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

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0 replies
jlacosta
May 1, 2025
0 replies
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k i Adding contests to the Contest Collections
dcouchman   1
N Apr 5, 2023 by v_Enhance
Want to help AoPS remain a valuable Olympiad resource? Help us add contests to AoPS's Contest Collections.

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


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


More specifically:

For new threads:


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

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


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

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


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


For answers to already existing threads:


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

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



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


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

The above rules will be applied from next monday (5. march of 2007).
Feel free to discuss on this here.
49 replies
ZetaX
Feb 27, 2007
NoDealsHere
May 4, 2019
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2-var inequality
sqing   14
N 21 minutes ago by ytChen
Source: Own
Let $ a,b> 0 ,a^3+ab+b^3=3.$ Prove that
$$ (a+b)(a+1)(b+1) \leq 8$$$$ (a^2+b^2)(a+1)(b+1) \leq 8$$Let $ a,b> 0 ,a^3+ab(a+b)+b^3=3.$ Prove that
$$ (a+b)(a+1)(b+1) \leq \frac{3}{2}+\sqrt[3]{6}+\sqrt[3]{36}$$
14 replies
sqing
Saturday at 1:35 PM
ytChen
21 minutes ago
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Projective geo
drmzjoseph   1
N 28 minutes ago by Luis González
Any pure projective solution? I mean no metrics, Menelaus, Ceva, bary, etc
Only pappus, desargues, dit, etc
Btw prove that $X',P,K$ are collinear, and $P,Q$ are arbitrary points
1 reply
drmzjoseph
Mar 6, 2025
Luis González
28 minutes ago
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interesting geo config (2/3)
Royal_mhyasd   6
N 39 minutes ago by Diamond-jumper76
Source: own
Let $\triangle ABC$ be an acute triangle and $H$ its orthocenter. Let $P$ be a point on the parallel through $A$ to $BC$ such that $\angle APH = |\angle ABC-\angle ACB|$. Define $Q$ and $R$ as points on the parallels through $B$ to $AC$ and through $C$ to $AB$ similarly. If $P,Q,R$ are positioned around the sides of $\triangle ABC$ as in the given configuration, prove that $P,Q,R$ are collinear.
6 replies
Royal_mhyasd
Saturday at 11:36 PM
Diamond-jumper76
39 minutes ago
J
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equal segments on radiuses
danepale   9
N 41 minutes ago by mshtand1
Source: Croatia TST 2016
Let $ABC$ be an acute triangle with circumcenter $O$. Points $E$ and $F$ are chosen on segments $OB$ and $OC$ such that $BE = OF$. If $M$ is the midpoint of the arc $EOA$ and $N$ is the midpoint of the arc $AOF$, prove that $\sphericalangle ENO + \sphericalangle OMF = 2 \sphericalangle BAC$.
9 replies
danepale
Apr 25, 2016
mshtand1
41 minutes ago
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Is there a good solution?
sadwinter   3
N an hour ago by sadwinter
:maybe: :love: :love:
3 replies
sadwinter
Yesterday at 9:47 AM
sadwinter
an hour ago
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IMO Shortlist 2014 N2
hajimbrak   33
N 2 hours ago by Maximilian113
Determine all pairs $(x, y)$ of positive integers such that \[\sqrt[3]{7x^2-13xy+7y^2}=|x-y|+1.\]
Proposed by Titu Andreescu, USA
33 replies
hajimbrak
Jul 11, 2015
Maximilian113
2 hours ago
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Beautiful geo but i cant solve this
phonghatemath   1
N 2 hours ago by Diamond-jumper76
Source: homework
Given triangle $ABC$ inscribed in $(O)$. Two points $D, E$ lie on $BC$ such that $AD, AE$ are isogonal in $\widehat{BAC}$. $M$ is the midpoint of $AE$. $K$ lies on $DM$ such that $OK \bot AE$. $AD$ intersects $(O)$ at $P$. Prove that the line through $K$ parallel to $OP$ passes through the Euler center of triangle $ABC$.

Sorry for my English!
1 reply
phonghatemath
Yesterday at 4:48 PM
Diamond-jumper76
2 hours ago
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Numbers on cards (again!)
popcorn1   79
N 2 hours ago by ezpotd
Source: IMO 2021 P1
Let $n \geqslant 100$ be an integer. Ivan writes the numbers $n, n+1, \ldots, 2 n$ each on different cards. He then shuffles these $n+1$ cards, and divides them into two piles. Prove that at least one of the piles contains two cards such that the sum of their numbers is a perfect square.
79 replies
popcorn1
Jul 20, 2021
ezpotd
2 hours ago
J
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prove that at least one of them is divisible by some other member of the set.
Martin.s   1
N 2 hours ago by Diamond-jumper76
Given \( n + 1 \) integers \( a_1, a_2, \ldots, a_{n+1} \), each less than or equal to \( 2n \), prove that at least one of them is divisible by some other member of the set.
1 reply
Martin.s
Yesterday at 7:03 PM
Diamond-jumper76
2 hours ago
J
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interesting incenter/tangent circle config
LeYohan   1
N 2 hours ago by Diamond-jumper76
Source: 2022 St. Mary's Canossian College F4 Final Exam Mathematics Paper 1, Q 18d of 18 (modified)
$BC$ is tangent to the circle $AFDE$ at $D$. $AB$ and $AC$ cut the circle at $F$ and $E$ respectively. $I$ is the in-centre of $\triangle ABC$, and $D$ is on the line $AI$. $CI$ and $DE$ intersect at $G$, while $BI$ and $FD$ intersect at $P$. Prove that the points $P, F, G, E$ lie on a circle.
1 reply
LeYohan
Yesterday at 8:29 PM
Diamond-jumper76
2 hours ago
J
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Channel name changed
Plane_geometry_youtuber   1
N 2 hours ago by ektorasmiliotis
Hi,

Due to the search handle issue in youtube. My channel is renamed to Olympiad Geometry Club. And the new link is as following:

https://www.youtube.com/@OlympiadGeometryClub

Recently I introduced the concept of harmonic bundle. I will move on to the conjugate median soon. In the future, I will discuss more than a thousand theorems on plane geometry and hopefully it can help to the students preparing for the Olympiad competition.

