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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
+1 w
rrusczyk
Mar 24, 2025
SmartGroot
Mar 26, 2025
J
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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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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
J
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A lot of numbers and statements
nAalniaOMliO   2
N 25 minutes ago by nAalniaOMIiO
Source: Belarusian National Olympiad 2025
101 numbers are written in a circle. Near the first number the statement "This number is bigger than the next one" is written, near the second "This number is bigger that the next two" and etc, near the 100th "This number is bigger than the next 100 numbers".
What is the maximum possible amount of the statements that can be true?
2 replies
nAalniaOMliO
Yesterday at 8:20 PM
nAalniaOMIiO
25 minutes ago
J
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USAMO 1981 #2
Mrdavid445   9
N 26 minutes ago by Marcus_Zhang
Every pair of communities in a county are linked directly by one mode of transportation; bus, train, or airplane. All three methods of transportation are used in the county with no community being serviced by all three modes and no three communities being linked pairwise by the same mode. Determine the largest number of communities in this county.
9 replies
Mrdavid445
Jul 26, 2011
Marcus_Zhang
26 minutes ago
J
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Monkeys have bananas
nAalniaOMliO   2
N 34 minutes ago by nAalniaOMIiO
Source: Belarusian National Olympiad 2025
Ten monkeys have 60 bananas. Each monkey has at least one banana and any two monkeys have different amounts of bananas.
Prove that any six monkeys can distribute their bananas between others such that all 4 remaining monkeys have the same amount of bananas.
2 replies
nAalniaOMliO
Yesterday at 8:20 PM
nAalniaOMIiO
34 minutes ago
J
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A number theory problem from the British Math Olympiad
Rainbow1971   12
N an hour ago by ektorasmiliotis
Source: British Math Olympiad, 2006/2007, round 1, problem 6
I am a little surprised to find that I am (so far) unable to solve this little problem:

[quote]Let $n$ be an integer. Show that, if $2 + 2 \sqrt{1+12n^2}$ is an integer, then it is a perfect square.[/quote]

I set $k := \sqrt{1+12n^2}$. If $2 + 2 \sqrt{1+12n^2}$ is an integer, then $k (=\sqrt{1+12n^2})$ is at least rational, so that $1 + 12n^2$ must be a perfect square then. Using Conway's topograph method, I have found out that the smallest non-negative pairs $(n, k)$ for which this happens are $(0,1), (2,7), (28,97)$ and $(390, 1351)$, and that, for every such pair $(n,k)$, the "next" such pair can be calculated as
$$ \begin{bmatrix} 7 & 2 \\ 24 & 7 \end{bmatrix} \begin{bmatrix} n \\ k \end{bmatrix} .$$The eigenvalues of that matrix are irrational, however, so that any calculation which uses powers of that matrix is a little cumbersome. There must be an easier way, but I cannot find it. Can you?

Thank you.




12 replies
+1 w
Rainbow1971
Yesterday at 8:39 PM
ektorasmiliotis
an hour ago
J
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A number theory about divisors which no one fully solved at the contest
nAalniaOMliO   22
N an hour ago by nAalniaOMliO
Source: Belarusian national olympiad 2024
Let's call a pair of positive integers $(k,n)$ interesting if $n$ is composite and for every divisor $d<n$ of $n$ at least one of $d-k$ and $d+k$ is also a divisor of $n$
Find the number of interesting pairs $(k,n)$ with $k \leq 100$
M. Karpuk
22 replies
nAalniaOMliO
Jul 24, 2024
nAalniaOMliO
an hour ago
J
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D1018 : Can you do that ?
Dattier   1
N an hour ago by Dattier
Source: les dattes à Dattier
We can find $A,B,C$, such that $\gcd(A,B)=\gcd(C,A)=\gcd(A,2)=1$ and $$\forall n \in \mathbb N^*, (C^n \times B \mod A) \mod 2=0 $$.

For example :

$C=20$
$A=47650065401584409637777147310342834508082136874940478469495402430677786194142956609253842997905945723173497630499054266092849839$

$B=238877301561986449355077953728734922992395532218802882582141073061059783672634737309722816649187007910722185635031285098751698$

