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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.

Are you interested in working towards MATHCOUNTS and don’t know where to start? We have you covered! If you have taken Prealgebra, then you are ready for MATHCOUNTS/AMC 8 Basics. Already aiming for State or National MATHCOUNTS and harder AMC 8 problems? Then our MATHCOUNTS/AMC 8 Advanced course is for you.

Summer camps are starting next month at the Virtual Campus in math and language arts that are 2 - to 4 - weeks in duration. Spaces are still available - don’t miss your chance to have an enriching summer experience. There are middle and high school competition math camps as well as Math Beasts camps that review key topics coupled with fun explorations covering areas such as graph theory (Math Beasts Camp 6), cryptography (Math Beasts Camp 7-8), and topology (Math Beasts Camp 8-9)!

Be sure to mark your calendars for the following upcoming events:
[list][*]May 9th, 4:30pm PT/7:30pm ET, Casework 2: Overwhelming Evidence — A Text Adventure, a game where participants will work together to navigate the map, solve puzzles, and win! All are welcome.
[*]May 19th, 4:30pm PT/7:30pm ET, What's Next After Beast Academy?, designed for students finishing Beast Academy and ready for Prealgebra 1.
[*]May 20th, 4:00pm PT/7:00pm ET, Mathcamp 2025 Qualifying Quiz Part 1 Math Jam, Problems 1 to 4, join the Canada/USA Mathcamp staff for this exciting Math Jam, where they discuss solutions to Problems 1 to 4 of the 2025 Mathcamp Qualifying Quiz!
[*]May 21st, 4:00pm PT/7:00pm ET, Mathcamp 2025 Qualifying Quiz Part 2 Math Jam, Problems 5 and 6, Canada/USA Mathcamp staff will discuss solutions to Problems 5 and 6 of the 2025 Mathcamp Qualifying Quiz![/list]
Our full course list for upcoming classes is below:
All classes run 7:30pm-8:45pm ET/4:30pm - 5:45pm PT unless otherwise noted.

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0 replies
jlacosta
May 1, 2025
0 replies
J
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k i Peer-to-Peer Programs Forum
jwelsh   157
N Dec 11, 2023 by cw357
Many of our AoPS Community members share their knowledge with their peers in a variety of ways, ranging from creating mock contests to creating real contests to writing handouts to hosting sessions as part of our partnership with schoolhouse.world.

To facilitate students in these efforts, we have created a new Peer-to-Peer Programs forum. With the creation of this forum, we are starting a new process for those of you who want to advertise your efforts. These advertisements and ensuing discussions have been cluttering up some of the forums that were meant for other purposes, so we’re gathering these topics in one place. This also allows students to find new peer-to-peer learning opportunities without having to poke around all the other forums.

To announce your program, or to invite others to work with you on it, here’s what to do:

1) Post a new topic in the Peer-to-Peer Programs forum. This will be the discussion thread for your program.

2) Post a single brief post in this thread that links the discussion thread of your program in the Peer-to-Peer Programs forum.

Please note that we’ll move or delete any future advertisement posts that are outside the Peer-to-Peer Programs forum, as well as any posts in this topic that are not brief announcements of new opportunities. In particular, this topic should not be used to discuss specific programs; those discussions should occur in topics in the Peer-to-Peer Programs forum.

Your post in this thread should have what you're sharing (class, session, tutoring, handout, math or coding game/other program) and a link to the thread in the Peer-to-Peer Programs forum, which should have more information (like where to find what you're sharing).
157 replies
jwelsh
Mar 15, 2021
cw357
Dec 11, 2023
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k i C&P posting recs by mods
v_Enhance   0
Jun 12, 2020
The purpose of this post is to lay out a few suggestions about what kind of posts work well for the C&P forum. Except in a few cases these are mostly meant to be "suggestions based on historical trends" rather than firm hard rules; we may eventually replace this with an actual list of firm rules but that requires admin approval :) That said, if you post something in the "discouraged" category, you should not be totally surprised if it gets locked; they are discouraged exactly because past experience shows they tend to go badly.
-----------------------------
1. Program discussion: Allowed
If you have questions about specific camps or programs (e.g. which classes are good at X camp?), these questions fit well here. Many camps/programs have specific sub-forums too but we understand a lot of them are not active.
-----------------------------
2. Results discussion: Allowed
You can make threads about e.g. how you did on contests (including AMC), though on AMC day when there is a lot of discussion. Moderators and administrators may do a lot of thread-merging / forum-wrangling to keep things in one place.
-----------------------------
3. Reposting solutions or questions to past AMC/AIME/USAMO problems: Allowed
This forum contains a post for nearly every problem from AMC8, AMC10, AMC12, AIME, USAJMO, USAMO (and these links give you an index of all these posts). It is always permitted to post a full solution to any problem in its own thread (linked above), regardless of how old the problem is, and even if this solution is similar to one that has already been posted. We encourage this type of posting because it is helpful for the user to explain their solution in full to an audience, and for future users who want to see multiple approaches to a problem or even just the frequency distribution of common approaches. We do ask for some explanation; if you just post "the answer is (B); ez" then you are not adding anything useful.

You are also encouraged to post questions about a specific problem in the specific thread for that problem, or about previous user's solutions. It's almost always better to use the existing thread than to start a new one, to keep all the discussion in one place easily searchable for future visitors.
-----------------------------
4. Advice posts: Allowed, but read below first
You can use this forum to ask for advice about how to prepare for math competitions in general. But you should be aware that this question has been asked many many times. Before making a post, you are encouraged to look at the following:
[list]
[*] Stop looking for the right training: A generic post about advice that keeps getting stickied :)
[*] There is an enormous list of links on the Wiki of books / problems / etc for all levels.
[/list]
When you do post, we really encourage you to be as specific as possible in your question. Tell us about your background, what you've tried already, etc.