Please share this to the people may need it.

Thank you!
1 reply
Plane_geometry_youtuber
5 hours ago
ektorasmiliotis
2 hours ago
J
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Integral ratio of divisors to divisors 1 mod 3 of 10n
cjquines0   20
N 2 hours ago by ezpotd
Source: 2016 IMO Shortlist N2
Let $\tau(n)$ be the number of positive divisors of $n$. Let $\tau_1(n)$ be the number of positive divisors of $n$ which have remainders $1$ when divided by $3$. Find all positive integral values of the fraction $\frac{\tau(10n)}{\tau_1(10n)}$.
20 replies
cjquines0
Jul 19, 2017
ezpotd
2 hours ago
J
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Kids in clubs
atdaotlohbh   1
N 2 hours ago by Diamond-jumper76
There are $6k-3$ kids in a class. Is it true that for all positive integers $k$ it is possible to create several clubs each with 3 kids such that any pair of kids are both present in exactly one club?
1 reply
atdaotlohbh
Yesterday at 7:24 PM
Diamond-jumper76
2 hours ago
J
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parallel wanted, right triangle, circumcircle, angle bisector related
parmenides51   6
N 3 hours ago by Ianis
Source: Norwegian Mathematical Olympiad 2020 - Abel Competition p4b
The triangle $ABC$ has a right angle at $A$. The centre of the circumcircle is called $O$, and the base point of the normal from $O$ to $AC$ is called $D$. The point $E$ lies on $AO$ with $AE = AD$. The angle bisector of $\angle CAO$ meets $CE$ in $Q$. The lines $BE$ and $OQ$ intersect in $F$. Show that the lines $CF$ and $OE$ are parallel.
6 replies
parmenides51
Apr 26, 2020
Ianis
3 hours ago
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J
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INMO 2018 -- Problem #3
integrated_JRC   44
N Apr 30, 2025 by bjump
Source: INMO 2018
Let $\Gamma_1$ and $\Gamma_2$ be two circles with respective centres $O_1$ and $O_2$ intersecting in two distinct points $A$ and $B$ such that $\angle{O_1AO_2}$ is an obtuse angle. Let the circumcircle of $\Delta{O_1AO_2}$ intersect $\Gamma_1$ and $\Gamma_2$ respectively in points $C (\neq A)$ and $D (\neq A)$. Let the line $CB$ intersect $\Gamma_2$ in $E$ ; let the line $DB$ intersect $\Gamma_1$ in $F$. Prove that, the points $C, D, E, F$ are concyclic.
44 replies
integrated_JRC
Jan 21, 2018
bjump
Apr 30, 2025
J
INMO 2018 -- Problem #3
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Reveal topic tags
geometry
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G H BBookmark kLocked kLocked NReply
Source: INMO 2018
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integrated_JRC
3465 posts
integrated_JRC
#1 Jan 21, 2018, 11:53 AM • 4 Y
Y by samrocksnature, Adventure10, Mango247, Rounak_iitr
Let $\Gamma_1$ and $\Gamma_2$ be two circles with respective centres $O_1$ and $O_2$ intersecting in two distinct points $A$ and $B$ such that $\angle{O_1AO_2}$ is an obtuse angle. Let the circumcircle of $\Delta{O_1AO_2}$ intersect $\Gamma_1$ and $\Gamma_2$ respectively in points $C (\neq A)$ and $D (\neq A)$. Let the line $CB$ intersect $\Gamma_2$ in $E$ ; let the line $DB$ intersect $\Gamma_1$ in $F$. Prove that, the points $C, D, E, F$ are concyclic.
This post has been edited 1 time. Last edited by integrated_JRC, Jan 22, 2018, 2:10 AM
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Kayak
1298 posts
Kayak
#2 Jan 21, 2018, 11:55 AM • 4 Y
Y by lneis1, samrocksnature, Adventure10, Mango247
After Inverting at $B$, the problem becomes trivial. (B becomes ortho centre of A*C*D* )
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AnArtist
1590 posts
AnArtist
#3 Jan 21, 2018, 12:08 PM • 5 Y
Y by Aryan-23, samrocksnature, Adventure10, Mango247, Rounak_iitr
$BE$ is a diameter of $T_2$.
$BF$ is a diameter of $T_1$.

And you obtain $FEA$ is a straight line parrallel to $O_1O_2$.

And rest is angle chasing.
This post has been edited 1 time. Last edited by AnArtist, Jun 12, 2018, 12:52 PM
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Vrangr
1600 posts
Vrangr
#4 Jan 21, 2018, 12:23 PM • 4 Y
Y by AG234, govind7701, samrocksnature, Adventure10
$$2\angle CFE = 2\angle BFC = \angle BO_1C = \angle O_1CO_2 - \angle O_1BO_2 = \angle O_1DO_2 - \angle O_1BO_2$$$$=\angle CO_2B = \angle CO_2B = 2\angle CFB = 2\angle CFD \ \blacksquare$$
This post has been edited 1 time. Last edited by Vrangr, Jan 21, 2018, 12:43 PM
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Drunken_Master
328 posts
Drunken_Master
#5 Jan 21, 2018, 12:30 PM • 5 Y
Y by DynamoBlaze, Arhaan, samrocksnature, Adventure10, Siddharthmaybe
Let $O_1B$ meet $\Gamma_2$ at $D'$, we have
$$\angle BDO_2=\angle DBO_2=180-\angle O_1BO_2=180-\angle O_1AO_2$$.
Hence $AO_1O_2D'$ is cyclic implying $D'=D$ giving $O_1,B,D$ are collinear. Similarly, $O_2,B,C$ are collinear.

