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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
1571 replies
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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Do you have plans this summer? There are so many options to fit your schedule and goals whether attending a summer camp or taking online classes, it can be a great break from the routine of the school year. Check out our summer courses at AoPS Online, or if you want a math or language arts class that doesn’t have homework, but is an enriching summer experience, our AoPS Virtual Campus summer camps may be just the ticket! We are expanding our locations for our AoPS Academies across the country with 15 locations so far and new campuses opening in Saratoga CA, Johns Creek GA, and the Upper West Side NY. Check out this page for summer camp information.

Be sure to mark your calendars for the following events:
[list][*]March 5th (Wednesday), 4:30pm PT/7:30pm ET, HCSSiM Math Jam 2025. Amber Verser, Assistant Director of the Hampshire College Summer Studies in Mathematics, will host an information session about HCSSiM, a summer program for high school students.
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0 replies
jlacosta
Mar 2, 2025
0 replies
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Find the probability
ali3985   0
2 minutes ago
Let $A$ be a set of Natural numbers from $1$ to $N$.
Now choose $k$ ($k \geq 3$) distinct elements from this set.

What is the probability of these numbers to be an increasing geometric progression ?
0 replies
ali3985
2 minutes ago
0 replies
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IMOC 2017 G2 , (ABC) <= (DEF) . perpendiculars related
parmenides51   7
N 6 minutes ago by AshAuktober
Source: https://artofproblemsolving.com/community/c6h1740077p11309077
Given two acute triangles $\vartriangle ABC, \vartriangle DEF$. If $AB \ge DE, BC \ge EF$ and $CA \ge FD$, show that the area of $\vartriangle ABC$ is not less than the area of $\vartriangle DEF$
7 replies
parmenides51
Mar 20, 2020
AshAuktober
6 minutes ago
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The Sums of Elements in Subsets
bobaboby1   3
N 7 minutes ago by bobaboby1
Given a finite set \( X = \{x_1, x_2, \ldots, x_n\} \), and the pairwise comparison of the sums of elements of all its subsets (with the empty set defined as having a sum of 0), which amounts to \( \binom{2}{2^n} \) inequalities, these given comparisons satisfy the following three constraints:

1. The sum of elements of any non-empty subset is greater than 0.
2. For any two subsets, removing or adding the same elements does not change their comparison of the sums of elements.
3. For any two disjoint subsets \( A \) and \( B \), if the sums of elements of \( A \) and \( B \) are greater than those of subsets \( C \) and \( D \) respectively, then the sum of elements of the union \( A \cup B \) is greater than that of \( C \cup D \).