Can you find $A,B,C$ such that $A>3$ is prime, $C,B \in (\mathbb Z/A\mathbb Z)^*$ with $o(C)=(A-1)/2$ and $$\forall n \in \mathbb N^*, (C^n \times B \mod A) \mod 2=0 $$?
1 reply
Dattier
Mar 24, 2025
Dattier
an hour ago
J
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Nordic 2025 P3
anirbanbz   8
N 2 hours ago by Primeniyazidayi
Source: Nordic 2025
Let $ABC$ be an acute triangle with orthocenter $H$ and circumcenter $O$. Let $E$ and $F$ be points on the line segments $AC$ and $AB$ respectively such that $AEHF$ is a parallelogram. Prove that $\vert OE \vert = \vert OF \vert$.
8 replies
anirbanbz
Mar 25, 2025
Primeniyazidayi
2 hours ago
J
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f( - f (x) - f (y))= 1 -x - y , in Zxz
parmenides51   6
N 2 hours ago by Chikara
Source: 2020 Dutch IMO TST 3.3
Find all functions $f: Z \to Z$ that satisfy $$f(-f (x) - f (y))= 1 -x - y$$for all $x, y \in Z$
6 replies
parmenides51
Nov 22, 2020
Chikara
2 hours ago
J
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Hard limits
Snoop76   2
N 3 hours ago by maths_enthusiast_0001
$a_n$ and $b_n$ satisfies the following recursion formulas: $a_{0}=1, $ $b_{0}=1$, $ a_{n+1}=a_{n}+b_{n}$$ $ and $ $$ b_{n+1}=(2n+3)b_{n}+a_{n}$. Find $ \lim_{n \to \infty} \frac{a_n}{(2n-1)!!}$ $ $ and $ $ $\lim_{n \to \infty} \frac{b_n}{(2n+1)!!}.$
2 replies
Snoop76
Mar 25, 2025
maths_enthusiast_0001
3 hours ago
J
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2025 Caucasus MO Seniors P2
BR1F1SZ   3
N 3 hours ago by X.Luser
Source: Caucasus MO
Let $ABC$ be a triangle, and let $B_1$ and $B_2$ be points on segment $AC$ symmetric with respect to the midpoint of $AC$. Let $\gamma_A$ denote the circle passing through $B_1$ and tangent to line $AB$ at $A$. Similarly, let $\gamma_C$ denote the circle passing through $B_1$ and tangent to line $BC$ at $C$. Let the circles $\gamma_A$ and $\gamma_C$ intersect again at point $B'$ ($B' \neq B_1$). Prove that $\angle ABB' = \angle CBB_2$.
3 replies
BR1F1SZ
Mar 26, 2025
X.Luser
3 hours ago
J
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IMO Shortlist 2010 - Problem G1
Amir Hossein   130
N 3 hours ago by LeYohan
Let $ABC$ be an acute triangle with $D, E, F$ the feet of the altitudes lying on $BC, CA, AB$ respectively. One of the intersection points of the line $EF$ and the circumcircle is $P.$ The lines $BP$ and $DF$ meet at point $Q.$ Prove that $AP = AQ.$

