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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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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.
[*]March 6th (Thursday), 4:00pm PT/7:00pm ET, Free Webinar on Math Competitions from elementary through high school. Join us for an enlightening session that demystifies the world of math competitions and helps you make informed decisions about your contest journey.
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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
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D1010 : How it is possible ?
Dattier   13
N 17 minutes ago by Dattier
Source: les dattes à Dattier
Is it true that$$\forall n \in \mathbb N^*, (24^n \times B \mod A) \mod 2 = 0 $$?

A=1728400904217815186787639216753921417860004366580219212750904
024377969478249664644267971025952530803647043121025959018172048
336953969062151534282052863307398281681465366665810775710867856
720572225880311472925624694183944650261079955759251769111321319
421445397848518597584590900951222557860592579005088853698315463
815905425095325508106272375728975

B=2275643401548081847207782760491442295266487354750527085289354
965376765188468052271190172787064418854789322484305145310707614
546573398182642923893780527037224143380886260467760991228567577
953725945090125797351518670892779468968705801340068681556238850
340398780828104506916965606659768601942798676554332768254089685
307970609932846902
13 replies
Dattier
Mar 10, 2025
Dattier
17 minutes ago
J
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Interesting inequality
sqing   1
N 17 minutes ago by sqing
Source: Own
Let $ a,b\geq 2 . $ Prove that
$$ (a^2-1)(b^2-1) (1-ab)+\frac{27}{8}a^2b^2\leq 27$$$$ (a^2-1)(b^2-1)(1-a^2b^2 )+\frac{81}{4}a^2b^2 \leq 189$$$$ (a^2-1)(b^2-1)(1-a^2b^2 )+ 162 ab \leq 513$$$$ (a^2-1)(b^2-1) (1-a^2b^2 )+21 a^2b^2\leq \frac{3219}{16}$$$$ (a^2-1)(b^2-1) (1-ab)+\frac{27}{8}a^2b^2\leq\frac{415+61\sqrt{61}}{18}$$
1 reply
1 viewing
sqing
an hour ago
sqing
17 minutes ago
J
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Minimal Grouping in a Complete Graph
swynca   1
N 27 minutes ago by swynca
Source: 2025 Turkey TST P1
In a complete graph with $2025$ vertices, each edge has one of the colors $r_1$, $r_2$, or $r_3$. For each $i = 1,2,3$, if the $2025$ vertices can be divided into $a_i$ groups such that any two vertices connected by an edge of color $r_i$ are in different groups, find the minimum possible value of $a_1 + a_2 + a_3$.
1 reply
1 viewing
swynca
3 hours ago
swynca
27 minutes ago
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Nice FE as the First Day Finale
swynca   1
N 35 minutes ago by swynca
Source: 2025 Turkey TST P3
Find all $f: \mathbb{R} \rightarrow \mathbb{R}$ such that, for all $x,y \in \mathbb{R}-\{0\}$,
$$ f(x) \neq 0 \text{ and } \frac{f(x)}{f(y)} + \frac{f(y)}{f(x)} - f \left( \frac{x}{y}-\frac{y}{x} \right) =2 $$
1 reply
swynca
3 hours ago
swynca
35 minutes ago
J
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Cn/lnn bound for S
EthanWYX2009   0
39 minutes ago
Source: 2025 March 谜之竞赛-2
Prove that there exists an constant $C,$ such that for all integer $n\ge 2$ and a subset $S$ of $[n],$ satisfy $a\mid\tbinom ab$ for all $a,b\in S,$ $a>b,$ then $|S|\le \frac{Cn}{\ln n}.$

Created by Yuxing Ye
0 replies
+1 w
EthanWYX2009
39 minutes ago
0 replies
J
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Natural function and cubelike expression
sarjinius   2
N 44 minutes ago by Kaimiaku
Source: Philippine Mathematical Olympiad 2025 P8
Let $\mathbb{N}$ be the set of positive integers. Find all functions $f : \mathbb{N} \to \mathbb{N}$ such that for all $m, n \in \mathbb{N}$, \[m^2f(m) + n^2f(n) + 3mn(m + n)\]is a perfect cube.
2 replies
sarjinius
Mar 9, 2025
Kaimiaku
44 minutes ago
J
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hard problem
Noname23   3
N an hour ago by Noname23
problem
3 replies
Noname23
Sunday at 4:57 PM
Noname23
an hour ago
J
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Roots, bounding and other delusions
anantmudgal09   28
N an hour ago by kes0716
Source: INMO 2021 Problem 6
Let $\mathbb{R}[x]$ be the set of all polynomials with real coefficients. Find all functions $f: \mathbb{R}[x] \rightarrow \mathbb{R}[x]$ satisfying the following conditions:

[list]
[*] $f$ maps the zero polynomial to itself,
[*] for any non-zero polynomial $P \in \mathbb{R}[x]$, $\text{deg} \, f(P) \le 1+ \text{deg} \, P$, and
[*] for any two polynomials $P, Q \in \mathbb{R}[x]$, the polynomials $P-f(Q)$ and $Q-f(P)$ have the same set of real roots.
[/list]

