(-90)); dot("$X$", X, dir(X)); dot("$B$",B, dir(-90)); dot("$C$",C, dir(-90)); dot("$I$", I, dir(I)); dot("$D$", D, dir(D)); draw(circle(I,distance(I,D)),dotted + green); draw(A--B--C--cycle,gray); draw(B--I,blue); draw(C--I,blue); draw(K--X, dotted+magenta); draw(Y--L,dotted+magenta); dot("$A$",A, dir(A)); [/asy]

Note now, that on triangle $\triangle AXY,$ we have that $BI$ and $CI$ are the perpendicular bissectors of $AX$ and $AY,$ respectively. Furthermore, $YL$ and $XK$ are altitudes of $\triangle AXY.$ So the new problem reads as follows

Let $\triangle AXY$ be an triangle with circumcenter $I$. Point $K$ is the intersection of the $X$-altitude with the perpendicular bissector of $AX;$ similarly point $L$ is the intersection of the $Y$-altitude with the perpendicular bissector of $AY.$ If $D$ is the midpoint of side $XY,$ show that $AD$ is the euler line of thriangle $IKL.$


So let $H$ be the orthocenter of $\triangle AXY.$ Also let $M$ and $N$ be the midpoints of sides $AX$ and $AY,$ respectively, and let $E$ and $F$ be the foots of $X$ and $Y$ respectively. Also let $T$ be the orthocenter of $IKL$

[asy] import olympiad; import graph; import geometry; size(250); pair A,B,C,O,I,D,X,Y,K,L,H,I,Bt,Mt,Ct,Nt; A = dir(-240.54); B = dir(-170.37); C = dir(-10.43); O = (0,0); I = incenter(A,B,C); D = foot(I,B,C); X= 2*foot(A,B,I) - A; Y = 2*foot(A,C,I) - A; Bt= B*0.5 + I*0.5; Mt = extension(I,Y,C,Bt); L =extension(B,Mt,C,I); Ct= C*0.5 + I*0.5; Nt = extension(I,X,B,Ct); K = extension(C,Nt,B,I); pair M,N,E,F,H,T; M = A*0.5 + X*0.5; N = A*0.5 + Y*0.5; E = foot(X,A,Y); F = foot(Y,A,X); H = extension(E,X,F,Y); T = extension(A,D,K,A+K-Y); draw(A--D, dotted); draw(K--T--L,magenta); draw(circumcircle(A,F,N), dotted + green); draw(circumcircle(A,E,M),dotted + blue); draw(A--X--Y--cycle,gray); draw(M--I--K--cycle,orange); draw(N--I--L--cycle,orange); draw(X--E,red); draw(F--Y,red); dot("$A$", A, dir(A)); dot("$X$", X, dir(X)); dot("$Y$", Y, dir(Y)); dot("$D$",D, dir(-90)); dot("$M$",M, dir(30)); dot("$N$", N, dir(N)); dot("$E$",E, dir(E)); dot("$F$",F, dir(-10)); dot("$I$",I, dir(90)); dot("$K$",K,dir(260)); dot("$L$",L,-dir(L)); dot("$H$",H,dir(-90)); dot("$T$",T, dir(45)); [/asy]
First, note that the centroid of $\triangle IKL$ lies on $AD.$ Indeed, by definition $IKHL$ is an parallelogram, so the centroid of $\triangle IKL$ divides the segment $IH$ in the ratio $1{/3};$ hence the centroid of $IKL$ coincides with the centroid of $AXY$ which indeed lies on the $A$-median, $AD$.