This gives $BE$ and $BF$ are diameters of $\Gamma_2$ and $\Gamma_1$ respectively, giving $\angle FCE=\angle EDF=90$.

Hence, alternate interior angles are equal and we are done!
This post has been edited 1 time. Last edited by Drunken_Master, Jan 21, 2018, 12:31 PM
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Mathphile01
2527 posts
Mathphile01
#6 Jan 21, 2018, 12:32 PM • 2 Y
Y by samrocksnature, Adventure10
rd1452002 wrote:
$$2\angle CFE = 2\angle BFC = \angle BO_1C = \angle O_1CO_2 - \angle O_1BO_2 = \angle O_1DO_2 - \angle O_1BO_2$$$$\angle CO_2B = \angle CO_2B = 2\angle CFB = 2\angle CFD \ \blacksquare$$

My solution
:)
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AnArtist
1590 posts
AnArtist
#7 Jan 21, 2018, 12:34 PM • 3 Y
Y by The-X-squared-factor, samrocksnature, Adventure10
Drunken_Master wrote:
Let $O_1B$ meet $\Gamma_2$ at $D'$, we have
$$\angle BDO_2=\angle DBO_2=180-\angle O_1BO_2=180-\angle O_1AO_2$$.
Hence $AO_1O_2D'$ is cyclic implying $D'=D$ giving $O_1,B,D$ are collinear. Similarly, $O_2,B,C$ are collinear.

This gives $BE$ and $BF$ are diameters of $\Gamma_2$ and $\Gamma_1$ respectively, giving $\angle FCE=\angle EDF=90$.

Hence, alternate interior angles are equal and we are done!

Same solution. I wonder why did they give only one geo this year.
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Drunken_Master
328 posts
Drunken_Master
#8 Jan 21, 2018, 12:38 PM • 3 Y
Y by samrocksnature, Adventure10, Mango247
AnArtist wrote:
Drunken_Master wrote:
Let $O_1B$ meet $\Gamma_2$ at $D'$, we have
$$\angle BDO_2=\angle DBO_2=180-\angle O_1BO_2=180-\angle O_1AO_2$$.
Hence $AO_1O_2D'$ is cyclic implying $D'=D$ giving $O_1,B,D$ are collinear. Similarly, $O_2,B,C$ are collinear.

This gives $BE$ and $BF$ are diameters of $\Gamma_2$ and $\Gamma_1$ respectively, giving $\angle FCE=\angle EDF=90$.

Hence, alternate interior angles are equal and we are done!

Same solution. I wonder why did they give only one geo this year.

Usually they give 2 to 2.5 geo
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Vrangr
1600 posts
Vrangr
#10 Jan 21, 2018, 1:07 PM • 3 Y
Y by AlastorMoody, samrocksnature, Adventure10
I prepared for 2-3 geometry questions because I am weak in geometry. Only 1 came :/
I should spent that time doing combi or algebra.
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arulxz
449 posts
arulxz
#11 Jan 21, 2018, 2:39 PM • 3 Y
Y by mueller.25, samrocksnature, Adventure10
Prove by angle chasing that $B$ is the incenter of $\triangle ACD$.
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TheDarkPrince
3042 posts
TheDarkPrince
#12 Jan 21, 2018, 3:09 PM • 5 Y
Y by Drunken_Master, Maths_Guy, FadingMoonlight, samrocksnature, Adventure10
Found a nice solution in the exam using phantom points!
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TheDarkPrince
3042 posts
TheDarkPrince
#13 Jan 21, 2018, 3:51 PM • 7 Y
Y by Maths_Guy, hydrohelium, Spiralflux789, FadingMoonlight, samrocksnature, Adventure10, Mango247
My solution (something like this): Let $O_1B \cap \Gamma_2 = D'$ and $O_2B \cap \Gamma_1 = C'$.

As $\triangle O_1D'A$ is not isosceles, $\angle AO_1O_2 = \angle O_2O_1B = \angle O_2O_1D'$ and $\angle O_2AD'=\angle O_2D'A$ gives $O_1AO_2D'$ is cyclic. So, $D'\equiv D$. Similarly, $C'\equiv C$.
Proved.
This post has been edited 1 time. Last edited by TheDarkPrince, Jan 21, 2018, 3:51 PM
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Mate007
69 posts
Mate007
#14 Jan 23, 2018, 1:09 AM • 3 Y
Y by samrocksnature, Adventure10, Mango247
We can also use the concept of projective geometry to show O1,B,Dand F collinear.
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absur_siam
1 post
absur_siam
#15 Jan 23, 2018, 10:40 AM • 5 Y
Y by JayantJha, samrocksnature, Adventure10, Mango247, Rounak_iitr
Claim 1 : $C , B , O_2$ and $D , B , O_1$ are co-linear.
Proof:
From the cyclic $\square O_1 A O_2 C$ we get,
$\angle O_1 C O_2 = 180^o - \angle O_1 A O_2$

$\triangle O_1 A O_2 \cong \triangle O_1 B O_2 \Rightarrow \angle O_1 A O_2 = \angle O_1 B O_2$

Let the line $O_2 B$ intersects $\tau_1$ at $K$
$\therefore \angle O_1 B K = 180^o - \angle O_1 B O_2 = 180^o - \angle O_1 A O_2$

$O_1 B = O_1 K$
$\therefore \angle O_1 K B = \angle O_1 B K = 180^o - \angle O_1 A O_2 = \angle O_1 C O_2$
Therefore, $K$ coincides with $C$

Thus , $C, B , O_2$ are co-linear. (Proved)
Similarly, $D, B , O_1$ are co-linear.