Proposed by Anant Mudgal, Sutanay Bhattacharya, Pulkit Sinha
28 replies
anantmudgal09
Mar 7, 2021
kes0716
an hour ago
J
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square geometry bisect $\angle ESB$
GorgonMathDota   11
N an hour ago by miiirz30
Source: BMO SL 2019, G1
Let $ABCD$ be a square of center $O$ and let $M$ be the symmetric of the point $B$ with respect to point $A$. Let $E$ be the intersection of $CM$ and $BD$, and let $S$ be the intersection of $MO$ and $AE$. Show that $SO$ is the angle bisector of $\angle ESB$.
11 replies
GorgonMathDota
Nov 8, 2020
miiirz30
an hour ago
J
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Inspired by my own results
sqing   5
N an hour ago by sqing
Source: Own
Let $ a , b $ be reals such that $ a+b+ab=1. $ Show that$$ 1-\frac{1 }{\sqrt2}\le \frac{1}{a^2+1}+\frac{1}{b^2+1}\le 1+\frac{1 }{\sqrt2} $$Let $ a , b\geq 0 $ and $ a+b+ab=1. $ Show that$$ \frac{3}{2}\le \frac{1}{a^2+1}+\frac{1}{b^2+1}\le 1+\frac{1 }{\sqrt2} $$
5 replies
sqing
Yesterday at 8:32 AM
sqing
an hour ago
J
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Polygon formed by the edges of an infinite chessboard
AlperenINAN   1
N an hour ago by AlperenINAN
Source: Turkey TST 2025 P5
Let $P$ be a polygon formed by the edges of an infinite chessboard, which does not intersect itself. Let the numbers $a_1,a_2,a_3$ represent the number of unit squares that have exactly $1,2\text{ or } 3$ edges on the boundary of $P$ respectively. Find the largest real number $k$ such that the inequality $a_1+a_2>ka_3$ holds for each polygon constructed with these conditions.
1 reply
AlperenINAN
3 hours ago
AlperenINAN
an hour ago
J
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Interesting inequality
sqing   5
N 2 hours ago by sqing
Source: Own
Let $ a,b\geq 2 . $ Prove that
$$(a^2-1)(b^2-1) -6ab\geq-15$$$$(a^2-1)(b^2-1) -7ab\geq -\frac{58}{3}$$$$(a^3-1)(b^3-1) -\frac{21}{4}a^2b^2\geq -35$$$$(a^3-1)(b^3-1) -6a^2b^2\geq-\frac{2391}{49}$$
5 replies
1 viewing
sqing
5 hours ago
sqing
2 hours ago
J
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Problem 2830
sqing   1
N 2 hours ago by invisibleman
Source: SXTB (2)2025
Let $ a,b>0 $ and $ \frac{1}{a^2+1}+ \frac{1}{b^2+1}=t $ $(1<t<2). $ Find the value range of $ a+b. $
h
1 reply
sqing
Yesterday at 8:15 AM
invisibleman
2 hours ago
J
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Polynomials and powers
rmtf1111   26
N 2 hours ago by ihategeo_1969
Source: RMM 2018 Day 1 Problem 2
Determine whether there exist non-constant polynomials $P(x)$ and $Q(x)$ with real coefficients satisfying
$$P(x)^{10}+P(x)^9 = Q(x)^{21}+Q(x)^{20}.$$
26 replies
rmtf1111
Feb 24, 2018
ihategeo_1969
2 hours ago
J
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J
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Polish MO Finals 2018, Problem 5
j___d   34
N Mar 15, 2025 by joshualiu315
An acute triangle $ABC$ in which $AB<AC$ is given. Points $E$ and $F$ are feet of its heights from $B$ and $C$, respectively. The line tangent in point $A$ to the circle escribed on $ABC$ crosses $BC$ at $P$. The line parallel to $BC$ that goes through point $A$ crosses $EF$ at $Q$. Prove $PQ$ is perpendicular to the median from $A$ of triangle $ABC$.
34 replies
j___d
Apr 19, 2018
joshualiu315
Mar 15, 2025
J
Polish MO Finals 2018, Problem 5
G H J
Reveal topic tags
geometry
Poland
radical axis
geometry solved
projective geometry
radical axes
Hi
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G H BBookmark kLocked kLocked NReply
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j___d
340 posts
j___d
#1 Apr 19, 2018, 12:26 PM • 7 Y
Y by Mathuzb, khoonyu, mathematicsy, itslumi, tiendung2006, Adventure10, Mango247
An acute triangle $ABC$ in which $AB<AC$ is given. Points $E$ and $F$ are feet of its heights from $B$ and $C$, respectively. The line tangent in point $A$ to the circle escribed on $ABC$ crosses $BC$ at $P$. The line parallel to $BC$ that goes through point $A$ crosses $EF$ at $Q$. Prove $PQ$ is perpendicular to the median from $A$ of triangle $ABC$.
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fastlikearabbit
27684 posts
fastlikearabbit
#2 Apr 19, 2018, 12:52 PM • 4 Y
Y by microsoft_office_word, guptaamitu1, Adventure10, Mango247
j___d wrote:
An acute triangle $ABC$ in which $AB<AC$ is given. Points $E$ and $F$ are feet of its heights from $B$ and $C$, respectively. The line tangent in point $A$ to the circle escribed on $ABC$ crosses $BC$ at $P$. The line parallel to $BC$ that goes through point $A$ crosses $EF$ at $Q$. Prove $PQ$ is perpendicular to the median from $A$ of triangle $ABC$.