Proposed by Christopher Bradley, United Kingdom
130 replies
Amir Hossein
Jul 17, 2011
LeYohan
3 hours ago
J
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CGMO6: Airline companies and cities
v_Enhance   13
N 4 hours ago by Marcus_Zhang
Source: 2012 China Girl's Mathematical Olympiad
There are $n$ cities, $2$ airline companies in a country. Between any two cities, there is exactly one $2$-way flight connecting them which is operated by one of the two companies. A female mathematician plans a travel route, so that it starts and ends at the same city, passes through at least two other cities, and each city in the route is visited once. She finds out that wherever she starts and whatever route she chooses, she must take flights of both companies. Find the maximum value of $n$.
13 replies
v_Enhance
Aug 13, 2012
Marcus_Zhang
4 hours ago
J
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nice problem
hanzo.ei   0
4 hours ago
Source: I forgot
Let triangle $ABC$ be inscribed in the circumcircle $(O)$ and circumscribed about the incircle $(I)$, with $AB < AC$. The incircle $(I)$ touches the sides $BC$, $CA$, and $AB$ at $D$, $E$, and $F$, respectively. A line through $I$, perpendicular to $AI$, intersects $BC$, $CA$, and $AB$ at $X$, $Y$, and $Z$, respectively. The line $AI$ meets $(O)$ at $M$ (distinct from $A$). The circumcircle of triangle $AYZ$ intersects $(O)$ at $N$ (distinct from $A$). Let $P$ be the midpoint of the arc $BAC$ of $(O)$. The line $AI$ cuts segments $DF$ and $DE$ at $K$ and $L$, respectively, and the tangents to the circle $(DKL)$ at $K$ and $L$ intersect at $T$. Prove that $AT \perp BC$.
0 replies
hanzo.ei
4 hours ago
0 replies
J
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Find a given number of divisors of ab
proglote   9
N 4 hours ago by zuat.e
Source: Brazil MO 2013, problem #2
Arnaldo and Bernaldo play the following game: given a fixed finite set of positive integers $A$ known by both players, Arnaldo picks a number $a \in A$ but doesn't tell it to anyone. Bernaldo thens pick an arbitrary positive integer $b$ (not necessarily in $A$). Then Arnaldo tells the number of divisors of $ab$. Show that Bernaldo can choose $b$ in a way that he can find out the number $a$ chosen by Arnaldo.
9 replies
proglote
Oct 24, 2013
zuat.e
4 hours ago
J
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J
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Oi! These lines concur
Rg230403   20
N Mar 22, 2025 by MathLuis
Source: LMAO 2021 P5, LMAOSL G3(simplified)
Let $I, O$ and $\Gamma$ respectively be the incentre, circumcentre and circumcircle of triangle $ABC$. Points $A_1, A_2$ are chosen on $\Gamma$, such that $AA_1 = AI = AA_2$, and point $A'$ is the foot of the altitude from $I$ to $A_1A_2$. If $B', C'$ are similarly defined, prove that lines $AA', BB'$ and $CC'$ concurr on $OI$.
Original Version from SL
Proposed by Mahavir Gandhi
20 replies
Rg230403
May 10, 2021
MathLuis
Mar 22, 2025
J
Oi! These lines concur
G H J
Reveal topic tags
geometry
L
G H BBookmark kLocked kLocked NReply
Source: LMAO 2021 P5, LMAOSL G3(simplified)
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
Rg230403
222 posts
Rg230403
#1 May 10, 2021, 6:39 PM • 4 Y
Y by A-Thought-Of-God, samrocksnature, Ya_pank, ohhh
Let $I, O$ and $\Gamma$ respectively be the incentre, circumcentre and circumcircle of triangle $ABC$. Points $A_1, A_2$ are chosen on $\Gamma$, such that $AA_1 = AI = AA_2$, and point $A'$ is the foot of the altitude from $I$ to $A_1A_2$. If $B', C'$ are similarly defined, prove that lines $AA', BB'$ and $CC'$ concurr on $OI$.
Original Version from SL
Proposed by Mahavir Gandhi
This post has been edited 4 times. Last edited by Rg230403, May 13, 2021, 11:41 AM
Z K Y
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hellomath010118
373 posts
hellomath010118
#2 May 10, 2021, 7:03 PM • 4 Y
Y by samrocksnature, Ya_pank, math_comb01, Exposter
Note that $A'B'C'$ is the incircle of $\triangle ABC$ because of tangents from the midpoint of arc $BC$ not containing $A$ and poncelet.
Z K Y
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PUjnk
71 posts
PUjnk
#3 May 10, 2021, 7:03 PM • 3 Y
Y by samrocksnature, Mango247, Mango247
Very nice configurations

\input{fig1.tex}

%% write the problem proof here:

Let w denote the incircle of $\triangle{ABC},D,E,F$ are the intouch points. Let $P_D$ be the foot of perpendicular from D onto EF. $P_E,P_F$ are defined analogously.
{\textbf{Claim 1}}: YZ is tangent to $w$.

\begin{proof}
Let $M_D = DP_D \cap w$ and define $M_E,M_F$ analogously. Let the tangent to $w$ at $M_D$ meet AB, AC at $Z_1$ and $Y_1$ respectively. Now by Newton's Theorem on quadrilateral $BCY_1Z_1$, we have $BY_1 \cap CZ_1$ = $DM_D \cap EF = P_D$

$\Rightarrow P_D \in\ BY_1$ and $P_D \in CZ_1$
$\because Y = Y_1$ and $Z$ = $Z_1$.
This proves the claim.
\end{proof}

{\textbf{Claim 2}}:
Let M be any point on $\circledcirc{ABC}$. Let the tangents from X to
$w$ intersect $w $ at $Y_1$ , $Y_2$ and $BC$ extended at $X_1$ , $X_2$ and let the point of tangency between the A-Mixtilinear incircle and $\circledcirc{ABC}$ be $U$. Then $\circledcirc{MX_1X_2}$ passes through U.

