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a My Retirement & New Leadership at AoPS
rrusczyk   1270
N 3 minutes ago by MC24
I write today to announce my retirement as CEO from Art of Problem Solving. When I founded AoPS 22 years ago, I never imagined that we would reach so many students and families, or that we would find so many channels through which we discover, inspire, and train the great problem solvers of the next generation. I am very proud of all we have accomplished and I’m thankful for the many supporters who provided inspiration and encouragement along the way. I'm particularly grateful to all of the wonderful members of the AoPS Community!

I’m delighted to introduce our new leaders - Ben Kornell and Andrew Sutherland. Ben has extensive experience in education and edtech prior to joining AoPS as my successor as CEO, including starting like I did as a classroom teacher. He has a deep understanding of the value of our work because he’s an AoPS parent! Meanwhile, Andrew and I have common roots as founders of education companies; he launched Quizlet at age 15! His journey from founder to MIT to technology and product leader as our Chief Product Officer traces a pathway many of our students will follow in the years to come.

Thank you again for your support for Art of Problem Solving and we look forward to working with millions more wonderful problem solvers in the years to come.

And special thanks to all of the amazing AoPS team members who have helped build AoPS. We’ve come a long way from here:IMAGE
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rrusczyk
Monday at 6:37 PM
MC24
3 minutes ago
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k a March Highlights and 2025 AoPS Online Class Information
jlacosta   0
Mar 2, 2025
March is the month for State MATHCOUNTS competitions! Kudos to everyone who participated in their local chapter competitions and best of luck to all going to State! Join us on March 11th for a Math Jam devoted to our favorite Chapter competition problems! Are you interested in training for MATHCOUNTS? Be sure to check out our AMC 8/MATHCOUNTS Basics and Advanced courses.

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

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0 replies
jlacosta
Mar 2, 2025
0 replies
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divisors on a circle
Valentin Vornicu   45
N 5 minutes ago by Ilikeminecraft
Source: USAMO 2005, problem 1, Zuming Feng
Determine all composite positive integers $n$ for which it is possible to arrange all divisors of $n$ that are greater than 1 in a circle so that no two adjacent divisors are relatively prime.
45 replies
Valentin Vornicu
Apr 21, 2005
Ilikeminecraft
5 minutes ago
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2025 Caucasus MO Juniors P7
BR1F1SZ   1
N 12 minutes ago by mpcnotnpc
Source: Caucasus MO
It is known that from segments of lengths $a$, $b$ and $c$, a triangle can be formed. Could it happen that from segments of lengths $$\sqrt{a^2 + \frac{2}{3} bc},\quad \sqrt{b^2 + \frac{2}{3} ca}\quad \text{and} \quad \sqrt{c^2 + \frac{2}{3} ab},$$a right-angled triangle can be formed?
1 reply
BR1F1SZ
an hour ago
mpcnotnpc
12 minutes ago
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Maximum of Incenter-triangle
mpcnotnpc   1
N 29 minutes ago by mpcnotnpc
Triangle $\Delta ABC$ has side lengths $a$, $b$, and $c$. Select a point $P$ inside $\Delta ABC$, and construct the incenters of $\Delta PAB$, $\Delta PBC$, and $\Delta PAC$ and denote them as $I_A$, $I_B$, $I_C$. What is the maximum area of the triangle $\Delta I_A I_B I_C$?
1 reply
mpcnotnpc
Yesterday at 6:24 PM
mpcnotnpc
29 minutes ago
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IMO 2009, Problem 2
orl   141
N 31 minutes ago by mananaban
Source: IMO 2009, Problem 2
Let $ ABC$ be a triangle with circumcentre $ O$. The points $ P$ and $ Q$ are interior points of the sides $ CA$ and $ AB$ respectively. Let $ K,L$ and $ M$ be the midpoints of the segments $ BP,CQ$ and $ PQ$. respectively, and let $ \Gamma$ be the circle passing through $ K,L$ and $ M$. Suppose that the line $ PQ$ is tangent to the circle $ \Gamma$. Prove that $ OP = OQ.$