Let $H_A$ be the A-HM point. As the polar of $M$-the midpoint of $BC$ passes through $Q$, by La Hire’s theorem we obtain that $QA=QH_A$.
It’s well known that $PH_A$ is tangent to $\odot(BH_AC) $ * . So $PH_A^2=PB\cdot PC=PA^2$. So $PQ$ is the perpendicular bisector of $AH_A$.

* look at Example 2 from https://www.awesomemath.org/wp-pdf-files/math-reflections/mr-2017-02/article_1_a_special_point_on_the_median.pdf
This post has been edited 2 times. Last edited by fastlikearabbit, Apr 19, 2018, 1:06 PM
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MarkBcc168
1593 posts
MarkBcc168
#3 Apr 19, 2018, 12:53 PM • 1 Y
Y by Adventure10
Nice problem!

Let $T$ be the reflection of $H$ w.r.t. $A$, $M$ be the midpoint of $BC$ and $A'$ be the antipode of $A$ w.r.t. $\odot(ABC)$.

Since $\triangle ABC\cup P\cup A'\sim\triangle AEF\cup Q\cup H$, we see that $\frac{AP}{AQ} = \frac{AA'}{AH}= \frac{AT}{AA'}$. Combining with $\angle TAQ=\angle PAA'=90^{\circ}$ gives $\triangle ATA'\sim\triangle AQP$. So $\angle(TA', PQ) = \angle(AT, AQ)=90^{\circ}$.

Clearly $BHCA'$ is parallelogram so $M$ is the midpoint of $HA'$. So $TA'\parallel AM$. Combining with the previous paragraph gives $PQ\perp AM$ as desired.
This post has been edited 1 time. Last edited by MarkBcc168, Apr 6, 2020, 10:07 AM
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rmtf1111
698 posts
rmtf1111
#4 Apr 19, 2018, 1:10 PM • 3 Y
Y by microsoft_office_word, Adventure10, Mango247
Let $H_A$ be the A-Humpty point, clearly $(AH_AEF)=-1$ and because $QA$ is tangent to $\odot(AEF)$ and $Q$ lies on $EF$ we have that $QA=QH_A$. Because $P$ is the center of the A-Apollonius circle, which passes through both $A$ and $H_A$ we have that $PQ$ is perpendicular to $\overline{AH_A}$, which is precisely the A-median of $\triangle{ABC}$.
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GGPiku
402 posts
GGPiku
#5 Apr 20, 2018, 1:49 PM • 12 Y
Y by Anar24, mijail, platypus43, tapir1729, ApraTrip, Maths_is_my_life, PRMOisTheHardestExam, guptaamitu1, packlj, Adventure10, Mango247, endless_abyss
Is this correct?
Take the circles $C(A,0)$ and $C(BCEF)$. We have $PA^2=PB\times PC$ and $QA^2=QE\times QF$ hence $PQ$ is the radical axis the 2 circles with centers $A$ and $M$, hence we are done.
This post has been edited 3 times. Last edited by GGPiku, Apr 20, 2018, 1:55 PM
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cirey
23 posts
cirey
#7 Apr 21, 2018, 2:05 PM • 3 Y
Y by Omeredip, Adventure10, Mango247
Here is a bashy solution, in which I will prove that $\overrightarrow{AM}\bullet\overrightarrow{PQ}=0$, $M$ being the midpoint of $BC$.

http://i64.tinypic.com/25qvkuq.png

Note that this is equivalent to $(\overrightarrow{AB}+\overrightarrow{AC})\bullet(\overrightarrow{PA}+\overrightarrow{AQ})=0$.

Now, observe these four equalities:

$\overrightarrow{AB}\bullet\overrightarrow{PA}=|AB|\cdot|PA|\cdot\cos{(180-\hat{C})}$

$\overrightarrow{AB}\bullet\overrightarrow{AQ}=|AB|\cdot|AQ|\cdot\cos{(180-\hat{B})}$

$\overrightarrow{AC}\bullet\overrightarrow{PA}=|AC|\cdot|PA|\cdot\cos{\hat{B}}$

$\overrightarrow{AC}\bullet\overrightarrow{AQ}=|AC|\cdot|AQ|\cdot\cos{\hat{C}}$

Adding these with using $|PA|=|AQ|\cdot\cos{\hat{A}}$ leaves to prove that $\frac{|AC|}{|AB|}=\frac{\cos{\hat{B}}+\cos{\hat{A}}\cdot\cos{\hat{C}}}{\cos{\hat{C}}+\cos{\hat{A}}\cdot\cos{\hat{B}}}$,

which is equal to $\frac{\cos{\hat{B}}+\cos{(\hat{A}-\hat{C})}}{\cos{\hat{C}}+\cos{(\hat{A}-\hat{B})}}=\frac{\sin{\hat{B}}\cdot\sin{\hat{A}}}{\sin\hat{C}\cdot\sin\hat{A}}$, the conclusion follows.
This post has been edited 1 time. Last edited by cirey, Apr 22, 2018, 8:38 AM
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anantmudgal09
1979 posts
anantmudgal09
#8 Apr 21, 2018, 8:17 PM • 3 Y
Y by MatBoy-123, Adventure10, Mango247
j___d wrote:
An acute triangle $ABC$ in which $AB<AC$ is given. Points $E$ and $F$ are feet of its heights from $B$ and $C$, respectively. The line tangent in point $A$ to the circle escribed on $ABC$ crosses $BC$ at $P$. The line parallel to $BC$ that goes through point $A$ crosses $EF$ at $Q$. Prove $PQ$ is perpendicular to the median from $A$ of triangle $ABC$.