Now it is sufficient to show that $T$ lies on $AD.$ On one hand, $AD$ is the $A$-median, so $T$ lies on $AD$ if and only if $[ATY]=[ATX].$ On the other hand, by construction $TK \parallel AY$ and $TL \parallel AX$ and hence $[ATY] = [AKY]$ and $[ATX] =[ALX]. $ Then it reduces to $$[AKY] = [ALX] \iff KE \cdot AY = LF \cdot AX.$$
So let $b =AX, c =AY, p = XE, q = YF.$ Since $AEKM$ is cyclic by construction, it follows by power of a point that
$$ XH \cdot XE = XM \cdot XA = \frac{b^2}{2} \Rightarrow HE = \frac{2p^2 -b^2}{2p} \Rightarrow KE\cdot AY = \frac{(2p^2-b^2)c}{2p}$$Similarly, $LF \cdot AX = \frac{(2q^2-c^2)b}{2q} $ and it is sufficient to show
$$(2p^2 -b^2)cq =(2q^2-c^2)bp $$which is obviously since $p = b\cdot \sin \angle XAY$ and $q = c \cdot \sin \angle XAY.$
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strong_boy
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strong_boy
#13 Jul 31, 2022, 6:18 AM • 1 Y
Y by Mango247
official solution !
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FairyBlade
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FairyBlade
#14 Sep 26, 2022, 2:43 PM
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Consider point $R, S$ on side $AB, AC$ s.t. $RIA=SIA=90$, then i claim that $(RKIA)$ cyclic:
$$\angle AKI=\beta/ 2+\gamma /2=90-\alpha /2 = \angle ARI$$similarly the other one.now said $O_b, O_c$ the midpoint of $AR, AS$ we have that the axis of $KI, LI$ pass through this points.
Now consider point $X, Y$ as the second intersection of $(RKIA),(SLIA)$ with $AC, AB$. I claim that the height from $K$ and $L$ in triangle $\triangle KIL$ intersect side $AC, AB$ on $X,Y$:
$$\angle IKX=\angle AIX=\alpha/2=\angle KIL-90$$Now consider the point $E, F$ as the projection on the side $AB, AC$ of $I$, then we have that the bisector $BI\perp ED$ and so $ED$ is parallel to the axis of $KI$, and the height of $L$ wrt. $IK$. Now the problem can be finished by noting that $AX/AY=AO_b/AO_c=AE/AF=1$ and so by homothety in $A$ the point $O,H,D$ are aligned.
This post has been edited 2 times. Last edited by FairyBlade, Sep 26, 2022, 2:45 PM
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squarc_rs3v2m
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squarc_rs3v2m
#15 Oct 5, 2022, 10:18 PM
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Let $G, O, H$ be the centroid, circumcenter, orthocenter of $\triangle IKL$.
Claim 1: $A \in OH$.
proof
Claim 2: $G \in AD$.
proof
Combining these two claims clearly solves the problem.
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StefanSebez
53 posts
StefanSebez
#16 Nov 17, 2022, 8:44 PM • 1 Y
Y by GeoKing
I will share my proof of showing that centroid of $\Delta IKL$ lies on $AD$
This proof is very interesting and beautiful and as i have seen no one else posted it before
Also i found this without geogebra :gleam:

Points $P, Q$ are basically irrelevant, $K$ and $L$ are just points on $BI$ and $CI$ such that $\angle KAB=\frac{\angle C}{2}$ and $\angle LAC=\frac{\angle B}{2}$
As $\angle KAB=\angle ACL$ and $\angle KBA=\angle LAC$ we see that $\Delta KBA\sim \Delta LAC$
Because these triangles are oriented the same way we can now apply the gliding principle
Let $M, N, T$ be midpoints of $AC, AB, KL$
By the gliding principle $\Delta TNM\sim \Delta KBA\sim \Delta LAC$
Let $X=MT\cap AK$ and $Y=NT\cap AL$
$\angle YNM=\angle TNM=\angle LAC=\angle YAM$ so $ANYM$ cyclic
similarly $ANXM$ cyclic
Hence $ANXYM$ cyclic

Consider a homothety at $A$ with scaling ratio $2$
$N\mapsto B, M\mapsto C$ and hence $(ANXYM)\mapsto (ABC)$
Now let $AX$ and $AY$ intersect $(ABC)$ at $R$ and $S$
$X\mapsto R, Y\mapsto S$
Let $J=BS\cap CR$
$T\mapsto J$ so $A-T-J$ and $T$ is midpoint of $AJ$
$\angle JBC=\angle SBC=\angle SAC=\angle ABI=\angle IBC$
similarly $\angle JCB=\angle ICB$
This means that $J$ is the reflection of $I$ in $BC$, hence $I-D-J$ and $D$ is midpoint of $IJ$
Let $G=IT\cap AD$
Consider triangle $\Delta IJA$
$T$ is midpoint of $AJ$, $D$ is midpoint of $IJ$ hence $G$ is centroid of $\Delta IJA$
Now $\frac{GT}{GI}=\frac{1}{2}$
As $T$ is midpoint of $KL$ as well we see that $G$ is centroid $\Delta IKL$ as needed
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KST2003
173 posts
KST2003
#17 May 29, 2023, 3:50 PM
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Let $K' = \overline{CI} \cap \overline{AK}$, and $L' = \overline{BI} \cap \overline{AL}$. Note that $\triangle ABC \sim \triangle PBA \sim \triangle QAC$, so $\triangle BIC \sim \triangle BKA \sim \triangle ALC$. In particular, $\triangle IKK'$ and $\triangle ILL'$ are isosceles, and so $K$, $L$, $K'$ and $L'$ are concyclic.