Actually, the absolute best way to get a helpful response is to take a few examples of problems that you tried to solve but couldn't, and explain what you tried on them / why you couldn't solve them. Here is a great example of a specific question.
-----------------------------
5. Publicity: use P2P forum instead
See https://artofproblemsolving.com/community/c5h2489297_peertopeer_programs_forum.
Some exceptions have been allowed in the past, but these require approval from administrators. (I am not totally sure what the criteria is. I am not an administrator.)
-----------------------------
6. Mock contests: use Mock Contests forum instead
Mock contests should be posted in the dedicated forum instead:
https://artofproblemsolving.com/community/c594864_aops_mock_contests
-----------------------------
7. AMC procedural questions: suggest to contact the AMC HQ instead
If you have a question like "how do I submit a change of venue form for the AIME" or "why is my name not on the qualifiers list even though I have a 300 index", you would be better off calling or emailing the AMC program to ask, they are the ones who can help you :)
-----------------------------
8. Discussion of random math problems: suggest to use MSM/HSM/HSO instead
If you are discussing a specific math problem that isn't from the AMC/AIME/USAMO, it's better to post these in Middle School Math, High School Math, High School Olympiads instead.
-----------------------------
9. Politics: suggest to use Round Table instead
There are important conversations to be had about things like gender diversity in math contests, etc., for sure. However, from experience we think that C&P is historically not a good place to have these conversations, as they go off the rails very quickly. We encourage you to use the Round Table instead, where it is much more clear that all posts need to be serious.
-----------------------------
10. MAA complaints: discouraged
We don't want to pretend that the MAA is perfect or that we agree with everything they do. However, we chose to discourage this sort of behavior because in practice most of the comments we see are not useful and some are frankly offensive.
[list] [*] If you just want to blow off steam, do it on your blog instead.
[*] When you have criticism, it should be reasoned, well-thought and constructive. What we mean by this is, for example, when the AOIME was announced, there was great outrage about potential cheating. Well, do you really think that this is something the organizers didn't think about too? Simply posting that "people will cheat and steal my USAMOO qualification, the MAA are idiots!" is not helpful as it is not bringing any new information to the table.
[*] Even if you do have reasoned, well-thought, constructive criticism, we think it is actually better to email it the MAA instead, rather than post it here. Experience shows that even polite, well-meaning suggestions posted in C&P are often derailed by less mature users who insist on complaining about everything.
[/list]
-----------------------------
11. Memes and joke posts: discouraged
It's fine to make jokes or lighthearted posts every so often. But it should be done with discretion. Ideally, jokes should be done within a longer post that has other content. For example, in my response to one user's question about olympiad combinatorics, I used a silly picture of Sogiita Gunha, but it was done within a context of a much longer post where it was meant to actually make a point.

On the other hand, there are many threads which consist largely of posts whose only content is an attached meme with the word "MAA" in it. When done in excess like this, the jokes reflect poorly on the community, so we explicitly discourage them.
-----------------------------
12. Questions that no one can answer: discouraged
Examples of this: "will MIT ask for AOIME scores?", "what will the AIME 2021 cutoffs be (asked in 2020)", etc. Basically, if you ask a question on this forum, it's better if the question is something that a user can plausibly answer :)
-----------------------------
13. Blind speculation: discouraged
Along these lines, if you do see a question that you don't have an answer to, we discourage "blindly guessing" as it leads to spreading of baseless rumors. For example, if you see some user posting "why are there fewer qualifiers than usual this year?", you should not reply "the MAA must have been worried about online cheating so they took fewer people!!". Was sich überhaupt sagen lässt, lässt sich klar sagen; und wovon man nicht reden kann, darüber muss man schweigen.
-----------------------------
14. Discussion of cheating: strongly discouraged
If you have evidence or reasonable suspicion of cheating, please report this to your Competition Manager or to the AMC HQ; these forums cannot help you.
Otherwise, please avoid public discussion of cheating. That is: no discussion of methods of cheating, no speculation about how cheating affects cutoffs, and so on --- it is not helpful to anyone, and it creates a sour atmosphere. A longer explanation is given in Seriously, please stop discussing how to cheat.
-----------------------------
15. Cutoff jokes: never allowed
Whenever the cutoffs for any major contest are released, it is very obvious when they are official. In the past, this has been achieved by the numbers being posted on the official AMC website (here) or through a post from the AMCDirector account.

You must never post fake cutoffs, even as a joke. You should also refrain from posting cutoffs that you've heard of via email, etc., because it is better to wait for the obvious official announcement. A longer explanation is given in A Treatise on Cutoff Trolling.
-----------------------------
16. Meanness: never allowed
Being mean is worse than being immature and unproductive. If another user does something which you think is inappropriate, use the Report button to bring the post to moderator attention, or if you really must reply, do so in a way that is tactful and constructive rather than inflammatory.
-----------------------------

Finally, we remind you all to sit back and enjoy the problems. :D

-----------------------------
(EDIT 2024-09-13: AoPS has asked to me to add the following item.)

Advertising paid program or service: never allowed

Per the AoPS Terms of Service (rule 5h), general advertisements are not allowed.

While we do allow advertisements of official contests (at the MAA and MATHCOUNTS level) and those run by college students with at least one successful year, any and all advertisements of a paid service or program is not allowed and will be deleted.
0 replies
v_Enhance
Jun 12, 2020
0 replies
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k i Stop looking for the "right" training
v_Enhance   50
N Oct 16, 2017 by blawho12
Source: Contest advice
EDIT 2019-02-01: https://blog.evanchen.cc/2019/01/31/math-contest-platitudes-v3/ is the updated version of this.

EDIT 2021-06-09: see also https://web.evanchen.cc/faq-contest.html.

Original 2013 post
50 replies
v_Enhance
Feb 15, 2013
blawho12
Oct 16, 2017
J
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A cyclic weighted inequality
MathMystic33   2
N 5 minutes ago by grupyorum
Source: 2024 Macedonian Team Selection Test P2
Let $u,v,w$ be positive real numbers. Prove that there exists a cyclic permutation $(x,y,z)$ of $(u,v,w)$ such that for all positive real numbers $a,b,c$ the following holds:
\[ \frac{a}{x\,a + y\,b + z\,c} \;+\; \frac{b}{x\,b + y\,c + z\,a} \;+\; \frac{c}{x\,c + y\,a + z\,b} \;\ge\; \frac{3}{x + y + z}. \]
2 replies
MathMystic33
an hour ago
grupyorum
5 minutes ago
J
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Perfect squares imply GCD is a perfect square
MathMystic33   1
N 6 minutes ago by grupyorum
Source: 2024 Macedonian Team Selection Test P6
Let \(a,b\) be positive integers such that \(a+1\), \(b+1\), and \(ab\) are perfect squares. Prove that $\gcd(a,b)+1$ is also a perfect square.
1 reply
MathMystic33
34 minutes ago
grupyorum
6 minutes ago
J
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Divisibility condition with primes
MathMystic33   1
N 8 minutes ago by grupyorum
Source: 2024 Macedonian Team Selection Test P1
Let \(p,p_2,\dots,p_k\) be distinct primes and let \(a_2,a_3,\dots,a_k\) be nonnegative integers. Define
\[ m \;=\; \frac12 \Bigl(\prod_{i=2}^k p_i^{a_i}\Bigr) \Bigl(\prod_{i=1}^k(p_i+1)\;+\;\sum_{i=1}^k(p_i-1)\Bigr), \]\[ n \;=\; \frac12 \Bigl(\prod_{i=2}^k p_i^{a_i}\Bigr) \Bigl(\prod_{i=1}^k(p_i+1)\;-\;\sum_{i=1}^k(p_i-1)\Bigr). \]Prove that
\[ p^2-1 \;\bigm|\; p\,m \;-\; n. \]
1 reply
MathMystic33
an hour ago
grupyorum
8 minutes ago
J
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Non-homogeneous degree 3 inequality
Lukaluce   4
N 9 minutes ago by Nuran2010
Source: 2024 Junior Macedonian Mathematical Olympiad P1
Let $a, b$, and $c$ be positive real numbers. Prove that
\[\frac{a^4 + 3}{b} + \frac{b^4 + 3}{c} + \frac{c^4 + 3}{a} \ge 12.\]When does equality hold?