Claim 2 : $F , A , E$ are co-linear.
Proof : Trivial.


Now we complete our proof,
Let $\angle A E O_2 = \angle F E C = \alpha$
$\therefore E A O_2 = \alpha \Rightarrow \angle A O_2 B = 2\alpha$
$\Rightarrow \angle O_1 O_2 B = \angle O_1 O_2 C = \angle O_1 D C = \angle F D C = \alpha$
$\therefore \angle F E C = \angle F D C$
So, $C , D , E , F$ are concyclic [Q.E.D.]
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chandramauli_2000
64 posts
chandramauli_2000
#16 Jan 28, 2018, 4:25 PM • 2 Y
Y by samrocksnature, Adventure10
all the ques pls?
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AnArtist
1590 posts
AnArtist
#17 Jan 28, 2018, 4:27 PM • 3 Y
Y by samrocksnature, Adventure10, Mango247
@chandramauli see here

https://artofproblemsolving.com/community/c596374_2018_india_national_olympiad
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vlohani
17 posts
vlohani
#18 May 21, 2018, 12:45 PM • 2 Y
Y by samrocksnature, Adventure10
For those who didn't get Kayak's slick solution, he says: Invert about $B$. Then $A \to A^*$, $B \to B^*$ and $C \to C^*$, while $\Gamma_1$ goes to the straight line $A^*C^*$ and $\Gamma_2$ goes to the straight line $A^*D^*$. (Because $\angle O_1AO_2$ is obtuse, $C$ and $D$, and hence $C^*$ and $D^*$, are different from B.)

$\odot (O_{1}AO_{2}) \to \odot (O_{1}^*A^*O_{2}^*)$, which is also the circumcircle of $\Delta A^*C^*D^*$.

Now note:
1. $O_1^*$ is the reflection of $B$ in $A^*C^*$,
2. $O_2^*$ is the reflection of $B$ in $A^*D^*$.

This forces $B$ to be the orthocenter of $A^*C^*D^*$ because there is only one point other than $A^*$ whose reflections in $A^*C^*$ and $A^*D^*$ respectively lie on $\odot (A^*C^*D^*)$ (why?) $-$ and the orthocenter clearly satisfies this condition. Hence, $B^*$ is the orthocenter of $\Delta A^*C^*D^*$.

Since $E^*$ and $F^*$ are the feet of altitudes through $D^*$ and $C^*$ in $\Delta A^*C^*D^*$, it's trivial to note that $C^*D^*E^*F^*$ is cyclic.
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Synthetic_Potato
114 posts
Synthetic_Potato
#19 May 21, 2018, 1:58 PM • 3 Y
Y by samrocksnature, Adventure10, Mango247
Extention: Let $AB$ meet the circle $\odot (O_1AO_2)$ again at $O$. Prove that $O$ is the circumcenter of $BCD$.
(Note: This is easier than the original problem ;) )
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Supercali
1261 posts
Supercali
#20 May 21, 2018, 4:42 PM • 2 Y
Y by samrocksnature, Adventure10
Synthetic_Potato wrote:
Extention: Let $AB$ meet the circle $\odot (O_1AO_2)$ again at $O$. Prove that $O$ is the circumcenter of $BCD$.
(Note: This is easier than the original problem ;) )

Just note that $B$ is the incentre of $ACD$
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XbenX
590 posts
XbenX
#21 Jul 19, 2018, 8:57 AM • 4 Y
Y by Pigeonhole_Biswaranjan_, samrocksnature, Adventure10, Mango247
A different approach:
After some easy angle chasing we get that $C,B,O_2,E$ and $ D,B,O_1,F$ are collinar in that order .
By Power of point $B$ on $(CDO_2O_1) \Longleftrightarrow BD \cdot BO_1=BC \cdot BO_2$ and since $BO_1$ and $BO_2$ are the radiuses of their respective circles , we get that $ BD \cdot BF=BC \cdot BE$ wich completes the proof.
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hydrohelium
245 posts
hydrohelium
#22 Dec 2, 2018, 6:07 AM • 3 Y
Y by samrocksnature, Adventure10, Mango247
TheDarkPrince wrote:
My solution (something like this): Let $O_1B \cap \Gamma_2 = D'$ and $O_2B \cap \Gamma_1 = C'$.

As $\triangle O_1D'A$ is not isosceles, $\angle AO_1O_2 = \angle O_2O_1B = \angle O_2O_1D'$ and $\angle O_2AD'=\angle O_2D'A$ gives $O_1AO_2D'$ is cyclic. So, $D'\equiv D$. Similarly, $C'\equiv C$.
Proved.

I think
$\angle AO_1O_2=\angle BAO_2$ which can never be equal to $\angle BAO_2$ so your claim is wrong
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TheDarkPrince
3042 posts
TheDarkPrince
#23 Dec 21, 2018, 2:36 PM • 3 Y
Y by samrocksnature, Adventure10, Mango247
hydrohelium wrote:
TheDarkPrince wrote:
My solution (something like this): Let $O_1B \cap \Gamma_2 = D'$ and $O_2B \cap \Gamma_1 = C'$.

As $\triangle O_1D'A$ is not isosceles, $\angle AO_1O_2 = \angle O_2O_1B = \angle O_2O_1D'$ and $\angle O_2AD'=\angle O_2D'A$ gives $O_1AO_2D'$ is cyclic. So, $D'\equiv D$. Similarly, $C'\equiv C$.
Proved.