By EGMO Theorem 10.5, the Euler line of $\triangle IKL$ must then be the radical axis $\ell$ of circles with diameters $KK'$ and $LL'$, call them $\omega_K$ and $\omega_L$. Obviously $A$ must lie on $\ell$ since $KK'L'L$ is cyclic, so we just need to show that $D$ has equal powers to both circles.

Let $\omega_K$ intersect $\overline{BI}$ and $\overline{CI}$ at $W$ and $X$. Define $Y$ and $Z$ similarly for $\omega_L$. We claim that $D$ lies on $\overline{WX}$. Let $M_B$ be the midpoint of minor arc $AC$. By the incenter lemma, $M_BI = M_BC$, so $\triangle IWX \sim \triangle IK'K \sim \triangle IM_BC$, so $\overline{WX} \parallel \overline{M_BC}$. Let $I'$ be the reflection of $I$ over $\overline{BC}$. Then $\triangle BI'C$ and $\triangle BKA$ are spirally similar, so $\triangle BKI'$ and $\triangle BAC$ are spirally similar as well. In particular, $\angle BKI' = \angle BAC = \angle BM_BC$, so $\overline{DW} \parallel \overline{I'K} \parallel \overline{M_BC}$. This shows the collinearity.

Since $WXYZ$ is cyclic, it then follows that $D$ has equal power to both $\omega_K$ and $\omega_L$. Therefore, $D$ lies on $\ell$ as desired.
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bin_sherlo
672 posts
bin_sherlo
#18 Sep 15, 2024, 8:49 AM
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Let $P,Q$ be the $A-$mixtilinear touch points to $AB,AC$ respectively. Let $E,F$ be the tangency points of the incircle with $AC,AB$. Let $O,H$ be the circumcenter and orthocenter of $\triangle IKL$.
Claim: $K=BI\cap (API)$ and $L=CI\cap (AQI)$.
Proof:
\[\measuredangle KAP=\measuredangle KAB=\frac{\measuredangle C}{2}=\measuredangle BIP=\measuredangle KIP\]\[\measuredangle QAL=\measuredangle CAL=\frac{\measuredangle B}{2}=\measuredangle QIC=\measuredangle QIL\]These yield the desired result.$\square$

Now we present a lemma.
Lemma: $ABC$ is a triangle whose circumcenter is $O$. Let $O'$ be the reflection of $O$ with respect to $BC$. The tangent to $(ABC)$ at $A$ intersect $BC$ at $D$. Points $E,F$ are taken on $O'C,O'B$ such that $EA=EC$ and $FA=FB$. Then, $D,E,F$ are collinear.
Proof: Let $X,Y$ be the intersection of the tangent to $(ABC)$ at $A$ with the tangent at $C,B$ respectively. By appyling Desargues theorem on $YOX$ and $BO'C,$ since $YB,OO',XC$ are concurrent, we get that these triangles are perpective. Hence $YO\cap BO'=F,OX\cap O'C=E,XY\cap BC=D$ are collinear.$\square$
Claim: $A,O,D$ are collinear.
Proof: Invert the diagram from $I$ with radius $ID$. Note that $K^*=IB\cap A^*P^*$ and $L^*=IC\cap A^*Q^*$. $O^*$ is the reflection of $I$ according to $K^*L^*$. Let $EF$ intersect $BC$ at $T$. $M,N,W$ are the midpoints of $IE,IF,IT$ respectively. $M,N,W$ are collinear. Let $K_1,L_1$ be the reflections of $I$ to $K^*,L^*$. By applying the lemma on $\triangle DEF,$ we get that $T,K_1,L_1$ are collinear. Take the homothety centered at $I$ with ratio $\frac{1}{2}$. Then, $W,K^*,L^*$ are collinear. Since $K^*L^*$ is the perpendicular bisector of $IO^*,$ we have $WT=WI=WO^*$. Hence $O^*$ is on $(TIDA^*)$ which proves the claim.$\square$
Claim: $A,H,D$ are collinear.
Proof: Let $(AIP)\cap AC=R$ and $(AIQ)\cap AB=S$.
\[\measuredangle HKI=90-(180-\measuredangle CIB)=\frac{\measuredangle A}{2}=\measuredangle RKI\]Thus, $H$ lies on $KR$. Similarily, $H$ lies on $LS$. So $H=KR\cap LS$.
Applying Desargues theorem on $RHS$ and $EDF,$ since $RH\cap ED,RS\cap EF,HS\cap DF$ is the line at infinity $A,H,D$ are collinear as desired.$\blacksquare$
This post has been edited 1 time. Last edited by bin_sherlo, Sep 15, 2024, 9:21 AM
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