The question is: Does there necessarily exist a positive solution \( (x_1, x_2, \ldots, x_n) \) that satisfies all these conditions?
3 replies
bobaboby1
Mar 12, 2025
bobaboby1
7 minutes ago
J
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3 var inquality
sqing   1
N 15 minutes ago by sqing
Source: Own
Let $a,b,c>0$. Prove that
$$ \dfrac{ab}{a^2-ab+3b^2} + \dfrac{bc}{b^2-bc+3c^2} + \dfrac{ca}{c^2-ca+3a^2} \le1$$$$ \dfrac{ab}{a^2-ab+ 2b^2} + \dfrac{bc}{b^2-bc+2 c^2} + \dfrac{ca}{c^2-ca+ 2a^2}\le \dfrac{3}{2}$$$$ \dfrac{ab}{2a^2-ab+3b^2} + \dfrac{bc}{2b^2-bc+3c^2} + \dfrac{ca}{2c^2-ca+3a^2} \le \dfrac{3}{4}$$
1 reply
1 viewing
sqing
18 minutes ago
sqing
15 minutes ago
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Inequality
JK1603JK   1
N 4 hours ago by lbh_qys
Let $a,b,c\ge 0: a+b+c=3$ then prove \frac{1}{a+b}+\frac{1}{b+c}+\frac{1}{c+a}+\frac{1}{2}\cdot\frac{abc}{ab+bc+ca}\ge \frac{5}{3}.$$
1 reply
JK1603JK
5 hours ago
lbh_qys
4 hours ago
J
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Inequality
JK1603JK   1
N 6 hours ago by lbh_qys
Prove that 9ab\left(a-b+c\right)+9bc\left(b-c+a\right)+9ca\left(c-a+b\right)\ge \left(a+b+c\right)^{3},\ \ a\ge 0\ge b\ge c: a+b+c\le 0.
1 reply
JK1603JK
6 hours ago
lbh_qys
6 hours ago
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Solve the equetion
yt12   4
N Today at 8:00 AM by lgx57
Solve the equetion:$\sin 2x+\tan x=2$
4 replies
yt12
Mar 31, 2025
lgx57
Today at 8:00 AM
J
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Inequalities
sqing   2
N Today at 7:41 AM by sqing
Let $ a, b,c\geq 0 $ and $ 2a+3b+ 4c=11.$ Prove that
$$a+ab+abc\leq\frac{49}{6}$$Let $ a, b,c\geq 0 $ and $ 2a+3b+ 4c=10.$ Prove that
$$a+ab+abc\leq\frac{169}{24}$$Let $ a, b,c\geq 0 $ and $ 2a+3b+ 4c=14.$ Prove that
$$a+ab+abc\leq\frac{63+5\sqrt 5}{6}$$Let $ a, b,c\geq 0 $ and $ 2a+3b+ 4c=32.$ Prove that
$$a+ab+abc\leq48+\frac{64\sqrt{2}}{3}$$
2 replies
sqing
Yesterday at 2:59 PM
sqing
Today at 7:41 AM
J
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geometry incentre config
Tony_stark0094   1
N Today at 7:38 AM by Tony_stark0094
In a triangle $\Delta ABC$ $I$ is the incentre and point $F$ is defined such that $F \in AC$ and $F \in \odot BIC$
prove that $AI$ is the perpendicular bisector of $BF$
1 reply
Tony_stark0094
Yesterday at 4:09 PM
Tony_stark0094
Today at 7:38 AM
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geometry
Tony_stark0094   1
N Today at 7:36 AM by Tony_stark0094
Consider $\Delta ABC$ let $\omega_1$ and $\omega_2$ be the circles passing through $A,B$ and $A,C$ respectively such that $BC$ is tangent to $\omega_1$ and $\omega_2$ define $R$ to be a point such that it lies on both the circles $\omega_1$ and $\omega_2$ prove that $HR$ and $AR$ are perpendicular.
1 reply
Tony_stark0094
Today at 7:04 AM
Tony_stark0094
Today at 7:36 AM
J
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one very nice!
MihaiT   1
N Today at 5:28 AM by MihaiT
Given $m_1$ weights, each weighing $k_1$ and another $m_2$ weights with $k_2$ each. Write a algorithm that determines the ways in which a scale can be balanced with a weight $X$ on the left pan, and display the number of possible solutions. (The weights can be placed on both pans and the program starts with the numbers $m_1,k_1,m_2,k_2,X$. What will be displayed after three successive runs: 5,2,5,1,4 | 5,2,5,1,11 | 5,2,5,1,20?