I think
$\angle AO_1O_2=\angle BAO_2$ which can never be equal to $\angle BAO_2$ so your claim is wrong

How is $\angle AO_1O_2 = \angle BAO_2$ :D I think my solution works fine.
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MathPassionForever
1663 posts
MathPassionForever
#24 Dec 21, 2018, 2:48 PM • 3 Y
Y by AlastorMoody, samrocksnature, Adventure10
TheDarkPrince wrote:
hydrohelium wrote:
TheDarkPrince wrote:
My solution (something like this): Let $O_1B \cap \Gamma_2 = D'$ and $O_2B \cap \Gamma_1 = C'$.

As $\triangle O_1D'A$ is not isosceles, $\angle AO_1O_2 = \angle O_2O_1B = \angle O_2O_1D'$ and $\angle O_2AD'=\angle O_2D'A$ gives $O_1AO_2D'$ is cyclic. So, $D'\equiv D$. Similarly, $C'\equiv C$.
Proved.

I think
$\angle AO_1O_2=\angle BAO_2$ which can never be equal to $\angle BAO_2$ so your claim is wrong

How is $\angle AO_1O_2 = \angle BAO_2$ :D I think my solution works fine.

People actually look up posts that old?
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mathlete18
22 posts
mathlete18
#25 Jan 9, 2019, 5:38 PM • 2 Y
Y by samrocksnature, Adventure10
Too easy for INMO, anyways here is an alternate proof.

Angle chase to get $C,B,O_{2},E$ are collinear. Similarly $D,B,O_{1},F$ are collinear.
Then notice $\angle FCE = \angle EDF = 90^{\circ}$ (Angle in a semicircle). By inscribed angles theorem, $C,D,E$ and $F$ are collinear. $\blacksquare$
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Gestapo
254 posts
Gestapo
#26 Jan 9, 2019, 7:25 PM • 3 Y
Y by samrocksnature, Adventure10, Mango247
vlohani wrote:
For those who didn't get Kayak's slick solution, he says: Invert about $B$. Then $A \to A^*$, $B \to B^*$ and $C \to C^*$, while $\Gamma_1$ goes to the straight line $A^*C^*$ and $\Gamma_2$ goes to the straight line $A^*D^*$. (Because $\angle O_1AO_2$ is obtuse, $C$ and $D$, and hence $C^*$ and $D^*$, are different from B.)
$\odot (O_{1}AO_{2}) \to \odot (O_{1}^*A^*O_{2}^*)$, which is also the circumcircle of $\Delta A^*C^*D^*$.

Now note:
1. $O_1^*$ is the reflection of $B$ in $A^*C^*$,
2. $O_2^*$ is the reflection of $B$ in $A^*D^*$.

This forces $B$ to be the orthocenter of $A^*C^*D^*$ because there is only one point other than $A^*$ whose reflections in $A^*C^*$ and $A^*D^*$ respectively lie on $\odot (A^*C^*D^*)$ (why?) $-$ and the orthocenter clearly satisfies this condition. Hence, $B^*$ is the orthocenter of $\Delta A^*C^*D^*$.

Since $E^*$ and $F^*$ are the feet of altitudes through $D^*$ and $C^*$ in $\Delta A^*C^*D^*$, it's trivial to note that $C^*D^*E^*F^*$ is cyclic.

So how does O1*B perpendicular to A*C* imply that O1* is reflection of B in A*C*??
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AlastorMoody
2125 posts
AlastorMoody
#27 Feb 21, 2019, 11:54 AM • 2 Y
Y by samrocksnature, Adventure10
$\angle ACO_2=\angle AO_1O_2=\frac{1}{2} \angle AO_1B=\angle ACB$ $\implies$ $BC$ passes through $O_2$, similarly, $BD$ passes through $O_1$, hence, $\angle FCE$ $=$ $90^{\circ}$ $=$ $\angle EDF$ which implies the conclusion
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Agsh2005
70 posts
Agsh2005
#28 Mar 24, 2020, 8:10 PM • 2 Y
Y by samrocksnature, Mango247
What about radical axis
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ftheftics
651 posts
ftheftics
#29 Apr 1, 2020, 3:59 AM • 2 Y
Y by Gerninza, samrocksnature
$\textcolor{red}{\text{Claim:}}$
$C,B,O_2$ are coliner. Similarly $O_1,B,D$ are similar .

Let's join $B,O_2$ and $B,0_1$ .Note that $AB \perp O_1O_2$ since it's radial axis of $\Gamma_1,\Gamma_2$. Note that $\triangle AO_2B$ is isosceles .And hence $\angle AO_2O_1=\angle BO_2O_1=a$ and by similar argument we have $\angle BO_1O_2=\angle AO_1O_2=b$ and hence $ \angle O_1AO_2=\angle O_1BO_2=180-(a+b)$.

Suppose$O_2B$ met $\Gamma_1$ at $C'$ .
So $\angle O_1O_2C'=a$. Again$\angle O_1C'B=\angle C'O_1B$ . Which means $A,O_1,C',D$ are concyclic . $\Rightarrow C'=C$.

Similarly we can show that $O_1,B,D$ are coliner.

$\textcolor{red}{\text{Claim:}}$ $E,A,F$ are Coliner and $FE $ parallel to $O_1O_2$.

In $\Gamma_2$ we get $\angle AO_2E =180-2b$ which gives $\angle AEB=\angle O_1O_2B =b$.

So $AE$ parallel to $O_1O_2$ by similar argument $ AF$ parallel to $O_1O_2$.

Our claim is proved.

Note that $C,O_1,O_2,D$ are concyclic so $CB.BO_2=DB.BO_1 \cdots (*)$.