%\begin{figure}
\input{fig2.tex}
%\end{figure}

\begin{proof}
Let $N$ = $AM\cap BC$
By Dual of Desargues Involution Theorem on complete quadrilateral $ABDC$ athrough $M$, giving the involutive pairing
($MA,MD); (MB, MC); (MY_1,MY_2$). Now projecting this onto line $BC$,
we get the pairs :
($MN,MD); (MB,MC); (MX_1,MX_2$). Now we know that every involution is an inversion about some center. Let this center be $K$.
$KB\times KC = KD\times KN = KX_1\times KX_2$. So
$\circledcirc{AMBC}$ , $\circledcirc{MDN} , \circledcirc{MX_1X_2}$ are
co- axial circles. So it suffices to prove $U \in\circledcirc{MDN}$.
Now let $DU \cap \circledcirc{ABC}$=$A_1$. By properties of mixtilinear incircles, $AA_1 \Vert BC$. $\because \angle ANB$ = $\angle A_1AM$ = $\angle DUM$. So $UDNM$ is cyclic as required.
\end{proof}

{\textbf{Claim 3}}:
Let $XY \cap\circledcirc{ABC}$ = $J$. Then the tangents from $X$ and $J$ to $w$ intersect at $\circledcirc{ABC}$.

\begin{proof}
Let the tangents from $X$ and $J$ to $w$ meet $BC$ at
$H$, $L$ and let $T$ = $YZ \cap BC$. Now by claim 1, $TX$ and $TH$ are tangent to $w$. So by claim 2, $\circledcirc{TXH}$ and $\circledcirc{TJL}$
pass through $U$.
$\Longrightarrow$ by Miquel's Theorem, $U$ is the miquel point of quadrilateral $XHLJ$.
$\because$ $XH \cap JL$ lies on $\circledcirc{XUJ}$ = $\circledcirc{ABC}$.
\end{proof}

{\textbf{Claim4}}: $M_D=A',M_E=B',M_F=C'$.

\begin{proof}:
We shall prove $M_d=A'$. The others can be proved analogously.
By Claim 3, we know that the tangents from $X$ and $J$ to $w$ intersect at $\circledcirc{ABC}$ at a point say K. Now w is the inscribed circle in $\triangle{XJK}$. So I is the incenter of $\triangle{XJK}$. Now we know $BCYZ$ is cyclic. So YZ is antiparallel to BC wrt $\angle{BAC}$. Now since, O is the circumcenter of $\triangle{ABC}, AO \perp XJ$. So $AX=AJ$.
Thus A is the midpoint of XJ in $\circledcirc{XJK}$. Now since I is the incenter of $\triangle{XJK}$, by incircle-excircle lemma, we have that $AX=AJ=AI$.
Thus $X=D$ and $J=E$. So $M_D$ is the foot of perpendicular from I onto DE which is exactly the definition of $A'$. This proves the claim.
\end{proof}

{\textbf{Claim 5}}: $\triangle{M_DM_EM_F}$ is similar to $\triangle{ABC}$

\begin{proof}:
Note that $\angle{M_DDF}=\angle{M_EDF}=\angle{M_EEF}=\frac{C}{2} \Longrightarrow \angle{M_DM_FM_E}=\angle{M_DDM_E}=C$.
Similarly it can be shown that $\angle{M_EM_DM_F}=A,\angle{M_DM_EM_F}=B$. This proves the claim.
\end{proof}

Back to the main problem, combining Claim 4 and Claim 5, we see that $\triangle{A'B'C'}$ is similar to $\triangle{ABC}$.
Thus there exists a centre of homothety T, swapping these two triangles.
Now since I is the circumcenter of $\triangle{A'B'C'}$ and O is the circumcenter of $\triangle{ABC}$, by properties of homothety, we have that $T \in IO$. We also notice that $AA',BB',CC'$ concur at T.
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srijonrick
168 posts
srijonrick
#4 May 10, 2021, 7:05 PM • 4 Y
Y by DebayuRMO, A-Thought-Of-God, samrocksnature, trigocalc
Hopefully correct.

Solution. Let $\odot(I)$ denote the incircle, $\odot(AI)$ the circle centered at $A$ with radius $AI$, and $(ABC)$ the circumcircle; $D, E, F$ the respective intouch points opposite to $A, B, C$ respectively, and $M_A$ the midpoint of arc $BC$ opposite to $A$.

Claim. $AI$ is the external bisector of $\angle A'ID$.

Proof. \[\measuredangle DIM_A = \measuredangle AM_AO = \measuredangle OAM_A = \measuredangle AIA'.\]As both $ID, OM_A$ are perpendicular to $BC$, and $IA', OA$ are perpendicular to $A_1A_2$ (the radical axis). $\quad\square$

Claim. $A' \in \odot(I)$.