Note that $Q$ is the radical center of $\odot(A), \odot(AEF), \odot(BC)$ hence $Q$ lies on the radical axis of $\odot(A), \odot(BC)$. Also $P$ is the radical center of $\odot(A), \odot(ABC), \odot(BC)$ hence $P$ also lies on the radical axis of $\odot(A), \odot(BC)$. Now the $A$-median passes through the center of $\odot(BC)$, the result follows.
This post has been edited 1 time. Last edited by anantmudgal09, Apr 21, 2018, 8:17 PM
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IstekOlympiadTeam
542 posts
IstekOlympiadTeam
#9 Apr 22, 2018, 5:34 PM • 3 Y
Y by bluedragon17, Adventure10, Mango247
Let $Z=EF\cap BC,K=EF\cap AH, T=AH\cap BC$.
It is well known fact that $ZH\perp AM$ $\implies$ it is enough to show that $ZH\parallel PQ$.

Let $F=ZH\cap AQ$. Let's show that $AQ=QF$ $\iff$ $\frac{AQ}{AF}=\frac{1}{2}$.
Using parellelism we have that \[AQ=\frac{|AK||ZT|}{KT} \ ,\ AF=\frac{|AH||ZT|}{HT}\]$\implies$ \[\boxed{\frac{AQ}{AF}=\frac{|AK||KT|}{|HT||AH|}}\]It is easy to show that last relatioon is equal to $\frac{1}{2}$ (Sine's Law).

Finally we have that $AQ=QF=PZ$ ($APZQ$ is alrealy a parallelogram since $AP\parallel EF$) $\implies$ $PQFZ$ is a parallelogram $\implies$ $ZH\parallel PQ$ as desired $\blacksquare$
This post has been edited 1 time. Last edited by IstekOlympiadTeam, Apr 22, 2018, 5:35 PM
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falantrng
249 posts
falantrng
#10 Apr 23, 2018, 8:03 AM • 1 Y
Y by Adventure10
This is a very nice algebra problem.(Codyj,USAMO 2018,P5)
We can find easily with barycentric coordinate
$P=(0,\frac{-2b^2}{2(c^2-b^2)},\frac{2c^2}{2(c^2-b^2)}),$ and
$Q=(\frac{2(c^2-b^2)}{2(c^2-b^2)},\frac{-a^2+b^2+c^2}{2(c^2-b^2)},\frac{-(-a^2+b^2+c^2)}{2(c^2-b^2)}).$
The rest is very easy.
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math_pi_rate
1218 posts
math_pi_rate
#11 Jun 28, 2018, 8:07 AM • 4 Y
Y by lahmacun, srijonrick, Adventure10, Mango247
Let $T$ be the midpoint of $AH$, where $H$ is the orthocenter of $\triangle ABC$. Also, Let $M_A$ be the midpoint of $BC$.

Note that $EF$ is the radical axis of $\odot (AEHF)$ and $\odot (BFEC) \Rightarrow TM_A$ is the perpendicular bisector of $EF$.

Also, $\angle PAB = \angle ACB \Rightarrow \angle PAF = \angle AFE \Rightarrow PA \parallel EF$

But, $TM_A$ is perpendicular to $EF \Rightarrow TM_A \perp PA \Rightarrow T$ is the orthocenter of $\triangle AM_AP \Rightarrow PT \perp AM_A$

Now, Let $H_A$ be the A-Humpty point and $PT \cap AM_A = X \Rightarrow TX \perp AH_A \Rightarrow X$ is the midpoint of $AH_A$.

Also, $M_AE$ and $M_AF$ are tangents to $\odot (AEHH_AF) \Rightarrow AEH_AF$ is a harmonic quadrilateral.