One answer is possible:
a)10;5;0;
b)20;7;0;
c)20;7;1;
d)10;10;0;
e)10;7;0;
f)20;5;0,
1 reply
MihaiT
Mar 31, 2025
MihaiT
Today at 5:28 AM
J
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School Math Problem
math_cool123   1
N Today at 5:12 AM by MathPerson12321
Find all ordered pairs of nonzero integers $(a, b)$ that satisfy $$(a^2+b)(a+b^2)=(a-b)^3.$$
1 reply
math_cool123
Today at 5:03 AM
MathPerson12321
Today at 5:12 AM
J
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Geo Mock #4
Bluesoul   1
N Today at 4:44 AM by Sedro
Consider acute triangle $ABC$ with orthocenter $H$. Extend $AH$ to meet $BC$ at $D$. The angle bisector of $\angle{ABH}$ meets the midpoint of $AD$. If $AB=10, BH=6$, compute the area of $\triangle{ABC}$.
1 reply
Bluesoul
Yesterday at 7:03 AM
Sedro
Today at 4:44 AM
J
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An inequality
JK1603JK   2
N Today at 3:24 AM by lbh_qys
Let a,b,c\ge 0: a+b+c=3 then prove \frac{1}{a+1}+\frac{1}{b+1}+\frac{1}{c+1}\le \frac{27}{2}\cdot\frac{1}{2ab+2bc+2ca+3}.
2 replies
JK1603JK
Today at 3:11 AM
lbh_qys
Today at 3:24 AM
J
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J
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All Russian Olympiad Day 1 P4
Davrbek   12
N Jul 23, 2024 by Mahdi_Mashayekhi
Source: Grade 11 P4
On the sides $AB$ and $AC$ of the triangle $ABC$, the points $P$ and $Q$ are chosen, respectively, so that $PQ\parallel BC$. Segments $BQ$ and $CP$ intersect at point $O$. Point $A'$ is symmetric to point $A$ relative to line $BC$. The segment $A'O$ intersects the circumcircle $w$ of the triangle $APQ$ at the point $S$. Prove that circumcircle of $BSC$ is tangent to the circle $w$.
12 replies
Davrbek
Apr 28, 2018
Mahdi_Mashayekhi
Jul 23, 2024
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All Russian Olympiad Day 1 P4
G H J
Reveal topic tags
geometry
moving points
L
G H BBookmark kLocked kLocked NReply
Source: Grade 11 P4
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Davrbek
252 posts
Davrbek
#1 Apr 28, 2018, 10:36 AM • 2 Y
Y by Adventure10, Mango247
On the sides $AB$ and $AC$ of the triangle $ABC$, the points $P$ and $Q$ are chosen, respectively, so that $PQ\parallel BC$. Segments $BQ$ and $CP$ intersect at point $O$. Point $A'$ is symmetric to point $A$ relative to line $BC$. The segment $A'O$ intersects the circumcircle $w$ of the triangle $APQ$ at the point $S$. Prove that circumcircle of $BSC$ is tangent to the circle $w$.
This post has been edited 3 times. Last edited by djmathman, Dec 18, 2018, 7:56 PM
Reason: formatting + wording
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TinaSprout
293 posts
TinaSprout
#2 Apr 28, 2018, 11:00 AM • 3 Y
Y by AlastorMoody, Adventure10, Mango247
See here
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Dr.Sop
206 posts
Dr.Sop
#3 Apr 28, 2018, 11:26 AM • 4 Y
Y by AlastorMoody, Yusuf3563_, Adventure10, Mango247
Lemma. $ABC$ given and $P, Q$ on $AB, AC$, $T= CP\cap BQ$, $R = AT\cap PQ$. Let $RH$ be the perpendicular from $R$ on $BC$, then $RH$ is angle $AHT$ bissector.

Now, in the main problem let $W$ is the circumcenter of $(APQ)$. Let the circle $\omega$ through $B, C$ is tangent to $(APQ)$ at $S'\not= A$. Consider the tangent line to $(ABC)$ at $A$ and intersect it with $BC$ at $L$. From radical center theorem we get that $S'L$ is tangent to $\omega$, $(APQ)$ at $S'$. Let the circle $(AS'LW)$ meet $BC$ at $L, J$. So $OJ\perp BC$. $WA = WS'$ and $AWS'J$ is cyclic, so $JW$ is angle $\angle S'JA$ bisector. Note that $OJ$ is passing through the middle of $PQ$ which coincides with $PQ\cap AO$, so from lemma we get that $J, S', O$ are collinear. From symmetry $A'\in JO$ and $S' = S$. $\Box$
This post has been edited 1 time. Last edited by Dr.Sop, Apr 28, 2018, 3:32 PM
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MarkBcc168
1594 posts
MarkBcc168
#4 Apr 28, 2018, 1:23 PM • 5 Y
Y by DanDumitrescu, Yusuf3563_, Adventure10, Mango247, ehuseyinyigit
Replace label $O$ with $K$ and let $O$ be the center of $\odot(ABC)$ instead. Let a line through $A$ parallel to $BC$ cut $\omega$ and $\odot(ABC)$ at $X,Y$ resp. Let $T$ be the circumcenter of $\Delta ASA'$, which clearly lies on $BC$.