Proof. Let the tangent from $M_A$ to $\odot(I)$ intersect $(ABC)$ at $A_1'$ and $A_2'$. So, by Poncelet's Porism $A_1'A_2'$ is tangent to $\odot(I)$. Now, by Fact 5 we get $AA_1' = AI = AA_2'$, so $A_1' \equiv A_1$ and $A_2' \equiv A_2$ (as $\odot(AI)$ and $(ABC)$ already intersect at $A_1, A_2$). So, $A_1A_2$ is tangent to $\odot(I)$, and that at $A'$ (using the right angle there). $\quad\square$

So, $ID=IA'$, and thus, the internal bisector of $\angle A'ID$ is perpendicular to $A'D$. This along with the first claim yields $DA' \parallel AI$. Hence, $DA' \perp EF$ (as $AI \perp EF$). So, $A'$ is the intersection of the perpendicular from $D$ to $EF$ with $\odot(I).$

Suppose $AA'$ meets $(ABC)$ at $T_A$.

Claim. $T_A$ is the $A$-mixtilinear intouch point.

Further let $\omega_A$ denote the $A$-mixtilinear incircle, and $E_1, F_1$ be the intouch points of $\omega_A$ on $AC, AB$ respectively.

Proof. Note that $AE \cdot AE_1=AF \cdot AF_1=AI^2$, so $\odot(I)$ and $\omega_A$ are inverses w.r.t $\odot(AI)$.

Let $E_1F_1$ intersect $BC$ at $Z$, as $ZI \perp AI$, so $ZI$ is tangent to both $\odot(AI)$ and $\odot (BIC)$, yielding $Z$ to lie on the radical axis of $(ABC)$ and $\odot(AI)$, and thus, $A'Z$ is the radical axis of $(ABC)$ and $\odot(AI)$ (since $A' \in A_1A_2$). In other words, $A'Z$ and $(ABC)$ are inverses w.r.t $\odot(AI)$.

On inverting w.r.t $\odot(AI)$, $A'$ goes to $T_A$. But, as $A' \in \odot(I)$, so $T_A \in \omega_A$ and we get the desired.$\quad\square$

Likewise define $T_B, T_C$, and get them as the $B, C$-mixtilinear intouch points; and further let $\omega_B$ and $\omega_C$ to be the respective mixtilinear incircles.

By Monge's theorem applied to $\omega_A, (ABC), \odot(I)$, we get the exsimilicenter of $(ABC)$ and $\odot(I)$ to lie on $AT_A$. Analogous holds for the lines $BT_B$ and $CT_C$. Whence, $OI, AT_A, BT_B, CT_C$ concur at $K$, the isogonal point of the Nagel point of $\triangle ABC$ (appealing to the well known fact that respective mixtilinear cevian acts as the isogonal of the Nagel line generating from the respective vertex; in other words $AT_A$ and $AQ_A$ are isogonals, where $Q_A$ is the $A$-extouch point on $BC$). Since $A' \in AT_A$, etc, we're done. $\quad \blacksquare$
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i3435
1350 posts
i3435
#5 May 10, 2021, 7:06 PM • 2 Y
Y by Aryan-23, samrocksnature
If I'm not mistaken SORY P6 was very similar.

Invert around $(A,AI)$. This takes $\overline{A_1A_2}$ to $(ABC)$ and takes the incircle to the $A$-mixtilinear incircle. Thus the incircle is tangent to $\overline{A_1A_2}$. Since $\overline{A_1A_2}\perp\overline{AO}$, $\overline{IA'}||\overline{AO}$. Thus the positive homothety taking the circumcircle to the incircle takes $A$ to $A'$, so $\overline{AA'}$ goes through the exsimillicenter of the incircle and circumcircle.
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Rg230403
222 posts
Rg230403
#6 May 10, 2021, 7:23 PM • 1 Y
Y by samrocksnature
Yes, that works. Can you please share what SORY P6 was? I have not seen that problem.
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Euler365
142 posts
Euler365
#7 May 10, 2021, 7:24 PM • 4 Y
Y by samrocksnature, Muaaz.SY, TheorM, MatBoy-123
The official solution
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hellomath010118
373 posts
hellomath010118
#8 May 10, 2021, 7:25 PM • 3 Y
Y by samrocksnature, math_comb01, Exposter
For @above
Rg230403 wrote:
Yes, that works. Can you please share what SORY P6 was? I have not seen that problem.
Attachments:
SORY_solutions.pdf (273kb)
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Rg230403
222 posts
Rg230403
#9 May 10, 2021, 7:40 PM • 1 Y
Y by samrocksnature
Oh I see, I think configurations of this sort have been explored. We did not know how much of it has appeared before, but I think it still serves well as an easy problem. The test-solvers and contestants had not seen the results beforehand on the basis of the response we have received.
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Psyduck909
95 posts
Psyduck909
#10 May 10, 2021, 9:42 PM • 1 Y
Y by samrocksnature
Very cool problem! Here is the solution I submitted (cleaned it up a bit :P) .
Let $A_1A_2 \cap B_1B_2=X$, and define $Y,Z$ similarly. The key claim of the problem is that $I$ is incenter of $\triangle XYZ$.