Proposed by Petar Filipovski
4 replies
Lukaluce
Apr 14, 2025
Nuran2010
9 minutes ago
J
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[Signups Now!] - Inaugural Academy Math Tournament
elements2015   1
N 3 hours ago by Ruegerbyrd
Hello!

Pace Academy, from Atlanta, Georgia, is thrilled to host our Inaugural Academy Math Tournament online through Saturday, May 31.

AOPS students are welcome to participate online, as teams or as individuals (results will be reported separately for AOPS and Georgia competitors). The difficulty of the competition ranges from early AMC to mid-late AIME, and is 2 hours long with multiple sections. The format is explained in more detail below. If you just want to sign up, here's the link:

https://forms.gle/ih548axqQ9qLz3pk7

If participating as a team, each competitor must sign up individually and coordinate team names!

Detailed information below:

Divisions & Teams
[list]
[*] Junior Varsity: Students in 10th grade or below who are enrolled in Algebra 2 or below.
[*] Varsity: All other students.
[*] Teams of up to four students compete together in the same division.
[list]
[*] (If you have two JV‑eligible and two Varsity‑eligible students, you may enter either two teams of two or one four‑student team in Varsity.)
[*] You may enter multiple teams from your school in either division.
[*] Teams need not compete at the same time. Each individual will complete the test alone, and team scores will be the sum of individual scores.
[/list]
[/list]
Competition Format
Both sections—Sprint and Challenge—will be administered consecutively in a single, individually completed 120-minute test. Students may allocate time between the sections however they wish to.

[list=1]
[*] Sprint Section
[list]
[*] 25 multiple‑choice questions (five choices each)
[*] recommended 2 minutes per question
[*] 6 points per correct answer; no penalty for guessing
[/list]

[*] Challenge Section
[list]
[*] 18 open‑ended questions
[*] answers are integers between 1 and 10,000
[*] recommended 3 or 4 minutes per question
[*] 8 points each
[/list]
[/list]
You may use blank scratch/graph paper, rulers, compasses, protractors, and erasers. No calculators are allowed on this examination.

Awards & Scoring
[list]
[*] There are no cash prizes.
[*] Team Awards: Based on the sum of individual scores (four‑student teams have the advantage). Top 8 teams in each division will be recognized.
[*] Individual Awards: Top 8 individuals in each division, determined by combined Sprint + Challenge scores, will receive recognition.
[/list]
How to Sign Up
Please have EACH STUDENT INDIVIDUALLY reserve a 120-minute window for your team's online test in THIS GOOGLE FORM:
https://forms.gle/ih548axqQ9qLz3pk7
EACH STUDENT MUST REPLY INDIVIDUALLY TO THE GOOGLE FORM.
You may select any slot from now through May 31, weekdays or weekends. You will receive an email with the questions and a form for answers at the time you receive the competition. There will be a 15-minute grace period for entering answers after the competition.
1 reply
elements2015
Yesterday at 8:13 PM
Ruegerbyrd
3 hours ago
J
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Circle Incident
MSTang   39
N 3 hours ago by Ilikeminecraft
Source: 2016 AIME I #15
Circles $\omega_1$ and $\omega_2$ intersect at points $X$ and $Y$. Line $\ell$ is tangent to $\omega_1$ and $\omega_2$ at $A$ and $B$, respectively, with line $AB$ closer to point $X$ than to $Y$. Circle $\omega$ passes through $A$ and $B$ intersecting $\omega_1$ again at $D \neq A$ and intersecting $\omega_2$ again at $C \neq B$. The three points $C$, $Y$, $D$ are collinear, $XC = 67$, $XY = 47$, and $XD = 37$. Find $AB^2$.
39 replies
MSTang
Mar 4, 2016
Ilikeminecraft
3 hours ago
J
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Lots of Cyclic Quads
Vfire   104
N Today at 5:53 AM by Ilikeminecraft
Source: 2018 USAMO #5
In convex cyclic quadrilateral $ABCD$, we know that lines $AC$ and $BD$ intersect at $E$, lines $AB$ and $CD$ intersect at $F$, and lines $BC$ and $DA$ intersect at $G$. Suppose that the circumcircle of $\triangle ABE$ intersects line $CB$ at $B$ and $P$, and the circumcircle of $\triangle ADE$ intersects line $CD$ at $D$ and $Q$, where $C,B,P,G$ and $C,Q,D,F$ are collinear in that order. Prove that if lines $FP$ and $GQ$ intersect at $M$, then $\angle MAC = 90^\circ$.

Proposed by Kada Williams
104 replies
Vfire
Apr 19, 2018
Ilikeminecraft
Today at 5:53 AM
J
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Evan's mean blackboard game
hwl0304   72
N Today at 3:26 AM by HamstPan38825
Source: 2019 USAMO Problem 5, 2019 USAJMO Problem 6
Two rational numbers \(\tfrac{m}{n}\) and \(\tfrac{n}{m}\) are written on a blackboard, where \(m\) and \(n\) are relatively prime positive integers. At any point, Evan may pick two of the numbers \(x\) and \(y\) written on the board and write either their arithmetic mean \(\tfrac{x+y}{2}\) or their harmonic mean \(\tfrac{2xy}{x+y}\) on the board as well. Find all pairs \((m,n)\) such that Evan can write 1 on the board in finitely many steps.