Proposed by Sergei Berlov, Russia
141 replies
orl
Jul 15, 2009
mananaban
31 minutes ago
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functions false or true
Math2030   2
N 5 hours ago by SomeonecoolLovesMaths
find all functions f: \mathbb{R} \to \mathbb{R} that satisfy the functional equation:


f(x^2 f(x) + f(y)) = (f(x))^3 + f(y), \quad \forall x, y \in \mathbb{R}
2 replies
Math2030
Yesterday at 3:05 PM
SomeonecoolLovesMaths
5 hours ago
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3D Geometry Problem
ReticulatedPython   0
6 hours ago
Three mutually tangent non-degenerate spheres rest on a plane. Let their centers be $A, B$, and $C$. The spheres with centers $A, B$, and $C$ touch the plane at $P, Q$, and $R$, respectively. Prove that $$\frac{1}{AP}+\frac{1}{BQ}+\frac{1}{CR}+PQ+RQ+PR \ge 6\sqrt{2}$$
0 replies
ReticulatedPython
6 hours ago
0 replies
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Ask mininum
TangenT-maTh-   3
N Yesterday at 4:10 PM by rchokler
Find the mininum value of function$f(x)=\cos^2 x-4\cos x-2\sqrt{3}\sin x$
3 replies
TangenT-maTh-
Mar 13, 2025
rchokler
Yesterday at 4:10 PM
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Problem of set
toanrathay   0
Yesterday at 3:36 PM
A set \( A \subset \mathbb{R} \) is called a $\textit{nice}$ if it satisfies the following conditions:
$i)$ \( A \) contains at least two elements.
$ii)$ For all \( x, y \in A \) with \( x \neq y \), we have \( xy(x+y) \neq 0 \), and among the two numbers \( x+y \) and \( xy \), exactly one is rational.
$iii)$ For all \( x \in A \), \( x^2 \) is irrational.
What is the maximum number of elements that \( A \) can have?


0 replies
toanrathay
Yesterday at 3:36 PM
0 replies
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combinations, probability
Chanome   5
N Yesterday at 3:09 PM by ReticulatedPython
Given a fair \( n \)-sided die with sides \( 1, 2, \dots, n \), consider the following game:

1. Roll the die. If the roll results in \( n \), you win immediately.
2. Otherwise, roll again. However, if the second roll is not greater than the previous roll, you lose.
3. Continue rolling until either:
- You roll \( n \), in which case you win.
- Or, your current roll is not greater than your previous roll, in which case you lose.

For example, when \( n = 4 \):
- Rolls \( 1, 3, 4 \): Win
- Rolls \( 3, 1 \): Lose
- Rolls \( 1, 2, 2 \): Lose
- Rolls \( 2, 4 \): Win