Since $B_1,B_2,A_1,A_2$ are concyclic, we deduce that $X$ lies on the radical axis of $(A)$ and $(B)$ $\Rightarrow AB \perp XI$ and similarly.

Let $A_1A_2 \cap AB=V,B_1B_2 \cap AB=U$. Note that $$\measuredangle BB_1U=\measuredangle BB_1B_2=\measuredangle B_1B_2B=\measuredangle B_1AB \Rightarrow \triangle BUB_1 \sim \triangle BB_1A$$and similarly $\triangle AA_1V \sim \triangle ABA_1$. But $\measuredangle BB_1A=\measuredangle BA_1A$ so we have $\measuredangle XUV=\measuredangle UVX$. Since $\triangle VXU$ is isoceles and $XI \perp \overline{UV}\equiv \overline{AB}$, we deduce $\measuredangle VXI= \measuredangle IXU$. Since similar results hold, we deduce that $I$ is the incenter of $\triangle XYZ$.

Now simply note that $AA_1=AA_2 \Rightarrow A_1A_2 \perp AO$, and similarly. Thus, we have $\triangle A'IB'$ and $\triangle AOB$ are isoceles with two sides parallel, so $AA',BB',OI$, and similarly $CC'$ as well, concur at the center of homothety of the two circles and we are done.
Attachments:
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GeoMetrix
924 posts
GeoMetrix
#11 May 11, 2021, 5:02 AM • 2 Y
Y by samrocksnature, Muaaz.SY
Let $M_A$ be the midpoint of arc $\widehat{BC}$ not containing $A$. Let $A_1',A_2'$ be points on $\odot(ABC)$ such that $\overline{M_AA_1'}$ and $\overline{M_AA_2'}$ are tangent to incircle of $\triangle{ABC}$

Claim 1: $\overline{AA_1'} = \overline{AA_2'}$
Proof: Obviously $\overline{M_AI}$ is the angle bisector of $\angle A_1'M_AA_2'$. Hence the result. $\qquad \square$

Claim 2: $\overline{A_1'A_2'}$ is tangent to incircle of $\triangle{ABC}$
Proof: Poncelets porism. $\qquad \square$

Claim 3: $\overline{AI} = \overline{AA_1'} = \overline{AA_2'}$. Thus $\{A_1',A_2'\} = \{A_1,A_2\}$.
Proof: From previous results we get that $I$ is the incenter of $\triangle{M_AA_1'A_2'}$ and the result follows from fact 5 $\qquad \square$

Now clearly $A'$ is the tangency point of $\overline{A_1A_2}$ with incircle of $\triangle{ABC}$ and let $D,E,F$ be the tangency points of incircle with $\overline{BC},\overline{CA},\overline{AB}$ respectively.

Claim 4: $\overline{DA'} \perp \overline{EF}$
Proof: Now notice that clearly $\overline{IA'} \parallel \overline{AO}$. Let $T$ be the midpoint of $\widehat{EF}$ not containing $D$ in incircle of $\triangle{ABC}$ and let $D'$ be the $D$ antipode in the incircle. Now we have that $$\angle A'IT = \angle IAO = \angle OM_AA = \angle DIM_A = \angle D'IT$$but this would clearly imply $\overline{DA'},\overline{DD'}$ are isogonal w.r.t $\angle{EDF}$ and hence done $\qquad \square$

Claim 5: $\overline{A'B'} \parallel {AB}$ similiarly for others.
Proof: $\overline{IF} \perp \overline{AB}$ and also $$\angle FA'B'=\angle FEB' = 90^\circ -\angle EFD = \angle A'DF = \angle A'B'F$$so $\overline{IF} \perp \overline{A'B'}$ $\qquad \square$

Now just apply homothety on $\triangle{A'B'C'}$ and $\triangle{ABC}$ to finish $\qquad \blacksquare$
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L567
1184 posts
L567
#12 May 11, 2021, 5:11 AM • 2 Y
Y by p_square, samrocksnature
Here's another way to get that $A_1A_2$ is tangent to the incircle.

Let $A_1A_2$ meet $AB,AC$ at $X,Y$. Let $\angle AA_2A_1 = \angle AA_1A_2 = x$

Then, we can easily get that $\triangle AXY \sim \triangle ACB$.