Proposed by Yannick Yao
72 replies
hwl0304
Apr 18, 2019
HamstPan38825
Today at 3:26 AM
J
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9 JMO<200?
DreamineYT   4
N Today at 3:16 AM by megarnie
Just wanted to ask
4 replies
DreamineYT
May 10, 2025
megarnie
Today at 3:16 AM
J
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Points Collinear iff Sum is Constant
djmathman   69
N Today at 1:37 AM by blueprimes
Source: USAMO 2014, Problem 3
Prove that there exists an infinite set of points \[ \dots, \; P_{-3}, \; P_{-2},\; P_{-1},\; P_0,\; P_1,\; P_2,\; P_3,\; \dots \] in the plane with the following property: For any three distinct integers $a,b,$ and $c$, points $P_a$, $P_b$, and $P_c$ are collinear if and only if $a+b+c=2014$.
69 replies
djmathman
Apr 29, 2014
blueprimes
Today at 1:37 AM
J
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Jane street swag package? USA(J)MO
arfekete   30
N Today at 12:32 AM by NoSignOfTheta
Hey! People are starting to get their swag packages from Jane Street for qualifying for USA(J)MO, and after some initial discussion on what we got, people are getting different things. Out of curiosity, I was wondering how they decide who gets what.
Please enter the following info:

- USAMO or USAJMO
- Grade
- Score
- Award/Medal/HM
- MOP (yes or no, if yes then color)
- List of items you got in your package

I will reply with my info as an example.
30 replies
arfekete
May 7, 2025
NoSignOfTheta
Today at 12:32 AM
J
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ranttttt
alcumusftwgrind   40
N Yesterday at 8:02 PM by ZMB038
rant
40 replies
alcumusftwgrind
Apr 30, 2025
ZMB038
Yesterday at 8:02 PM
J
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Equivalent averages
Royalreter1   16
N Yesterday at 12:04 PM by SomeonecoolLovesMaths
Source: 2016 AMC 10A #7
The mean, median, and mode of the $7$ data values $60, 100, x, 40, 50, 200, 90$ are all equal to $x$. What is the value of $x$?


$\textbf{(A)}\ 50 \qquad\textbf{(B)}\ 60 \qquad\textbf{(C)}\ 75 \qquad\textbf{(D)}\ 90 \qquad\textbf{(E)}\ 100$
16 replies
Royalreter1
Feb 3, 2016
SomeonecoolLovesMaths
Yesterday at 12:04 PM
J
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Paths around a circle
tenniskidperson3   45
N Yesterday at 11:19 AM by N3bula
Source: 2013 USAMO Problem 2
For a positive integer $n\geq 3$ plot $n$ equally spaced points around a circle. Label one of them $A$, and place a marker at $A$. One may move the marker forward in a clockwise direction to either the next point or the point after that. Hence there are a total of $2n$ distinct moves available; two from each point. Let $a_n$ count the number of ways to advance around the circle exactly twice, beginning and ending at $A$, without repeating a move. Prove that $a_{n-1}+a_n=2^n$ for all $n\geq 4$.
45 replies
tenniskidperson3
Apr 30, 2013
N3bula
Yesterday at 11:19 AM
J
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J
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Medium geometry with AH diameter circle
v_Enhance   95
N May 11, 2025 by Markas
Source: USA TSTST 2016 Problem 2, by Evan Chen
Let $ABC$ be a scalene triangle with orthocenter $H$ and circumcenter $O$. Denote by $M$, $N$ the midpoints of $\overline{AH}$, $\overline{BC}$. Suppose the circle $\gamma$ with diameter $\overline{AH}$ meets the circumcircle of $ABC$ at $G \neq A$, and meets line $AN$ at a point $Q \neq A$. The tangent to $\gamma$ at $G$ meets line $OM$ at $P$. Show that the circumcircles of $\triangle GNQ$ and $\triangle MBC$ intersect at a point $T$ on $\overline{PN}$.

Proposed by Evan Chen
95 replies
v_Enhance
Jun 28, 2016
Markas
May 11, 2025
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Medium geometry with AH diameter circle
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Source: USA TSTST 2016 Problem 2, by Evan Chen
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Pyramix
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Pyramix
#85 Mar 5, 2024, 7:49 AM
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We have that $Q$ is the $A-$Humpty Point and $G$ is the $A-$Queue Point.
Let $X=EF\cap BC$ and let points $T,N$ be the intersection of $(GNQ)$ and $(DEF)$. It is well-known that $H$ is the orthocenter of $AXN$ and $AD,NG,XQ$ are the altitudes. Hence, $NGQX$ is cyclic with diameter $\overline{NX}$, which gives $\angle XTN=90^\circ$. Moreover, $\overline{MN}$ is the diameter of $(DEF)$ (nine point circle). So, $\angle MTN=90^\circ=\angle XTN$. So, $M,T,X$ are collinear.

Note that $MG=MA$ and $OG=OA$, as $M$ is the center of $(AGH)$ and $O$ is center of $(ABC)$. So, $OM$ is the perpendicular bisector of $\overline{AG}$. It follows that $PA=PG$, which means that $\overline{PA}$ is tangent to $(AGH)$ at $A$. Hence, $P,A,M,G$ are concyclic.

Claim: $T\in(MBC)$
Proof. Let $K,G$ be the intersection of $(GNQ)$ and $(ABC)$. It is well-known that $K$ is the reflection of $Q$ in $\overline{BC}$ and that $AK$ is the $A-$symmedian. Let $A,H'$ be the intersection of line $AH$ with $(ABC)$. It is well-known that $H'$ is the reflection of $H$ in $\overline{BC}$. Finally, note that $\angle XQN=\angle HQN=\angle HDN=90^\circ$, which means $H,Q,N,D$ are cyclic. Reflecting about $\overline{BC}$, we get that $H',K,N,D$ are cyclic.
We now perform $\sqrt{-HA\cdot HD}$ inversion, which is the inversion about the circle with center $H$ and radius $\sqrt{HA\cdot HD}$, and then reflection about $H$. Under this inversion, the nine-point circle $(DEF)$ goes to $(ABC)$ and the circle $(GNQ)$ goes to itself as $G$ goes to $N$, $Q$ goes to $X$, $N$ goes to $G$ and $X$ goes to $Q$. This can be proved using the fact that $H$ is the orthocenter of $AXN$ with altitudes $AD,XQ,NG$. So, $T$ goes to an intersection of $(GNQ)$ and $(ABC)$. So, $T$ goes to either $G$ or $K$. However, $N$ goes to $G$, so $T$ must go to $K$. Finally, note that $D$ goes to $A$ and $H'$ goes to $M$, as $HM=\frac{HA}{2}$ and $HH'=2HD$, while $N$ goes to $G$. So, circle $(H'KND)$ goes to $(MTGA)$. Hence, $T\in(PAMG)$.
So, $XG\cdot XA=XT\cdot XM$. But since $A,G,B,C$ are concyclic, $XG\cdot XA=XB\cdot XC$. So, $XT\cdot XM=XB\cdot XC$ which means $T\in(MBC)$. $\blacksquare$