Since $ \triangle BO_1O_2 \sim BEF$ hence $ \frac{BO_1}{BF}=\frac{BO_2}{BE}$.

From $(*)$ we get $ CB.BE =DB .BF$ so we are done .
This post has been edited 1 time. Last edited by ftheftics, Apr 1, 2020, 4:01 AM
Reason: Jjsj
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MatBoy-123
396 posts
MatBoy-123
#30 Apr 22, 2021, 10:13 AM • 1 Y
Y by samrocksnature
XbenX wrote:
A different approach:
After some easy angle chasing we get that $C,B,O_2,E$ and $ D,B,O_1,F$ are collinar in that order .
By Power of point $B$ on $(CDO_2O_1) \Longleftrightarrow BD \cdot BO_1=BC \cdot BO_2$ and since $BO_1$ and $BO_2$ are the radiuses of their respective circles , we get that $ BD \cdot BF=BC \cdot BE$ wich completes the proof.

First you need to prove that $(CDO_2O_1) $ is cyclic..
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MrOreoJuice
594 posts
MrOreoJuice
#31 May 5, 2021, 5:12 AM • 2 Y
Y by samrocksnature, kamatadu
Wait what? i just realised this problem is a part of https://artofproblemsolving.com/community/q1h1952359p21527833
$C-B-O_2$ are collinear, so is $D-B-O_1$
$FB$ and $BE$ is diameter so $\angle FCE = 90^\circ = \angle EDF$ and we are done.

edit-
arulxz wrote:
Prove by angle chasing that $B$ is the incenter of $\triangle ACD$.
yes indeed, this was the brazil problem lol
This post has been edited 1 time. Last edited by MrOreoJuice, May 5, 2021, 7:19 AM
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lazizbek42
548 posts
lazizbek42
#33 Feb 6, 2022, 10:37 AM • 1 Y
Y by tuymurod2005
$$\angle CAB =\angle DAB,\angle FAB = \angle EAB \implies FB \cdot BD = CB \cdot BE$$
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James_HN
51 posts
James_HN
#34 Feb 23, 2022, 10:43 AM • 1 Y
Y by Rounak_iitr
$$\measuredangle DO_1O_2 =\measuredangle DAO_2 =\measuredangle O_2DA =\measuredangle O_2O1A =\measuredangle BO_1O_2$$$\implies D,B,O_1$ are collinear, hece $BE$ is the diameter of $\Gamma_1$ similiarly we get $BF$ as the diameter of $\Gamma_2$,
$\implies \measuredangle FDE = \measuredangle FCE = 90^{\circ}$, Hence $C,D,E,F$ are concyclic
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Mahdi_Mashayekhi
698 posts
Mahdi_Mashayekhi
#35 Mar 6, 2022, 6:07 AM
Y by
Claim: $C,B,O_2$ and $D,B,O_1$ are collinear.
Proof : $\angle ADO_1 = \angle AO_2O_1 = \angle AO_2B/2 = \angle ADB$ so $D,B,O_1$ are collinear. we prove the other one with same approach.

Now we have $\angle ECF = \angle BCF = \angle 90 = \angle BDE = \angle FDE$ so $CDEF$ is cyclic.
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bluedragon17
87 posts
bluedragon17
#36 Apr 9, 2022, 7:08 PM
Y by
Just invert about $B$, using the inversion distance formula we find out that $O_1'$ and $O_2'$ are the reflection of $B$ over $A'C'$ and $A'D'$ respectively, then note that since both $O_1'$ and $O_2'$ lie on $(A'C'D')$, $B'$ is the orthocenter of $\triangle{A'C'D'}$ and therefore, $C,B,O_2,E$ and $D,B,O_1,F$ are in fact collinear, the conclusion now follows immediately.
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Pyramix
419 posts
Pyramix
#37 Dec 20, 2022, 7:50 PM
Y by
Proof
Remark
I hope you enjoyed reading my proof :)
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john0512
4191 posts
john0512
#38 May 4, 2023, 3:38 AM
Y by
Let $\angle O_1BC=\angle O_1CB=\alpha$, $\angle O_1AB=\angle O_1BA=\beta$, and $\angle O_2AB=\angle O_2BA=\gamma.$

Main Claim: $C,B,O_2$ are collinear. We wish to show that $\alpha+\beta+\gamma=180$. Note that $\angle AO_2O_1=90-\gamma$ since $AB\perp O_1O_2$. Thus, from cyclic $AO_1CO_2$, we have $\angle ACO_1=90-\gamma$. Since $O_1C=O_1A$, $\angle AO_1C=2\gamma$. However, we have $\angle AO_1B=180-2\beta$, and $\angle BO_1C=180-2\alpha$. Hence, $$2\gamma=180-2\beta+180-2\alpha\rightarrow \alpha+\beta+\gamma=180,$$as desired.

Hence, $BE$ is a diameter of $\Gamma_2$, so $\angle BDE=90$. Similarly, $\angle BCF=90$. Hence, $C,D,E,F$ are concyclic and we are done.
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kamatadu
481 posts
kamatadu
#39 May 9, 2023, 3:31 PM • 2 Y
Y by aansc1729, HoripodoKrishno
Bro what? Why Invert this :maybe: ?

Anyways here is the sketch (typing full solns is too stressful due to my 50 WPM :stretcher: ).

https://i.imgur.com/RZLbbWr.png

You get that $E$ and $F$ are the $B-$antipodes in $\Gamma_1$ and $\Gamma_2$ respectively from some angle chasing.