Find a formula to find the probability of winning for any given \( n \).
5 replies
Chanome
Monday at 2:36 PM
ReticulatedPython
Yesterday at 3:09 PM
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a+b+c=3 inequality
JK1603JK   1
N Yesterday at 2:57 PM by giangtruong13
Let a,b,c\ge 0: a+b+c=3 then prove \frac{a+bc}{b^{2}+c^{2}+2}+\frac{b+ca}{c^{2}+a^{2}+2}+\frac{c+ab}{a^{2}+b^{2}+2}\le \frac{3}{2}
When does equality hold?
1 reply
JK1603JK
Yesterday at 2:04 PM
giangtruong13
Yesterday at 2:57 PM
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Inequalities
sqing   31
N Yesterday at 12:55 PM by sqing
Let $ a,b>0 $ and $ \frac{1}{a}+\frac{1}{b}=1. $ Prove that
$$(a^2-a+1)(b^2-b+1) \geq 9$$$$ (a^2-a+b+1)(b^2-b+a+1) \geq 25$$Let $ a,b>0 $ and $ \frac{1}{a}+\frac{1}{b}=\frac{2}{3}. $ Prove that
$$(a+8)(a^2-a+b+2)(b^2-b+5)\geq1331$$$$(a+10)(a^2-a+b+4)(b^2-b+7)\geq2197$$
31 replies
sqing
Mar 10, 2025
sqing
Yesterday at 12:55 PM
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Inequality
MathsII-enjoy   1
N Yesterday at 12:13 PM by sqing
A good inequality problem :coolspeak:
1 reply
MathsII-enjoy
Yesterday at 11:00 AM
sqing
Yesterday at 12:13 PM
J
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an inequality
JK1603JK   1
N Yesterday at 10:18 AM by lbh_qys
Let a,b,c\ge 0: ab+bc+ca>0 then prove \frac{ab+c^2}{a+b}+\frac{bc+a^2}{b+c}+\frac{ca+b^2}{c+a}\ge\frac{2(a^2+b^2+c^2)+ab+bc+ca}{a+b+c}.
1 reply
JK1603JK
Yesterday at 7:56 AM
lbh_qys
Yesterday at 10:18 AM
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Phương Trình Hàm
Doanh   0
Yesterday at 8:34 AM
Find f R-->R :


2^(xy)*f(xy-1)+2^(x+y+1)*f(x)*f(y)=4xy-2
0 replies
Doanh
Yesterday at 8:34 AM
0 replies
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Equilateral Triangle and Euler Line
RetroTurtle   7
N Jan 15, 2025 by TestX01
Let $D$, $E$, and $F$ be points on the perpendicular bisectors of $BC$, $CA$, and $AB$ of triangle $ABC$ such that $DEF$ is equilateral. Show that the center of $DEF$ lies on the Euler line of $ABC$.
7 replies
RetroTurtle
Jul 12, 2024
TestX01
Jan 15, 2025
J
Equilateral Triangle and Euler Line
G H J
Reveal topic tags
geometry
Equilateral Triangle
Fermat Point
Isodynamic points
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G H BBookmark kLocked kLocked NReply
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RetroTurtle
839 posts
RetroTurtle
#1 Jul 12, 2024, 4:06 AM • 4 Y
Y by KevinYang2.71, ehuseyinyigit, Rounak_iitr, EpicBird08
Let $D$, $E$, and $F$ be points on the perpendicular bisectors of $BC$, $CA$, and $AB$ of triangle $ABC$ such that $DEF$ is equilateral. Show that the center of $DEF$ lies on the Euler line of $ABC$.
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qwerty123456asdfgzxcvb
1077 posts
qwerty123456asdfgzxcvb
#2 Jul 12, 2024, 6:27 AM • 4 Y
Y by ehuseyinyigit, RetroTurtle, centslordm, trigadd123
you can reduce this with moving points to "is there a single point on the euler line that's not the circumcenter such that we can construct DEF centered at that point?"

edit: i heard from tapir that napoleons' theorem wins
This post has been edited 1 time. Last edited by qwerty123456asdfgzxcvb, Jul 12, 2024, 11:43 PM
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RetroTurtle
839 posts
RetroTurtle
#4 Jul 20, 2024, 2:24 PM
Y by
Any other solution?
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Luis González
4145 posts
Luis González
#5 Jul 24, 2024, 12:04 AM • 4 Y
Y by YaoAOPS, RetroTurtle, qwerty123456asdfgzxcvb, EpicBird08
Solution 1: $\triangle {ABC}$ and $\triangle DEF$ are orthologic through the circumcenter $O$ of $\triangle {ABC}$ $\Longrightarrow$ perpediculars from $A,B,C$ to $EF,FD,DE$ concur at the second orthology center $T.$ Thus $\angle (TB,TC)=\angle (DF,DE)=120^{\circ}$ and same for the others $\Longrightarrow$ $T$ is a Fermat point of $\triangle {ABC}.$ Hence if $O_A,O_B,O_C$ are the circumcenters of $\triangle TBC,$ $\triangle TCA,$ $\triangle TAB$ (apices of external/internal Fermat triangles of $\triangle {ABC}$), then $\triangle O_AO_BO_C$ is equilateral with center the centroid $G$ of $\triangle {ABC}$ (well-known) and it's homothetic to $\triangle DEF$ through $O$ $\Longrightarrow$ center of $\triangle DEF$ lies on $OG.$