To conclude, note that $\overline{MP}$ is the diameter of $(PMT)$, so $\angle MTP=\angle MTN=90^\circ$, which means $T\in\overline{PN}$. So, $T\in\overline{PN}$, $T\in(GNQ)$ and $T\in(MBC)$. Hence, $T$ is the required point of intersection. $\blacksquare$
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ihatemath123
3446 posts
ihatemath123
#86 Apr 21, 2024, 10:01 PM
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Since $\overline{GH} \perp \overline{GA}$ and $\overline{OM} \parallel \overline{NH}$, it follows that $OM$ is the perpendicular bisector of $\overline{AG}$. So, $\overline{AP}$ is also tangent to $\gamma$; this means $\overline{AP} \parallel \overline{BC}$.

Let $X$ be the intersection of lines $AG$ and $BC$. Then, it's well known that $X$, $H$ and $Q$ are collinear, so $XGQN$ is cyclic.

Claim: lines $PN$ and $XM$ are perpendicular.

Proof: Let $P'$ be the reflection of $A$ over $P$, so that $P'$ lies on line $NHG$. We will in fact show that $\triangle AXH \sim \triangle P'NA$, which implies our claim (since the segments we're trying to show perpendicular are the medians of the respective triangles). We already have $\angle XAH = \angle NP'A$ since $\overline{XA} \perp \overline{HP'}$; furthermore,
\[ \angle AHX = 180^{\circ} - \angle ANX = \angle P'AN,\]where the step is because $H$ is the orthocenter of $\triangle AXN$. So, our claim is proved.

Let $U$ be the intersection of $\overline{PN}$ and $\overline{XM}$. As stated earlier, $PM$ is the perpendicular bisector of $\overline{AG}$, so $(PAMG)$ is cyclic with diameter $PM$. Since $\angle PUM = 90^{\circ}$, it follows that $GUMA$ is cyclic. So, by the radical axis theorem, $BUMC$ is cyclic. Since $\angle XUN = 90^{\circ}$, we also have $XQUN$ cyclic, finishing.
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Aiden-1089
293 posts
Aiden-1089
#87 May 13, 2024, 7:53 AM
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Note that $G$ is the $A$-Queue point, $Q$ is the $A$-Humpty point. Let $X$ be the $A$-Ex point.
Reflecting about line $OM$, we see that $G$ goes to $A$, so $PA$ is tangent to $(AH)$. Thus, $P,A,M,G$ are concyclic.

Let $T' \neq M$ be the intersection between $(PAMG)$ and $(MBC)$.
By radax on $(PAMG)$, $(ABC)$, $(MBC)$, we get that $AG, BC, T'M$ are concurrent. Thus $T'$ lies on $XM$.
Let $D$ be the foot of the $A$-altitude. It is well-known that we can take a suitable inversion about $X$ that swaps the following pair of points: $(A,G), (M,T'), (H,Q), (D,N)$. Thus the $A$-altitude $AMHD$ is taken to the circle $(XGT'QN)$.

Now, since $\measuredangle MT'N = \measuredangle XT'N = \measuredangle XGN = \measuredangle AGN = 90^{\circ} = \measuredangle MAP = \measuredangle MT'P$, we get that $P,N,T'$ are collinear.
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EpicBird08
1753 posts
EpicBird08
#88 Jun 20, 2024, 2:52 AM
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For some reason I love overcomplicating things.

Humpty point properties imply that $B,H,Q,C$ are concyclic. Thus applying the radical center theorem on $\gamma, (BHQC),$ and $(ABC)$ gives that $AG, QH,$ and $BC$ are concurrent, say at point $X.$

Claim 1: $XGQN$ is cyclic with diameter $XN.$
Proof: It is well-known that $G,H,N$ are collinear, so we see that $\angle XGN = \angle AGH = \angle AQH = \angle XQN = 90^\circ,$ as claimed.

We now get rid of the point $O$ from the problem:

Claim 2: $PA$ is tangent to $\gamma$ as well.
Proof: Note that $AM = MH$ and $AO = OG,$ so $MO$ is none other than the perpendicular bisector of $AG.$ Since $PG$ is tangent to $\gamma,$ this implies that $PA$ is as well.

Thus $P$ is just the intersection of the tangents to $\gamma$ at $A$ and $G.$

Now let $Z$ be the intersection of the circumcircle of $GQN$ with $PN.$ By Claim 1, we see that $Z$ is just the foot of the altitude from $X$ to $PN.$ However,

Claim 3: $XM \perp PN.$
Proof: We in fact show the stronger statement that $PM$ is the polar of $X$ with respect to $\gamma.$ First, we show that $P$ lies on the polar of $X.$ By La-Hire this is equivalent to showing that $X$ lies on the polar of $P,$ which is just $AG,$ and this holds by the definition of $X.$ Now we show that $N$ lies on the polar of $X,$ which proves the claim. Again by La-Hire this is equivalent to showing that $X$ lies on the polar of $N,$ which is just $EF$ where $E$ the foot of the altitude from $B$ to $AC$ and $F$ is the foot of the altitude from $C$ to $AB.$ But by the radical center theorem on $\gamma, (BFEC),$ and $(ABC),$ we see that $X,E,F$ are collinear. Therefore, $X$ lies on the polar of $N,$ which proves our claim.