Then a bit of homothety shows $EF\parallel O_1O_2$ and $\overline{A-E-F}$ and so you get $\measuredangle ECF=\measuredangle ECB=90^\circ=\measuredangle BDF=\measuredangle EDF$ which finishes.
This post has been edited 1 time. Last edited by kamatadu, May 9, 2023, 3:33 PM
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HamstPan38825
8874 posts
HamstPan38825
#40 Aug 13, 2023, 8:07 PM
Y by
To be fair, inversion (especially about $A$) doesn't help a ton, but I'll just stick with it :|

In the inverted picture, $\omega_1^*$ and $\omega_2^*$ become two lines that intersect at $B$, and $(O_1AO_2)$ becomes the line $\overline{CD}$, on which the reflections of $A$ over $\omega_1^*$ and $\omega_2^*$ lie. Now, observe
  • $O_1$ and $O_2$ lie on $(ABD)$ and $(ACD)$, the two images of the lines, respectively, by the converse of Fact 5;
  • $A, E, F$ are collinear as $\angle BAE = \angle BAF = 90^\circ$;
  • $CDFE$ is cyclic by a quick angle chase.
Hence done!
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Math4Life7
1703 posts
Math4Life7
#41 Dec 6, 2023, 4:09 AM
Y by
We invert about $A$ with radius $1$. We can see that $F^*C^*B^*$ are collinear, $E^*D^*B^*$ are collinear, $O_1^*C^*D^*O_2^*$ are collinear, $F^*O_1^*B^*D^*$ are concyclic, and $E^*O_2^*B^*C^*$ are concyclic.

\begin{lemma}
$O_1^*$ is the reflection of $A$ over $F^*B^*$.
\end{lemma}
\begin{proof}
EGMO lemma 8.10
\end{proof}

This we have \[\angle AF^*C^* = \angle C^*F^*O_1^* = \angle C^*D^*B^*\]$\blacksquare$
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cursed_tangent1434
656 posts
cursed_tangent1434
#42 Apr 9, 2024, 12:17 AM
Y by
Me when I wanted a medium geo and tried this only for it to turn out trivial.

The following observation is key.

Claim : The points $D$ , $B$ and $O_1$ are collinear. Similarly, the points $C$ , $B$ and $O_2$ are collinear.
Proof : Simply note that
\[\measuredangle AO_1D = \measuredangle AO_2D = 2\measuredangle ADO_2 = 2\measuredangle AO_1O_2 = \measuredangle AO_1B\]from which it is clear that $D-B-O_1$ as claimed. Similarly, we can also show $C-B-O_2$.

Now, note that this means $BF$ and $BE$ are diameters of $\Gamma_1$ and $\Gamma_2$ respectively. This then gives us,
\[\measuredangle FCE = \measuredangle FCB = 90^\circ = \measuredangle BDE = \measuredangle FDE\]from which it is clear that the points $C, D, E, F$ are concyclic as required.
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reni_wee
63 posts
reni_wee
#43 Jun 4, 2024, 5:12 PM • 1 Y
Y by GeoKing
Let $O_2B$ intersect $\Gamma_1$ at $C'$ (phantom point), then,
$$\angle O_1C'B = \angle O_1BC' = 180^o - \angle O_1BO_2$$As $O_1$ and $O_2$ are the centers of $\Gamma_1$ and $\Gamma_2$, we have $O_1B=O_1A$, $O_2B=O_2A$, which implies that,
$$ \angle O_1BA = \angle O_1AB , \angle O_2BA = \angle O_2AB$$$\therefore \angle O_1BO_2 = \angle O_1AO_2$
Hence, $\angle O_1C'B = \angle O_1AO_2 = \angle O_1CB$, $\Rightarrow C \equiv C'$,
$\therefore C,B,O_2,E $ are collinear,
Similarly, $ D,B,O_1,F$ are collinear, $\Rightarrow BF$ and $BE$ are diameters of $\Gamma_1$ and $\Gamma_2$ respectively.
$\therefore \angle BDE= \angle FDE = \angle FCE = 90^o$, $\Rightarrow CDEF$ is a cyclic quadrilateral.
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Mathandski
773 posts
Mathandski
#44 Sep 20, 2024, 5:03 PM
Y by
$ $
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Ilikeminecraft
676 posts
Ilikeminecraft
#47 Feb 19, 2025, 10:09 PM
Y by
Claim: $FO_1BD$ is collinear.
Proof: Invert at $A.$ Then, we have that $(ABC)$ goes to a line $\ell_1,(ABD)$ goes to a line $\ell_2, O_1$ goes to the reflection of $A$ across $\ell_1, O_2$ goes to the reflection of $A$ across $\ell_2, C, D$ going to the intersections of $\ell_1, \ell_2$ with $O_1^*O_2^*.$ We also have that $E^*, F^*$ go to the intersections of $\ell_1, \ell_2$ with $(AB^*D^*)$ and $(AC^*D^*).$
Now, note that $B^*$ is the circumcenter of $AO_1O_2$ since $B^*$ is the intersection of $\ell_1, \ell_2.$ Thus, $\angle AB^*D^* = \frac12\angle AB^*O_2^* = \angle AO_1^*D,$ so $AO_1^*B^*D^*$ is cyclic. However, since $E^*$ also lies on $AB^*D^*,$ we have that $AO_1^*B^*D^*E^*$ is cyclic. Inverting back, we get our desired claim.