$\Rightarrow QH_A$ is also tangent to $\odot (AEH_AF) \Rightarrow Q, X, T, P$ are collinear $\Rightarrow PQ \perp AM_A \text{ } \blacksquare$
This post has been edited 2 times. Last edited by math_pi_rate, Oct 29, 2018, 1:12 PM
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soryn
5303 posts
soryn
#12 Jun 28, 2018, 8:09 AM • 2 Y
Y by Adventure10, Mango247
Nice problem from Poland..Nice solutions..
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math_pi_rate
1218 posts
math_pi_rate
#13 Oct 29, 2018, 1:05 PM • 2 Y
Y by Adventure10, Mango247
Sorry for double posting, but here's a bit different ending: Let $H_A$ be the $A$-Humpty point, and let $EF \cap BC=X$. From the various properties proved here, we have that $X$ lies on $HH_A$, and that $HH_A$ is perpendicular to the $A$-median. Thus it suffices to show that $PQ$ is parallel to $XH$. Let $XH \cap AQ=T$. Now, as both $EF$ and $AP$ are antiparallel to $BC$, we get that $EF$ is parallel to $PQ$. But, as $PX$ is parallel to $AQ$, we have that $APXQ$ is a parallelogram, and so $AQ=PX$. Also, as $AEH_AF$ is a harmonic quadrilateral, and cause $AQ$ is tangent to $\odot (AEHH_AF)$ at $A$, we must have that $QH_A$ is tangent to $\odot (AEHH_AF)$ at $H_A$, which gives $QH_A=QA$. But, $TH_A$ is perpendicular to $AH_A$, which means that $Q$ is the circumcenter of $\triangle AH_AT$, or equivalently $QT=QA=PX$. As $PX \parallel QT$, quadrilateral $PXTQ$ is a parallelogram $\Rightarrow PQ \parallel TX$. Hence, done. $\blacksquare$
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khanhnx
1617 posts
khanhnx
#14 Feb 23, 2019, 3:53 PM • 2 Y
Y by Adventure10, Mango247
Let $M$ be midpoint of $BC$ then we have: $PA^2$ $-$ $QA^2$ = $\overline{PB}$ . $\overline{PC}$ $-$ $\overline{QE}$ . $\overline{QF}$ = $P_{P / (BCEF)}$ $-$ $P_{Q / (BCEF)}$ = $PM^2$ $-$ $QM^2$ or $PQ$ $\perp$ $AM$
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Optx
4 posts
Optx
#15 May 9, 2019, 3:16 PM • 2 Y
Y by Adventure10, Mango247
Let T denote midpoint of AH where H is orthocenter of ABC. It easy to prove that T is orthocenter of APM since AT is perpendicular to BC and MT is perpendicular to AP. Therefore, PT is perpendicular to AM. Now, since Q lies on EF which is polar of M, then AM is polar of Q so QT is perpendicular to AM and we are done.
This post has been edited 1 time. Last edited by Optx, May 9, 2019, 3:16 PM
Reason: Mistake
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Ali3085
214 posts
Ali3085
#16 Aug 1, 2019, 4:25 PM • 3 Y
Y by Myriam2003, Adventure10, Mango247
let $T=EF \cap BC$ ,$N=EF \cap AD$,$X=AQ \cap TH$
from brocard on $EFBC$ we have that $AM$ is perpendicular to $TH$
so it suffices to show that $QP \parallel TX$
we have $AP \parallel TQ \implies AQTP $is parallelogram so it suffices to show that $Q$ is the midpoint of $AX$
but we have $(A,H;N,D) =_T (A,X:Q,P_\infty)=-1$ and we done :D
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jayme
9767 posts
jayme
#17 May 30, 2020, 8:56 AM • 1 Y
Y by Mango247
Dear Mathlinkers,

http://jl.ayme.pagesperso-orange.fr/Docs/Orthique%20encyclopedie%205.pdf p. 48-50.

Sincerely
Jean-Louis
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mathlogician
1051 posts
mathlogician
#18 Aug 8, 2020, 5:51 PM
Y by
Let $H$ be the orthocenter of $\triangle ABC$, and let $AH$ intersect $BC$ at $D$. Let $X_A$ be the $A$-humpty point of $\triangle ABC$. Let $L$ be the midpoint of $AH$, and let $\omega$ be the circle with diameter $AH$, let $K$ be the foot of the perpendicular from $H$ to $AP$. Let $J$ be the midpoint of $EF$, which lies on line $LM$ by inversion around $\omega$.

Claim: $QA = QX_A$.

Proof: Note that $-1 =(AX_A;EF)$ by Three Tangents Lemma, and since $QA$ is a tangent to $\omega$, $QX_A$ must also be, as desired.

Claim: $PA = PX_A$.

Proof: First, remark that $PKHD$ is cyclic, so by radical axes on $(PKHD)$ and $(DHX_AM)$ we find that $PKX_AM$ is cyclic. We claim that $KLX_AM$ is also cyclic, which would imply the $L$ is the arc midpoint of $\triangle PKX_A$, and thus $\angle APL = \angle LPX_A$, which would finish the claim.

To this end, we invert around $\omega$. We wish to show that $K,J,X_A$ are collinear. Redefine $J$ to be the intersection of $KX_A$ and $EF$. Remark that $AK \parallel EF$, so $-1 = (EF;AX_A) \stackrel{K}{=}(EF;\infty_{EF}J)$, so $J$ is the midpoint of $EF$, as desired.

Finally, consider the circles centered around $P$ and $Q$ passing through $A$ and $X_A$. Their radical axis is $AM$, thus $PQ \perp AM$, as desired.

Remarks: After reading the solutions I realized how much I overcomplicated this problem. However, I think most steps in this proof are really natural if you've seen HM point before; most points that showed up in my diagram are standard pieces of the orthocenter puzzle; the only strange one was $P$ and $K$, which was dealt with by only considering the property that $AP \parallel EF$ instead of trying to use the tangent.
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franzliszt
23531 posts
franzliszt
#19 Oct 17, 2020, 11:00 PM
Y by
Let the midpoint of $BC$ be $M$.