First, note that $\Delta XPQ$ and $\Delta A'CB$ are hmothetic so $A', K, X$ are colinear. Moreover, if we let $A_1$ be the point diametrically opposite to $A$ w.r.t. $\odot(ABC)$. Then,
$$\measuredangle ASA' = \measuredangle ASX = \measuredangle AA_1Y = \measuredangle(AO, AA'). $$But $\measuredangle TAA' = \measuredangle ASA' - 90^{\circ}$ so $AT\perp AO$. Hence $TS^2=TA^2 = TB\cdot TC$ and we are done.
This post has been edited 2 times. Last edited by MarkBcc168, Apr 29, 2018, 12:51 AM
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anantmudgal09
1979 posts
anantmudgal09
#5 Apr 28, 2018, 9:56 PM • 2 Y
Y by Adventure10, Mango247
Davrbek wrote:
On the sides $AB$ and $AC$ of the triangle $ABC$, the points $P$ and $Q$ are chosen, respectively, so that $PQ||BC$. Segments of $BQ$
and $CP$ intersect at point $O$. Point $A'$ is symmetric to point $A$ relative to line$ BC$. The segment $A'O$ intersects
circle $w$ circumcircle of the triangle $APQ$, at the point $S$.
Prove that circumcircle of $BSC$ is tangent to the circle $w$.

Fix $k \in \mathbb{R}$ with $\overrightarrow{BC}=(1+k)\overrightarrow{PQ}$. Redefine $S \ne A$ as the point on $\omega$ with $\odot(BSC)$ tangent to $\omega$. Let tangent at $A$ to $\odot(ABC)$ meet $BC$ at $T$. By radical axis theorem applied to $\odot(BSC), \odot(ABC), \odot(APQ)$ we conclude that $ST$ is tangent to $\omega$.

Let $AA_1$ be an altitude in $\triangle ABC$; $S_1$ be the midpoint of $AS$; $O_1$ be the midpoint of $AO$. Now we need to show $A_1,S_1,O_1$ are collinear. Let $Y$ be the circumcenter of $\omega$. Suppose $AA_1MM_1$ is a rectangle. Let $X=AM_1 \cap A_1O_1$.

Claim. $\triangle AA_1X \sim \triangle ATY$

(Proof) Let $N$ be the circumcenter of $\triangle ABC$. Then $\triangle AM_1N \sim \triangle AA_1T$ so by spiral similarity, $\triangle ATN \sim \triangle AA_1M_1$ Now $\overrightarrow{AN}=(1+k)\overrightarrow{AY}$. Thus, we need $\overrightarrow{AM_1}=(1+k)\overrightarrow{AX}$ to conclude. Now observe by Van-Aubel's that $\tfrac{AO}{OM}=\tfrac{2}{k}$ hence $\tfrac{AX}{A_1M}=\tfrac{AO_1}{O_1M}=\tfrac{1}{(k+1)}$ which together with $A_1M=AM_1$ and directions proves the claim. $\blacksquare$

Finally, we observe $\angle AA_1X=\angle ATY=\angle ATS_1=\angle AA_1S_1$ as $ATA_1S_1$ is cyclic so $A_1,S_1,O_1$ are collinear.
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IstekOlympiadTeam
542 posts
IstekOlympiadTeam
#6 May 16, 2018, 4:21 PM • 4 Y
Y by tenplusten, Anar24, Adventure10, Mango247
Let the line parallel to $BC$ through $A$ and $A'O$ intersect at $S'$ and $\omega$ and $T=S'Q\cap BC$.

Claim: $APQS'$ is isosceles trapezoid and $A'BS'T$ is parallelogram.