By Thales, we are done.
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Rounak_iitr
457 posts
Rounak_iitr
#48 Apr 26, 2025, 5:12 PM
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[asy] /* Geogebra to Asymptote conversion, documentation at artofproblemsolving.com/Wiki go to User:Azjps/geogebra */ import graph; size(13cm); 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 = -25.51570034117379, xmax = 40.82314408852699, ymin = -16.69519592790025, ymax = 21.93029312646862; /* image dimensions */ pen qqccqq = rgb(0,0.8,0); pen ttffqq = rgb(0.2,1,0); pen ffdxqq = rgb(1,0.8431372549019608,0); pen ffqqff = rgb(1,0,1); pen ffwwqq = rgb(1,0.4,0); pen xfqqff = rgb(0.4980392156862745,0,1); /* draw figures */ draw(circle((-3,-1), 9.501880502737109), linewidth(1) + blue); draw(circle((12.983545658162647,-1.0859342715935283), 10.371101277912132), linewidth(1) + red); draw(circle((4.978910084569212,-3.4354033592755004), 8.342313567590866), linewidth(1) + qqccqq); draw((-3,-1)--(12.983545658162647,-1.0859342715935283), linewidth(1) + red); draw((4.455727850687627,4.890488545509315)--(12.983545658162647,-1.0859342715935283), linewidth(1) + ttffqq); draw((4.455727850687627,4.890488545509315)--(-3,-1), linewidth(1) + ttffqq); draw((-0.10455216140722312,-10.049978723858084)--(21.50932605200054,4.81921690282699), linewidth(1) + blue); draw((9.085859717659737,-10.69675036732216)--(-10.445019518138734,4.904017061529285), linewidth(1) + red); draw((-10.445019518138734,4.904017061529285)--(21.50932605200054,4.81921690282699), linewidth(1) + ffdxqq); draw((-10.445019518138734,4.904017061529285)--(-0.10455216140722312,-10.049978723858084), linewidth(1) + ffdxqq); draw((-0.10455216140722312,-10.049978723858084)--(9.085859717659737,-10.69675036732216), linewidth(1) + ffdxqq); draw((9.085859717659737,-10.69675036732216)--(21.50932605200054,4.81921690282699), linewidth(1) + ffdxqq); draw((4.455727850687627,4.890488545509315)--(4.419722115642268,-6.935777692513815), linewidth(1) + ffqqff); draw((4.455727850687627,4.890488545509315)--(9.085859717659737,-10.69675036732216), linewidth(1) + ffwwqq); draw((4.455727850687627,4.890488545509315)--(-0.10455216140722312,-10.049978723858084), linewidth(1) + ffwwqq); draw(circle((5.532254937295013,4.899928348557101), 15.977274978600997), linewidth(1) + linetype("4 4") + ffqqff); draw((-3,-1)--(-0.10455216140722312,-10.049978723858084), linewidth(1) + xfqqff); draw((12.983545658162647,-1.0859342715935283)--(9.085859717659737,-10.69675036732216), linewidth(1) + xfqqff); /* dots and labels */ dot((-3,-1),dotstyle); label("$O_1$", (-4.514173220805075,-1.4528504714676924), NE * labelscalefactor); dot((4.455727850687627,4.890488545509315),dotstyle); label("$A$", (4.362760922855928,5.995113785652763), NE * labelscalefactor); dot((12.983545658162647,-1.0859342715935283),dotstyle); label("$O_2$", (13.889226833126274,-1.7126631781114292), NE * labelscalefactor); dot((4.419722115642268,-6.935777692513815),dotstyle); label("$B$", (4.2328545695340605,-9.030721081910016), NE * labelscalefactor); dot((-0.10455216140722312,-10.049978723858084),dotstyle); label("$C$", (-0.6169826211490247,-11.67215026612134), NE * labelscalefactor); dot((9.085859717659737,-10.69675036732216),dotstyle); label("$D$", (9.125993877991101,-12.105171443860902), NE * labelscalefactor); dot((21.50932605200054,4.81921690282699),dotstyle); label("$E$", (22.72285885901332,4.782654487981991), NE * labelscalefactor); dot((-10.445019518138734,4.904017061529285),dotstyle); label("$F$", (-11.745626889055746,4.955862959077816), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]
A Great Angle Chasing Exercise :love:
$\color{red}\textbf{Claim:-}$ $C,D,E,F$ are concyclic.
$\color{green}\textbf{Proof:-}$ By Angle Chasing we get, $$\angle O_1AC =\angle O_1CA = 180-2\angle AO_1C = 90-\angle CFA = 90+\angle ABC $$Also, $$\angle O_2AD = \angle O_2DA =180-2\angle AO_2D = 90-\angle AED = 90+\angle ABD$$Since, $\angle AFC = \angle ABE$ and $\angle AED = \angle ABF$ $\implies C,B,O_2$ are collinear and $D,B,O_1$ are collinear points.
Therefore, $BE$ and $BF$ are the diameters of circumcircles of $\triangle ABE$ and $\triangle ABF \implies \angle FAB = \angle BAE = 90^o \implies F,A,E$ are collinear and parallel to $O_1O_2.$ Now By Angle Chasing we get, $$\angle O_1AC = \angle O_1CA = \angle AO_2O_1 = \angle O_1DC $$And $$\angle O_2AD = \angle O_2DA = \angle EFB = \angle AO_1O_2 = \angle ACO_2 $$Therefore $B$ is the incentre of $\triangle ACD.$

Now finish this problem from this angle relation $\angle AEC = \angle FEC = \angle FDC \implies C,D,E,F$ are concyclic points.
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bjump
1035 posts
bjump
#49 Apr 30, 2025, 4:01 PM
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Invert at $A$. By Egmo Lemma 8.10 $B'D'$ is the perpendicular bisector of $AO_1'$. Similar bisector statement holds for $AO_2'$.
$2\angle AB'D' = 2\angle AO_1'O_2' = \angle AB'O_2'$ which gives $(AO_1'B'C')$ is a circle so $DO_1BE$ collinear, finishes by PoP.
This post has been edited 1 time. Last edited by bjump, Apr 30, 2025, 4:01 PM
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