Invert about the circle centered at $A$ with radius $\sqrt{AE \cdot AC}=\sqrt{AF \cdot AB}$. Then $E$ and $F$ go to $B$ and $C$, so $(AEF)$ gets sent to line $BC$ and $(ABC)$ gets sent to line $EF$.

$P$ goes to the other intersect of line $AP$ and $(AEF)$ and $Q$ goes to the second intersection of $(ABC)$ and line $QA$. Call these two points $P'$ and $Q'$, respectively.

We want to show that lines $\overline{AM} \perp \overline{PQ}$. It suffices to show that their images under the inversion are orthagonal. Since $\overline{AM}$ goes through the center of inversion ($A$), it gets sent to itself. $\overline{PQ}$ gets sent to $(P'AQ')$. For a circle and a line to be orthogonal, the line must go through the circle's center. So to finish, it suffices to show that $MP'=MA=MQ'$.

The angle between $\overline{AH}$ and $\overline{BC}$ maps to the angle between $\overline{AH}$ and $\overline{Q'A}$ so $\angle Q'AH=90^\circ$ and $QA \parallel BC$. Hence $ABCQ'$ is a trapezoid. $ABCQ'$ is cyclic and consequently an isocoleces trapezoid so, combined with the fact that $M$ is a midpoint, $\overline{MA}=\overline{MQ'}$. Similarly, $\overline{PA} \parallel \overline{EF}$ so $P'AEF$ is a trapezoid. $P'AEF$ is also cyclic and consequently an isocoleces trapezoid. Now, we prove the following

Claim. $M$ lies on the perpendicular bisector of $EF$.
Proof. Notice that $\measuredangle BFC = \measuredangle BEC$ so $BFEC$ is cyclic. It is well known that the circumcenter of a right triangle is the midpoint of the hypotenuse. The circumcenter of both $\triangle BFC$ and $\triangle BEC$ is $M$. Hence, it must also be the circumcenter of $(BFEC)$. The circumcenter of a cyclic quadrilateral is the intersection of the perpendicular bisectors of its sides. So the perpendicular bisector of $EF$ meets $BC$ at $M$. $\square$

Hence $M$ is on the perpendicular bisector of $AP'$ and $MA=MP'$. Thus, $MP'=MA=MQ'$ and the problem is solved. $\blacksquare$
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iman007
270 posts
iman007
#20 May 13, 2021, 7:28 PM
Y by
j___d wrote:
An acute triangle $ABC$ in which $AB<AC$ is given. Points $E$ and $F$ are feet of its heights from $B$ and $C$, respectively. The line tangent in point $A$ to the circle escribed on $ABC$ crosses $BC$ at $P$. The line parallel to $BC$ that goes through point $A$ crosses $EF$ at $Q$. Prove $PQ$ is perpendicular to the median from $A$ of triangle $ABC$.
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First of all note that $(GD,BC)=-1$ since $BEFC$ is a complete quadrilateral. also $\angle PAF=\angle ACB=\angle AFE$ so $AP||QG$, now from $(GD,BC)=-1$ we understand that $(AE,Ft)=-1$ which gives that $QA=QT$ on the other hand $T$ is A-humpty point so $PA=PT$ so $PQ$ is the perpendicular bisecot of $AT$ and we are done.(You can read more about A-Humpty point here)
This post has been edited 1 time. Last edited by iman007, May 13, 2021, 7:29 PM
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RM1729
63 posts
RM1729
#21 Nov 9, 2021, 6:21 PM
Y by
An excellent problem! Let $H$ denote the orthocentre of $ABC$. Let $\omega_1$ denote the circumcircle of $ABC$

First, note that $AEHf$ and $EFCB$ are cyclic quadrilaterals. Denote by $\omega_2$ the circle through $AEFH$ (diameter $AH$) and $\omega_3$ the circle through $EFCB$ (diameter $BC$ and centre $M_{BC}$).

Now observe that the parallel through $A$ to $BC$ is simply the tangent at $A$ to $\omega_2$

We now define a circle of radius zero at point $A$ as $\omega_4$ and consider the radical centre of $\omega_1$, $\omega_3$, $\omega_4$

Note that the radical axes are $BC$, tangent at $A$ and the radical axis of the zero radius circle at $A$ and the circle through $EFCB$

Since $BC \cap$ tangent at $A = P$, $P$ lies on the 3rd radical axis too.