Hence $Z$ is the foot of the altitude from $N$ to $XM.$

Now, let $AH$ intersect $BC$ at point $D.$ Then $\angle MZN = \angle MDN = 90^\circ,$ so $MZDN$ is cyclic. Thus by power of a point at $X,$ we get $XZ \cdot XM = XD \cdot XN.$ Since $\angle AGN = \angle ADN = 90^\circ,$ we get that $AGDN$ is cyclic, so $XD \cdot XN = XG \cdot XA = XB \cdot XC$ by power of a point on $(ABC).$ Combining everything together, we get
\[ XZ \cdot XM = XD \cdot XN = XG \cdot XA = XB \cdot XC, \]which implies that $ZMBC$ is cyclic, and we are done.
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Clew28
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Clew28
#89 Jun 20, 2024, 3:50 PM • 1 Y
Y by duckman234
Given that the intersection of $QG$ with $BC$ is at $K$, and $N$ is the midpoint of the arc $BC$ that does not contain $A$, we start with the known result that $ND$ and $IP$ intersect at $Q$. Given that $DP \parallel AN$, by Reim's theorem, $Q$, $P$, $D$, and $G$ are concyclic. It's apparent that they all lie on the $D$-Apollonius circle with respect to $BC$, leading to the relation $QB \cdot CG = QC \cdot BG$. This implies the cross-ratio $-1 = (Q, G; B, C)$, indicating that $GK$ must align with the $G$-symmedian of triangle $BGC$. Therefore, $DG$ bisects the angle $\angle QGM$.

Furthermore, $QK$ aligns with the $Q$-symmedian of triangle $QBC$. Consequently, the tangents to $(ABC)$ at $B$ and $C$ intersect at $T$ on line $QK$, establishing that the cross-ratio $(Q, G; T, K) = -1$. This conclusion leads to the result that $DM$ bisects $\angle GMQ$.

Hence, it follows that $D$ serves as the incenter of triangle $GQM$, as required.
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kiemsibongtoi
25 posts
kiemsibongtoi
#90 Jul 1, 2024, 7:18 AM
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v_Enhance wrote:
Let $ABC$ be a scalene triangle with orthocenter $H$ and circumcenter $O$. Denote by $M$, $N$ the midpoints of $\overline{AH}$, $\overline{BC}$. Suppose the circle $\gamma$ with diameter $\overline{AH}$ meets the circumcircle of $ABC$ at $G \neq A$, and meets line $AN$ at a point $Q \neq A$. The tangent to $\gamma$ at $G$ meets line $OM$ at $P$. Show that the circumcircles of $\triangle GNQ$ and $\triangle MBC$ intersect at a point $T$ on $\overline{PN}$.

Proposed by Evan Chen

Let $D$, $E$, $F$ be the foot of altitude from vertex $A$, $B$, $C$ in triangle $ABC$ respectively
$\hspace{0.5cm}$$S$ be the intersection of lines $EF$ and $BC$; $T$ be the intersection of lines $PN$ and $MS$
Examine radical axis of circles $\gamma$, circle with diameter $BC$, $(ABC)$ we see that lines $EF$, $BC$, $HQ$ concur at $S$, so $\angle SQN = \angle HQA = 90^\circ$
Cuz $OM \perp AG$ so $P$ is the pole of $AG$ respect to $\gamma$, and we ez to see that $N$ is the pole of $EF$ respect to $\gamma$
Therefore, $PN$ is the polar of $S$ respect to $\gamma$ (Follow La Hire theorem)
Lead to $SM \perp PN$ at $T$ and $\overline{ST}.\overline{SM} = \overline{SE}.\overline{SF} = \overline{SB}.\overline{SC} $
Combine with $\angle SPN = \angle SQN = 90^\circ$, we see that $T$ lie on circles $(TQN)$, circle $(BMC)$, done
Attachments:
usatstst-2016.pdf (73kb)
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bin_sherlo
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bin_sherlo
#91 Aug 12, 2024, 5:07 PM • 2 Y
Y by egxa, ehuseyinyigit
Let $D,E,F$ be the altitudes from $A,B,C$ to $BC,CA,AB$. $EF\cap BC=T$. Let $M^*$ be the reflection of $A$ with respect to $BC$ and $K$ be the point on $TM^*$ such that $GK\perp BC$. $L$ is on $TM^*$ such that $GL\perp AD$.
$OM$ is the perpendicular bisector of $AG$ hence $PA$ is tangent to $(AGH)$ which means $AP\parallel BC$.
Invert from $A$ with radius $\sqrt{AH.AD}$. $PN\leftrightarrow (AQP^*)$ where $TP^*=TP$ and $P^*$ is on $AP$. $(MBC)\leftrightarrow (M^*EF)$ and $(TQGN)\leftrightarrow (TQNG)$.
When we invert from $T$ with radius $\sqrt{TB.TC},$ $A,Q,K,P^*$ swap with $G,H,M^*,L$ which are cyclic since $\angle GLM^*=\angle AP^*M^*=\angle TAP^*=\angle GHA$. Thus, $(AQP^*)$ pass through $K$. Also $TK.TM^*=TG.TA=TE.TF$ hence $K$ is on $(M^*EF)$. $\angle TKG=\angle KGT=\angle TNG$ so $K$ also lies on $(TNGQ)$ which gives that $(AQP^*),(M^*EF),(TNQG)$ are concurrent as desired.$\blacksquare$
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Eka01
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Eka01
#92 Aug 20, 2024, 1:34 PM • 1 Y
Y by AaruPhyMath
Let $X$ be the $A$ expoint. We make a few observations:-
$P$ is the pole of $AG$ in $\gamma$ since it is the intersection of one tangent and perpendicular bisector of $AG$ $\implies (PAGM)$ is cyclic.
$Q$ is the $A$ humpty point and it lies on $HX$ so $(GXNQ)$ is cyclic and $\Delta AXN$ has orthocenter $H$.

Now, by radax on $(ABC)$, $(PAMG)$ and $(MBC)$, $X$ lies on the radical axis of $(MBC)$ and $(PAMG)$. By radical axis on the nine point circle, $(MBC)$ and $(PAMG)$ , we get that they are coaxial and that the second intersection $T$ lies on $PN$ as well as the circle with diamter $XN$ which is what we needed to prove.
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L13832
268 posts
L13832
#93 Sep 5, 2024, 1:29 PM
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Finally got time to latex this!
v_Enhance wrote:
Let $ABC$ be a scalene triangle with orthocenter $H$ and circumcenter $O$. Denote by $M$, $N$ the midpoints of $\overline{AH}$, $\overline{BC}$. Suppose the circle $\gamma$ with diameter $\overline{AH}$ meets the circumcircle of $ABC$ at $G \neq A$, and meets line $AN$ at a point $Q \neq A$. The tangent to $\gamma$ at $G$ meets line $OM$ at $P$. Show that the circumcircles of $\triangle GNQ$ and $\triangle MBC$ intersect at a point $T$ on $\overline{PN}$.