Proof: Let $M=A'S\cap BC$. Let's show that $BM=MT$. By Menelaus's and Thales's Theorem \[\frac{TM}{MB}=\frac{OQ}{BO}\times\frac{S'T}{S'Q}=\frac{AP}{AB}\times\frac{AB}{AP}=1 \ (\bigstar)\]$\rightarrow$ $BM=MT$. On the other hand, parallelity of $AS'$ and $BC$ implies that $BC$ bisects the segment $A'S'$ as well. Therefore $MA=\boxed{MA'=MS'} \ (\bigstar\bigstar)$ in the right $A'AS'$ triangle $\rightarrow$ $\boxed{A'BS'T}$ is parallelogram.

Combining $(\bigstar)$,$(\bigstar\bigstar)$ and $AS'\parallel BT$ $\rightarrow$ $ABTS'$ and $\boxed{APQS'}$ isosceles trapezoid.
Back to main Problem: Let the tangent line to $\omega$ at $A$ and $BC$ intersect at $X$.It is enough to show that $XA=XS$ $\iff$ $X$ is center of circumcircle of triangle $AA'S$ $\iff$ $\frac{\angle AXA'}{2}+\angle ASA'=180^\circ$.But we have already got $\angle SAQ=\angle SS'Q=\angle BA'S'$ using the fact that $TQ\parallel BA'$ (See above). Finally, the last property of angles makes it easy to prove that$\frac{\angle AXA'}{2}+\angle ASA'=180^\circ$ with angle chasing. $\blacksquare$
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bobthesmartypants
4337 posts
bobthesmartypants
#7 Jul 25, 2018, 6:13 PM • 2 Y
Y by Adventure10, Mango247
solution
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nguyenhaan2209
111 posts
nguyenhaan2209
#8 Jul 12, 2019, 5:27 AM • 3 Y
Y by top1csp2020, Adventure10, Mango247
P',Q' sym P,Q wrt BC,PQ'-P'Q=E by Desargues for BQP'-CPQ': O lies on A'E. (E,EP) cuts AC,AB at H,I then I,H on (EP'B),(EQ'C) but AP.AI=AH.AC so A lies on radical center of (EP'B),(QE'C). Reflect wrt BC so A'E is radical center of (EPB),(EQC) so D lies on 2 circle but by Miquel D lies on (APQ) so D=O.
Thus PQO+OCB=PQE=PEB=POB so (APQ) tangent to (BSC)
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L567
1184 posts
L567
#9 Jan 2, 2023, 5:33 PM • 8 Y
Y by mathscrazy, jelena_ivanchic, TheProblemIsSolved, mxlcv, PROA200, Mango247, Mango247, Resolut1on07
This solution seems to be new. Solved with Sunaina Pati, Krutarth Shah, and Malay Mahajan.

Define $X$ to be the intersection of lines $OA'$ and $BC$ and $M$ be the midpoint of $PQ$. Supose $BC= s \cdot PQ$. By Ceva, we have that $A,M,O$ are collinear. But note that $$\frac{OX}{XA'} = \frac{d(O,BC)}{d(A',BC)} = \frac{d(O,BC)}{d(A,BC)} = \frac{s \cdot d(O,PQ)}{s \cdot d(A,PQ)} = \frac{OM}{MA}$$which means $XM$ and $AA'$ are parallel, giving $XP = XQ$.

Now, define $Y$ to be the reflection of $A'$ over $X$. Since $MX$ is parallel to $AA'$, we have that $d(Y,MX) = d(A',MX) = d(A,MX)$. But also, if $D$ is the foot of the $A$-altitude, $AY$ is parallel to $DX$ because of midpoints, and so $AY$ is parallel to $PQ$. These two together imply that $A$ is the reflection of $A$ over the perpendicular bisector of $PQ$ and hence lies on the circumcircle of $\triangle APQ$.

This gives that $\angle YSP = \angle YQP = \angle APQ = \angle ABC = \angle PQX$, implying that points $P,S,X,B$ are concyclic. Analogously, $Q,S,X,C$ are concyclic, so $S$ is the miquel point of $P,Q$ and $X$. To finish, we have that $\angle PSB = \angle PXB = \angle PQX = \angle PQS + \angle SQX = \angle PQS + \angle SCB$ so the circumcircles of $BSC$ and $APQ$ are tangent to each other, as desired. $\blacksquare$
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ike.chen
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ike.chen
#10 Apr 9, 2023, 7:30 PM
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Let $K$ be the point on $w$ such that $AK \parallel PQ$ and $T$ lie on $BC$ such that $TA$ is tangent to $(ABC)$. It's easy to see that $(ABC)$ and $w$ are tangent at $A$, so $TA$ is clearly the common tangent of $(ABC)$ and $w$.