Since $\angle AA_1Y = \angle YCA_1$, $AA_1$ is tangent to $(A_1YC)$ and so $AA_1^2= AY.AC$.

Since $AI = AA_1$, $AI^2 = AY.AC$ and so $AI$ is tangent to $(IYC)$ and so $\angle AIY = \angle ICY$ and now its easy enough to prove by angel chasing that $I$ is the A-excenter in $\triangle AXY$. So because $AX,AY$ are already tangent to the incircle, it must be the excircle. So, $A_1A_2$ is tangent to the incircle
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khina
993 posts
khina
#13 May 13, 2021, 11:44 PM
Y by
why are the solutions above so ridiculously complicated >.<

Note that $AO$ is perpendicular to $A_1A_2$. Thus, it suffices to prove that the ratio between the distance from $I$ to $A_1A_2$, and $AO$, is constant (when replaced with $B$ and $C$ instead). Since $AO$ is just the circumradius of $ABC$ it suffices to prove $I$ is equidistant from $A_1A_2$, $B_1B_2$, and $C_1C_2$.

We in fact claim all three lines are tangent to the incircle of $ABC$, which finishes. Indeed, let $AI \cap (ABC) = A, M$, and let the tangents from $M$ to the incircle of $ABC$ meet the circumcircle of $ABC$ again at $X$ and $Y$. Note by Poncelet's Porism, $XY$ is tangent to the incircle of $ABC$ as well. Now by fact five $AX = AI = AY$, so $\{ X, Y \}$ is some permutation of $\{A_1, A_2 \}$, and so we are done!
This post has been edited 2 times. Last edited by khina, May 13, 2021, 11:47 PM
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KST2003
173 posts
KST2003
#14 May 14, 2021, 3:29 PM • 1 Y
Y by Mango247
Here is a way to sneakily avoid Poncelet's Porism using (one of many) Euler's Formula.

Let $\triangle DEF$ and $\triangle D'E'F'$ be the intouch triangle and circumcevian triangle of $I$. By the incenter lemma, it follows that $I$ is the incenter of $\triangle D'A_1A_2$, and by Euler's formula, the inradius of $\triangle ABC$ is the same as that of $\triangle A_1A_2D'$, so it follows that they share the same incircle. Now let $\overline{A_1A_2}$ cut $\overline{AB}$ and $\overline{AC}$ at $X$ and $Y$ respectively. Then as $AO\perp A_1A_2$ ,
\[\measuredangle AYX=90^\circ-\measuredangle OAC=\measuredangle CBA\]and thus quadrilateral $XYCB$ is bicentric. It is then well-known that $DA'\perp EF$. (This can be easily proven via angle chasing.) Similarly, we can deduce that $EB'\perp DF$, and $FC'\perp DE$. Since $\triangle DEF$ and $\triangle D'E'F'$ are homothetic, $\triangle ABC$ and $\triangle A'B'C'$ must also be homothetic as well. Therefore, $\overline{AA'}$, $\overline{BB'}$ and $\overline{CC'}$ are concurrent at the homothetic center of two triangles, which lies on $\overline{OI}$.
This post has been edited 2 times. Last edited by KST2003, May 14, 2021, 3:37 PM
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SPHS1234
466 posts
SPHS1234
#15 Oct 31, 2021, 5:58 AM
Y by
L567 wrote:
Here's another way to get that $A_1A_2$ is tangent to the incircle.
Inverting at $A$ with radius $AI$ maps the incircle to the $A-$ mixtilinear incircle (can be easily proved).
Also $A_1A_2$ goes to the circumcircle of $\triangle ABC$.
Simple homothety:$OA || IA'$ , the ratios $\frac{OA}{IA'}=\frac{R}{r}$ are constant and $O$ and $I$ are the circumcenters of $ABC$ and $A'B'C'$ ....
This post has been edited 1 time. Last edited by SPHS1234, Oct 31, 2021, 5:58 AM
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math_comb01
662 posts
math_comb01
#16 Dec 25, 2023, 3:39 PM
Y by
Funny Problem.
We make use of following 3 well-known claims
Claim 1: $A_1A_2$ is tangent to incircle at $P$ s.t. $DP \perp EF$
Claim 2 IF $T_a$ is the mixti touch point then $A-P-T_a$
Claim 3: $AT_a,BT_b,CT_c,OI$ concurr
Hence we're done
This post has been edited 1 time. Last edited by math_comb01, Dec 25, 2023, 3:39 PM
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ezpotd
1251 posts
ezpotd
#17 Aug 2, 2024, 3:33 AM
Y by
woah...