Proposed by Evan Chen

Let $PN\cap RM=T$. Note that $G$ is the $A-$Queue Point, so we have the following claims
Claim I: ${G-H-N}$ is collinear. [Coxeter]
Claim II: $\odot(GAND)$ [a**]
Claim III: $EF, BC, AG$ concur at $R$, the radical center of $\odot(AGHQ) \odot(AGBC), \odot(BHQC)$.
Claim IV: $\odot(RGQN)$ with $RN$ as the diameter.
Proof: We need to show $\angle RQN=90^{\circ}$, which is true since $\overline{R-H-Q}$ by Brocard's Theorem on $BCEF$, we get $RH \perp AN$.
Claim V: $\odot(AMGP)$
Proof: $P$ is the pole of $AG$ w.r.t $\gamma$ and it lies on the perpendicular bisector of $AG$.
So we also have $PN$ is the polar of $R$ w.r.t $\gamma\implies PN\perp RM$ where $PN\cap RM=T$.

Claim VI: $\overline{R-T-M}\iff \angle MTN=90^{\circ}\iff T \in (AMGP)$
Proof: $\angle APT=\angle RNT=\angle TGA\implies \boxed{T \in \odot (RGTQN)}$.
Claim VII: $\boxed{T \in \odot(MBC)}$
Proof: $RM \cdot RT=RE\cdot RF=RC\cdot RB$

Figure
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EeEeRUT
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EeEeRUT
#94 Jan 6, 2025, 6:17 AM
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Let $S,E,F$ be feel of altitudes from $A,B,C$, respectively.
Denote $X : EF \cap AH$ and $I$ be midpoint of $EF$. Also, let $\gamma_1$ be circle with diameter $MX$.
Note that $MIN$ collinear and $E,F$ lies on $\gamma$ with their tangent intersect at $N$.
By Brokard, $X$ is orthocenter of $\triangle MBC$.
Note that $\angle MIX = 90^{\circ}$, so $ I \in \gamma_1$.But $I$ also lies on the median of $\triangle MBC$, so $I$ is humpty point of $\triangle MBC$.
Let $Y$ be midpoint of $GA$, $R$ be $EF \cap BC$. It is well-known that $AGR$ are collinear.
and $PA$ is tangent to the circumcircle of $ABC$( the line $OM$ is coaxis of $\gamma$ and the circumcircle $ABC$, so reflecting $G$ across perpendicular bisector of this line will give point $A$.)
Note that $\angle MRY = 180^{\circ} - \angle ASR$, so $MYR$ is cyclic.
Also, it is well known that $(R,S;B,C) = -1 \rightarrow NR \times NS = NB^2 = NI \times NM$
Thus, $SRYMI$ is cyclic.
Inverting this circle about $\gamma$ gives $PXN$ collinear.
Let $T’$ be $PN \cap (MBC)$, so $T’$ is queue point of $\triangle MBC$, that is $NX \times NT = NB^2 = NI \times NM$.
Inverting about $(BCEF)$ map $(MBC)$ to $(IBC)$ and $(GNQ)$ to $AH$($Q$ is humpty point so we have $NQ \times NA = NB^2$). Also, it maps $T’$ to $X$.
Since $X$ already lies on $AH$, it is suffice to show that $X \in (IBC)$, which is a well known property of $M$ humpty point that it lies on the circle with orthocenter and the remaining vertex of triangle $MBC$.
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label("$P$", (-7.243805477579469,6.8114252604126975), NE * labelscalefactor); dot((-0.9559422750255506,0.6539861738886703),linewidth(2pt) + dotstyle); label("$Q$", (-0.8241988647575746,0.7836256239602221), NE * labelscalefactor); dot((-4.516499937369707,4.56135543079989),linewidth(2pt) + dotstyle); label("$Y$", (-4.410739648446802,4.671556389472069), NE * labelscalefactor); dot((-2.089057089312553,1.7642128883409183),linewidth(2pt) + dotstyle); label("$I$", (-1.9694807956835465,1.89876855670393), NE * labelscalefactor); dot((-3.914722019191468,2.5320259687490156),linewidth(2pt) + dotstyle); label("$T'$", (-3.807959684801554,2.6522435112604894), NE * labelscalefactor); dot((-2.92298627100397,1.3298905074235121),linewidth(2pt) + dotstyle); label("$X$", (-2.813372744786894,1.4466835839699943), NE * labelscalefactor); clip((xmin,ymin)--(xmin,ymax)--(xmax,ymax)--(xmax,ymin)--cycle); /* end of picture */ [/asy]
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iStud
268 posts
iStud
#95 Jan 6, 2025, 12:29 PM
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It's a really nice problem! Evan Chen's medium geometry problems are the best!

Let $D,E,F$ be the foot of altitudes in $\triangle{ABC}$.

Firstly, note that $G$ is the $A$-queue point and $Q$ is the $A$-humpty point. It's well known that $\overline{G,H,N}$ and $BHQC$ is cyclic. Radical Axis Theorem at $(ABC),(BCEF),(AGFHQE),(BHQC)$ tells us that lines $AG,EF,QH,BC$ are concurrent, say the intersection point to be $R$. Notice that $BDHF$ and $AGFH$ cyclic easily implies $RGFB$ is cyclic by Miquel Point. Moreover, $P$ lies on the perpendicular bisector of $AG$ which is $OM$ and $PG$ is tangent to $(AGFHQE)$ at $G$, so $PA$ must be tangent to the same circle at $A$ and therefore is parallel to $BC$.

One can show that $R$ lies on $(GQN)$ easily. Let $RM$ hits $(MBC)$ at $J$. Observe that $AD,BE,CF$ are concurrent at $H$ and $R=EF\cap BC$, so by Ceva-Menelause, $(R,D;B,C)=-1$. Since that $N$ is the midpoint of $BC$, we have $RD\times RN=RB\times RC$. But by Power of Point's Theorem, we have $RJ\times RN=RB\times RC=RD\times RN$. This results in $J$ lying on the nine-point circle of $\triangle{ABC}$, so $\angle{RJN}=180^\circ-\angle{MJN}=180^\circ-\angle{MDN}=90^\circ$, so $J$ lies on $(RGQN)$.