Consider the homothety taking $QP$ to $BC$. Because $QP \parallel BC$, this homothety must be centered at $O$. Now, observe $$\measuredangle (KP, BC) = \measuredangle KPQ = \measuredangle KAQ = \measuredangle KAC = \measuredangle BCA = \measuredangle A'CB$$which means $KP \parallel A'C$. An analogous process yields $KQ \parallel A'B$. Combining these two results with $QP \parallel BC$, we conclude that the aforementioned homothety maps $KPQ$ to $A'CB$, so $K \in \overline{A'OS}$ follows immediately.

Since $AK \parallel \overline{TBC}$ follows from transitivity, symmetry implies $$\measuredangle ATA' = \measuredangle ATB + \measuredangle BTA' = 2 \measuredangle ATB$$$$= 2 \measuredangle TAK = 2 \measuredangle ASK = 2 \measuredangle ASA'.$$Hence, because $TA = TA'$ by symmetry, we know $T$ is the center of $(ASA')$.

Now, $TA = TS$ means $TS$ is tangent to $w$ by equal tangents and $$TS^2 = TA^2 = Pow_{(ABC)}(T) = TB \cdot TC$$implying $TS$ is tangent to $(BSC)$, which finishes. $\blacksquare$
This post has been edited 1 time. Last edited by ike.chen, Apr 14, 2023, 7:53 AM
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starchan
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starchan
#11 Aug 16, 2023, 11:56 AM
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always a fun day to do moving points!
solution
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NO_SQUARES
1073 posts
NO_SQUARES
#12 Mar 25, 2024, 10:43 AM
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Let $T=OS \cap \omega$.
Claim: $AT \parallel BC$.
If so, let tangent to $\omega$ at $A$ intersect $BC$ at $X$. By easy angle chasing we can get that $X$ is center of $(ASA')$ and so $XS^2=XA^2=XB\cdot XC$ (the last is since $(APQ)$ and $(ABC)$ are tangent) and we are done.
Sketch for proof of claim: fix $A, T, P, Q$ and move linearity $B, C$. Then points $O, A'$ also move linearity. We want to prove that $T, O, A'$ are collinear, so it's enough to check 3 cases.
1) $B=P$, $C=Q$, $O$ is a midpoint of $PQ$.
2) $B=A=C=A'=O$.
3) $BC$ is midline of $\Delta APQ$.
All cases are obvious (but in last I bashed in complex numbers...).
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Mahdi_Mashayekhi
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Mahdi_Mashayekhi
#13 Jul 23, 2024, 12:35 PM
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Let $A''$ be point on $APQ$ such that $AA'' \parallel BC$. Since $A''PQ$ and $A'CB$ are homothetic we have that $A''$ lies on $A'O$. Let $A'O$ meet $BC$ at $T$.
Claim $1 :PBTS$ and $QCTS$ are cyclic.
Proof $:$ Note that $\angle BTA' = \angle AA''S = \angle SPB$ so $PBTS$ is cyclic. we prove the other part with same approach.
Claim $2 :TP = TQ$.
Proof $:$ Note that $BC \parallel AA''$ and midpoint of $AA'$ lies on $BC$ so $T$ is midpoint of $A'A''$ and since $\angle A'AA'' = 90$ we have that $T$ lies on perpendicular bisector of $AA'$ and since $AA'QP$ is isosceles trapezoid we have that $T$ lies on perpendicular bisector of $PQ$ as well.
Now note that $\angle PSB = \angle PTB = \angle PQT = \angle PQS + \angle SQT = \angle PAS + \angle SCT$ so $BSC$ and $APQ$ are tangent.
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