Let $M_a$ be the arc midpoint of $BC$ and cyclic variants. By Poncelet's Porism, there exist two unique points $X,Y$ such that $M_aXY$ has both the same circumcircle and incircle as $ABC$. Since $M_aI$ is the bisector of $\angle M_aY$, we can in fact conclude the arc midpoint of $XY$ is $A$, thus the center of $(XYI)$ is $A$, clearly forcing $A_1$, $A_2$ = $X$, $Y$. Thus the foot from $I$ to $A_1A_2$ lies on the incircle.

Let $AA'$ meet $OI$ at $K$. We prove $\frac{KI}{KO}$ is symmetric in $AB$ , $BC$, $AC$. Since $IA'$ is parallel to $AO$, we just want $\frac{IA'}{AO} = \frac rR$, so we are done.
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L13832
252 posts
L13832
#18 Mar 19, 2025, 1:14 PM
Y by
SORY P6

solution
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HoRI_DA_GRe8
588 posts
HoRI_DA_GRe8
#19 Mar 20, 2025, 6:23 PM • 1 Y
Y by ohhh
I've done tooooooo much config geo in life.

Invert at $A$ with radius $AI$.Note that the incircle and the mixtillinear incircle gets swapped and $(ABC)$ gets swapped to $A_1A_2$. So the incircle is tangent to $A_1A_2$ as well.Also note that $A,A',T_A$ become collinear since $A'$ becomes the tangency point of the incircle with $A_1A_2$ and on inversion it swaps with $T_A$ (the $A-$mixtillinear intouch point).Now it's well known that $AT_A,BT_B,CT_C,OI$ are concurrent and we are done $\blacksquare$

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cursed_tangent1434
558 posts
cursed_tangent1434
#20 Mar 22, 2025, 12:13 PM
Y by
We barely need to prove anything at all here. We claim that the concurrency point is actually the exsimilicenter of the incircle and excircle $X_{56}$. We shall now show why this is true. The main claim is the following.

Claim : The incircle of $\triangle ABC$ is tangent to $\overline{A_1A_2}$ at $A'$ (and similarly).

Proof : Let $M$ denote the minor $BC$ arc midpoint and let $A_1'$ and $A_2'$ be the second intersections of the tangents from $M$ to the incircle. By Poncelet's Porism for triangles and circles we have that $A_1'A_2'$ is in fact tangent to the incircle as well. Thus, $I$ must be the incenter of $\triangle MA_1'A_2'$. Since points $A$ , $I$ and $M$ are collinear, $A$ must be the minor $A_1'A_2'$ arc midpoint and thus Incenter/Excenter Lemma tells us that $AI=AA_1'=AA_2'$. Thus, $A_1'$ and $A_2'$ are the intersections of the circle with center $A$ and radius $AI$ which implies that $\{A_1,A_2\}=\{A_1',A_2'\}$ which implies that $\overline{A_1A_2}$ is tangent to the incircle. The $M-$ intouch point must be the foot of the perpendicular from $I$ to side $A_1A_2$ which implies the claim.

Now note that since $AO$ is the perpendicular bisector of segment $A_1A_2$ we have that $OA \perp A_1A_2 \perp IA'$. Thus, $IA' \parallel OA$. Let $AA' \cap IO = X_{56}'$. Note that the homothety centered at $X_{56}'$ mapping $I$ to $O$ maps $A'$ (on the incircle) to $A$ (on the circumcircle). Thus, $X_{56}' \equiv X_{56}$ as it must be the exsimilicenter of the incircle and circumcircle. This implies that $AA'$ passes through $A'$. A similarl argument on the other two sides proves that $AA', BB'$ and $CC'$ concur on $X_{56}$ which is well known to lie on $OI$.
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MathLuis
1470 posts
MathLuis
#21 Mar 22, 2025, 1:32 PM • 1 Y
Y by L13832
Knowledge test.
Basically let $M_A$ midpoint of minor arc $BC$ and let $N_A$ midpoint of arc $BAC$ on $\Gamma$ then let $T_A$ be $N_AI \cap \Gamma=T_A$ be the A-mixtilinear intouch point by $\sqrt{bc}$ invert but now from Poncelet and I-E Lemma we have that $M_AA_1, M_AA_2$ are tangent to the incircle of $\triangle ABC$ and from $\triangle A_1M_AA_2$ perspective $T_A$ is the A-sharkydevil point and thus from miquel ratios we get that $T_A,A',A$ are colinear and from Monge we get that $AT_A$ goes through $X_{56}$ which lies on $OI$ as it is exsimillicenter of incircle and $\Gamma$ in $\triangle ABC$ thus repeating this cyclically we are done :cool:.
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