Lastly, we claim that $J$ lies on $(APGM)$. Indeed,
\begin{align*} \angle{GJM}&=180^\circ-\angle{GJR}\\ &=180^\circ-\angle{GNR}\\ &=180^\circ-\angle{HND}\\ &=90^\circ+\angle{GHA}\\ &=90^\circ+\frac{180^\circ-2\angle{GPM}}{2}\\ &=180^\circ-\angle{GPM} \end{align*}
For the final act, simply see that $\angle{MJN}+\angle{PJM}=\angle{MDN}+\angle{PGM}=90^\circ+90^\circ=180^\circ$, so $\overline{P,J,N}$, as desired. $\blacksquare$

P.S. I was about to invert when I suddenly realized that synthetic approach is more than enough for this problem :D
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Cali.Math
128 posts
Cali.Math
#96 Mar 10, 2025, 4:59 PM
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We uploaded our solution https://calimath.org/pdf/USATSTST2016-2.pdf on youtube https://youtu.be/FA4RxRnKcFk.
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waterbottle432
6 posts
waterbottle432
#97 Apr 21, 2025, 10:36 AM
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Let $E=AH \cap ABC$, $D$ be reflection of $E$ w.r.t. $ON$ and $L=AH \cap BC.$ Since $AH\perp BC$ and $ON\perp BC \Longrightarrow AH\parallel ON.$ Since $ON\perp ED \Longrightarrow AH\perp ED$ Since $\angle ECB = \angle EAB = \angle HCB$ it follows that $BC$ bisects segment $HE.$ Therefore, $NH=NE=ND.$ Since $\angle HED = 90^\circ \Longrightarrow H,N,D$ collinear and $A,O,D$ collinear. Since $AM=MH,AO=OD \Longrightarrow MO\parallel HD.$ Since $\angle AGH = 90^\circ = \angle AGD \Longrightarrow G,H,N,D$ collinear. Let $F=HQ\cap BC.$ By P.O.P. $FH \cdot HQ=AH\cdot HL=GH\cdot HN \Longrightarrow G,F,Q,N$ concyclic. $\angle AGH+\angle FGH = 90^\circ+90^\circ=180^ \circ \Longrightarrow A,G,F$ collinear. Let $B'$ be a point that lies on $AC$ s.t. $BB'\perp AC.$ Define $C'$ similarly. Clearly $A,G,H,Q,B',C'$ concyclic. Since $\angle GAM=\angle GAH = \angle HGS = \angle OPS = \angle MPG \Longrightarrow P,G,M,A$ concyclic.

Let $T=(PAMG)\cap(MBC)$. By Radical Axis concurrence theorem on $(GTMA),(BTMC),(AGBC) \Longrightarrow F,T,M$ collinear. By Radical Axis concurrence theorem on $(BCB'C'),(AGHQ),(AGBC) \Longrightarrow F,C',B'$ collinear. By P.O.P. $FT\cdot FM=FB\cdot FC=FB'\cdot FC' \Longrightarrow T$ lies on the nine point circle of $\triangle ABC \Longrightarrow M,T,C',L,N,B'$ comcyclic. Therefore, $\angle FTN = 180^\circ -\angle MTN = 180^\circ -\angle MLN=90^\circ \Longrightarrow T$ lies on $(GNQ).$ Thus, $T=(GNQ)\cap(MBC)$.

Since $OM\parallel NH \Longrightarrow OM\perp AG$ and since $O$ is center of $(AGBC) \Longrightarrow OM$ is perpendicular bisector of $AG$. Thus, $PM$ is diameter of $(PGTMA)$. Since $\angle FTN = 90^\circ = \angle PTM$ and $F,T,M$ collinear $\Longrightarrow T$ lies on $PN$ and we are done.
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alexanderchew
10 posts
alexanderchew
#98 May 1, 2025, 1:38 AM
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Solution. Let $X=EF \cap BC$, where E and F are such that BE and CF are altitudes of ABC. We claim that T is the intersection of $PN$ and $MX$.
First, we show that $T$ lies on $(XGQN)$. Note that since $B$ is the pole of $PTN$, the conclusion follows.
Next, we show that $T$ lies on $(MBC)$. By Power of a Point theorem, $XT\times XM = XE\times XF$ since T lies on the nine-point circle. Since $XE\times XF = XB\times XC$, we have $XT\times XM = XB\times XC$ which implies that $T$ lies on $(MBC)$. Thus we are done.
This post has been edited 1 time. Last edited by alexanderchew, May 1, 2025, 1:48 AM
Reason: Forgot to add something
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Markas
150 posts
Markas
#99 May 11, 2025, 5:48 PM
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Let DEF be the orthic triangle in $\triangle ABC$. Let $(ABC) = \omega_1$, $(BFEC) = \omega_2$, $(AGFHE) = \gamma$. Now $rad(\omega_1,\omega_2) = BC$, $rad(\omega_1,\gamma) = AG$, $rad(\omega_2,\gamma) = FE$ $\Rightarrow$ their radical center is $AG \cap BC \cap FE = T$. By Brokard on BFEC we get that H is the orthocenter of $\triangle ATN$ $\Rightarrow$ G, H, N lie on one line, also T, H, Q lie on one line and $\angle TGN = \angle TQN = 90^{\circ}$ since $\angle HGA = \angle HQA = 90^{\circ}$ from AH diameter. Let $PN \cap TM = R$. It is enough to prove that $R \in (GNQ)$ and $R \in (MBC)$. To show that $R \in (GNQ)$ we need to show $R \in (TGQN)$ - it is enough to prove $\angle TRN = 90^{\circ}$. Wrt. $\gamma$ AG is the polar of P and EF is the polar of N $\Rightarrow$ $T \in AG$, T $\in$ polar of P and $T \in EF$, T $\in$ polar of N and from La Hire P $\in$ polar of T and N $\in$ polar of T $\Rightarrow$ PN $\equiv$ polar of T $\Rightarrow$ $\angle TRN = 90^{\circ}$ $\Rightarrow$ $R \in (GNQ)$. It is left to show that $R \in (MBC)$. Now $R \in (GPAM)$ from $\angle PGM = \angle PRM = \angle PAM = 90^{\circ}$ $\Rightarrow$ TR.TM = TG.TA = TB.TC $\Rightarrow$ TR.TM = TB.TC $\Rightarrow$ RMBC is cyclic $\Rightarrow$ $R \in (MBC)$ $\Rightarrow$ $R \in (GNQ)$, $R \in (MBC)$ and $R \in PN$ $\Rightarrow$ we are ready.
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