We now consider the radical centre of $\omega_2$, $\omega_3$ and $\omega_4$

Note that the radical axes are $EF$, parallel at $A$ and the same radical axis of the zero radius circle at $A$ and the circle through $EFCB$

Since $EF \cap $ parallel at $A = Q$, $Q$ lies on the same radical axis too

Thus line $PQ$ is just the radical axis of the radius $0$ circle at $A$ and the circle through $EFCB$. Since the line joining the centres is perpendicular to the radical axis, $AM \perp PQ$
This post has been edited 1 time. Last edited by RM1729, Nov 9, 2021, 6:22 PM
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DottedCaculator
7303 posts
DottedCaculator
#22 Dec 11, 2021, 3:55 AM • 2 Y
Y by MiraclesINmaths, Elnuramrv
Solution
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ike.chen
1162 posts
ike.chen
#23 Dec 13, 2021, 6:58 PM
Y by
Let $\omega_a$ denote the point circle $A$ and $M$ be the midpoint of $BC$. It's clear that $$Pow_{\omega_a}(P) = PA^2 = Pow_{(ABC)}(P) = PB \cdot PC = Pow_{(BC)}(P)$$and the Three Tangents Lemma gives $$Pow_{\omega_a}(Q) = QA^2 = Pow_{(AEF)}(Q) = QE \cdot QF = Pow_{(BC)}(Q)$$so $PQ$ is the Radical Axis of $\omega_a$ and $(BC)$. But $(BC)$ is centered at $M$, so we're done. $\blacksquare$


Remark: Utilizing the $A$-Humpty point is probably more motivated than this solution.
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Mahdi_Mashayekhi
689 posts
Mahdi_Mashayekhi
#24 Dec 16, 2021, 7:20 AM
Y by
In order to prove PQ ⊥ AM we need to prove |PA^2 - PM^2| = |QA^2 - QM^2| or |PA^2 - QA^2| = |PM^2 - QM^2|
|PA^2 - QA^2| = PB.PC - QE.QF = power of P w.r.t BFEC - power of Q w.r.t BFEC
Let M be midpoint of BC. M is center of BFEC so :
power of P w.r.t BFEC - power of Q w.r.t BFEC = |PM^2 - QM^2|
so at the end we have |PA^2 - QA^2| = P w.r.t BFEC - power of Q w.r.t BFEC = |PM^2 - QM^2| and this will prove our problem so we're Done.
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Mogmog8
1080 posts
Mogmog8
#25 Jan 22, 2022, 5:05 AM • 2 Y
Y by centslordm, megarnie
Let $M$ be the midpoint of $\overline{BC},$ $\omega_1=(M,\overline{MB}),$ and $\omega_2=(A,0)$ with $(O,r)$ denoting the circle with center $O$ and radius $r.$ Notice $\angle PAB=\angle ACB$ so $\triangle ACP\sim\triangle BAP.$ Hence, $$\text{pow}_{\omega_2}{P}=AP^2=PB\cdot PC=\text{pow}_{\omega_1}{P}.$$Similarly, $Q$ lies on the radical axis of $\omega_1$ and $\omega_2$ by the three tangents lemma. Radical Axis finishes. $\square$

Remarks: (Motivation) My solution was motivated by the three tangents lemma, which had occurred to me after seeing $A,E,F,$ and $\overline{AQ}\parallel\overline{BC}.$ Since $M$ was the center of $(BCEF),$ radical axis was natural and the solution followed.
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anurag27826
93 posts
anurag27826
#27 Jun 3, 2022, 10:05 AM
Y by
Special Thanks to guptaamitu1 for referring and motivating me to solve this problem :D.

consider a circle of radius zero
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JAnatolGT_00
559 posts
JAnatolGT_00
#28 Jun 3, 2022, 5:29 PM • 1 Y
Y by Mango247
From $\angle BAP=\angle BCA=\angle EFA =\angle EAQ$ we deduce $$|QA|^2=|QE|\cdot |QF|,|PA|^2=|PB|\cdot |PC|,$$hence $PQ$ is the radical axis of $A,\odot (BCEF),$ the conclusion follows.
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GeoKing
515 posts
GeoKing
#29 Jun 11, 2022, 4:08 AM
Y by
Sol:- Note that $P$ is the radical center of $(A, 0), (BC), (ABC)$ and $Q$ is the radical center of $(A,0), (BC), (AED)$.Hence the radax of $(A, 0)$ and $(BC)$ is $A$- median.
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blackbluecar
302 posts
blackbluecar
#30 Sep 11, 2022, 6:22 AM • 1 Y
Y by Mango247
We claim $P$ and $Q$ lie on the radax of $(A)$ and $(BFEC)$ (which is sufficient). By PoP on $(ABC)$ we have $PA^2 = PB \cdot PC$. It is well known that $AQ$ is tangent to $A$. By PoP $AQ^2 = QE \cdot QF$. Proving our result.
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minusonetwelth
225 posts
minusonetwelth
#31 Apr 20, 2023, 10:54 PM
Y by
Lol I complicated the solution so much although iÍ still think it is really nice.

Let $X$ be the intersection of $AM$ with the nine-point circle $\gamma$. Also, let $Y$ be the intersection of $AH$ with $\gamma$. It is well-known that $MY$ is a diameter of $\gamma$, so $\angle YXM=90^\circ$. It now suffices to show that $P,Q\in XY$.

It is well-known that $(AEHF)$ is tangent to the line through $A$ to $BC$. To see that, simply note $\angle QAE=\angle ACB=180^\circ-\angle BFE=\angle EFA$. It is also easy to see that $\triangle AXY$ and $\triangle AMD$ are homothetic at $A$, so $(AXY)$ is tangent to $QA$ as well. Applying the radical axis theorem to $\gamma$, $(AEHF)$ and $(AXY)$ shows that $Q\in XY$.

An angle chase shows that
\[\angle PAB=\angle ACB=\angle EFA=\angle AEH\]meaning that $AP\parallel EF$. As $MY\perp EF$, we also have $MY\perp AP$. Therefore, letting $Z=MY\cap AP$, we see that $Z$ lies on $(AYX)$. Therefore, $AZDM$ is cyclic, and apllying the radical axis theorem on $(AZDM)$, $\gamma$ and $(AYX)$ we see that $P\in YX$, so we are done.
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dolphinday
1310 posts
dolphinday
#32 Feb 4, 2024, 6:16 PM
Y by
Let $M$ be the midpoint of $BC$.
We claim that $PQ$ is the radical axis of the circle with radius $0$ centered at $A$, and $(BFEC)$.
Since by Power of a Point on $(ABC)$, we have $PA^2 = PB \cdot PC$, $P$ has equal power to both $(A)$ and $(BFEC)$. Then we have $\angle QAE = \angle C = \angle AFE$, and $\angle Q = \angle Q$, $\triangle QAF \sim \triangle QEA$. From this, we have $\frac{QA}{QE} = \frac{QF}{QA} \implies QA^2 = QE \cdot QF$ so $Q$ also lies on the radical axis of $(A)$ and $(BFEC)$. We finish by noting that $A$ and $M$ are the respective centers of $(A)$ and $(BFEC)$, so $AM \perp PQ$.
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john0512
4170 posts
john0512
#33 Mar 25, 2024, 4:52 AM
Y by
oops radius 0 is so smart i didn't think of that

here is a probably isomorphic solution

We first eliminate $P$. The conclusion is equivalent to $$PM^2-PA^2=QM^2-QA^2.$$However, note that $$PM^2-PA^2=PM^2-PB\cdot PC=PM^2-(PM^2-MB^2)=MB^2=\frac{a^2}{4}.$$Thus, it remains to show that $$QM^2-QA^2=\frac{a^2}{4}.$$
Note that $$\angle QAE=\angle QFA=\gamma$$since $AQ\parallel BC$ and $BFEC$ is cyclic. Thus, $$QA^2=QE\cdot QF.$$Hence, $$QE\cdot QF=Pow_{(BFEC)}(Q)=QM^2-\frac{a^2}{4},$$as desired.
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ismayilzadei1387
219 posts
ismayilzadei1387
#34 Mar 26, 2024, 2:52 PM
Y by
Decent problem indeed.
$EF \cap BC$ at $X_{A}$
$X_{A}H \cap AQ$ at $R$
$EF \cap AH$ at $L$
We have $X_{A}H$ is prependicular to $AM$ that motivates us to prove $PQ$ is parallel to $X_{A}H$
We also have $AQ$ is parallel to $BC$ and $PX_{A}$ and $AP$ is parallel to $X_{A}Q$ so that $APX_{A}Q$ is parallelogram
It remains to prove $Q$ is midpoint of $AR$
From easy harmonic bundle $(A,H;L,AH \cap BC) \equiv (A,R;Q,V_\infty)=-1$.
which leads conclusion.
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drmzjoseph
444 posts
drmzjoseph
#35 Mar 12, 2025, 11:11 PM
Y by
Idk isn't the question trivial? PQ is the radical axis between (A) (radius 0) and the circle of diameter BC?

I think post #23 said it but it's quite confused ?
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cj13609517288
1865 posts
cj13609517288
#36 Mar 13, 2025, 2:28 AM • 1 Y
Y by peace09
theres no way this worked

We claim that $N$, the midpoint of $AH$, is exactly the orthocenter of triangle $PAM$. Indeed, it lies on $AH$, and also $MNAO$ is a parallelogram so $MN\perp AP$. Now if $PN\cap AM=X$ and $R$ is the $A$-Humpty point, then $X$ is the midpoint of $AR$. Therefore, it suffices to prove that $QX$ is also perpendicular to $AM$.

Note that $Q$ is the radical center of $(BFEC)$, $(AFE)$, and the point circle at $A$. Therefore, the foot of the perpendicular from $Q$ to $AM$ should have equal power to the point circle at $A$ and $(BFEC)$. Call that point $Y$. Then
\[AY^2=YM^2-MC^2\Longrightarrow (YM-YA)(YM+YA)=MC^2\Longrightarrow YM-YA=RM.\]Therefore, $Y$ is the midpoint of $AR$, so $Y=X$, as desired. $\blacksquare$
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joshualiu315
2513 posts
joshualiu315
#37 Mar 15, 2025, 12:46 AM
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Let $\omega$ be the circle at $A$ with radius $0$ and let $M$ be the midpoint of $\overline{BC}$. It is obvious that $M$ is the center of $(BFEC)$.

Note that $PA^2 = PB \cdot PC$ from Power of a Point on $(ABC)$, which means $P$ lies on the radical axis of $\omega$ and $(BFEC)$. Moreover, some angle chasing yields

\[\angle QAE = \angle ECB = \angle EFA,\]
so $\triangle QAE \sim \triangle QFA$. This implies $QA^2 = QE \cdot QF$, so $Q$ also lies on the radical axis of $\omega$ and $(BFEC)$. Hence, the radical axis is $\overline{PQ}$, and it is perpendicular to the line connecting the centers of the circles, which is $\overline{AM}$. $\blacksquare$
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