Solution 2 (Overkill): Let $O$ be the circumcenter of $\triangle {ABC}.$ Perpendiculars to $OD,OE,OF$ at $D,E,F$ bound a triangle $\triangle {XYZ}$ $\Longrightarrow$ pedal triangle of $O$ WRT $\triangle XYZ$ is equilateral $\Longrightarrow$ $O$ is an isodynamic point of $\triangle XYZ$ $\Longrightarrow$ center $U$ of $\triangle DEF$ is the midpoint of $OT$ (being $T$ the isogonal conjugate of $O$ WRT $\triangle XYZ$). Now it's well-known that $OT$ is parallel to Euler line of $\triangle XYZ$ (see for example Fermat points and Euler line and elsewhere). Since $\triangle XYZ$ is clearly homothetic to $\triangle ABC,$ then it follows that $U$ is on Euler line of $\triangle {ABC}.$
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huoxy1623
42 posts
huoxy1623
#6 Jul 24, 2024, 3:58 PM • 1 Y
Y by qwerty123456asdfgzxcvb
Just notice that DEF and pedal triangle of 1st(2nd) isodynamic point are homothetic :)
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TestX01
330 posts
TestX01
#7 Jan 15, 2025, 3:05 AM
Y by
mmp tunnel vision

We will solve this with reference to the medial triangle: that $DEF$ are on the altitudes of a triangle $ABC$. Note the Euler line is invariant as a homothety at $G$ swaps the two triangles.

Now, for any equilateral triangle that works, we can homothety it at $H$ so one vertex coincides with the reference triangle.

Let us MMP. Suppose our equilateral triangle is $AEF$, and our reference triangle $ABC$. Fix $AEF$. We will move $H$ on a fixed line through $F$.

https://i.imgur.com/b88FlyP.png

Let the line be $\ell$. Then, we get $B$ by intersecting the perpendicular to $\ell$ through $A$ with $EH$. Similarly, $C$ is the intersection of the perpendicular to $EH$ through $A$ with $\ell$.

Now, the centroid of $ABC$ is the dilation of the midpoint of $BC$ by $\frac{2}{3}$. Let us check degrees. If $H$ moves linearly, then $B$ and $C$ move linearly too.

I'm too lazy to show that the midpoint is linear, so I assume that it has degree $2$. Now, $G$ (centroid) is degree $2$ too. Note the centre of $DEF$ is obviously fixed, $H$ is linearly, and $GH$ is euler line so we check $4$ cases.

Consider $H$ as the point $AEHF$ is a kite, this works lol because symmetry.

Consider $H$ as $F$. https://i.imgur.com/vIMq6C7.png

We'll still show that the result is true, just using $O$, circumcentre of $ABC$ to prove euler line instead out of convenience.

Let $O'$ be circumcentre of $AEF$, then, $\angle AFO'=30^\circ$. Now, from $\angle BFA=120^\circ$ by our assumption, we have $\angle C=60^\circ$ hence $\angle BOA=120^\circ$. Thus $BFOA$ is cyclic and $\angle AFO=\angle ABO=30^\circ$, hence $F=H, O,O'$ are collinear.

Now, take $H=AE\cap \ell$. This works because now, as $FO'\perp HA$, and we easily check that $\angle HAC$ is right, dilate $FO'$ to $AC$. Note that centroid and circumcentre coincide on equilateral triangle, so the image of $O'$ divides $AC$ in two to one split, but this is precisely where the centroid of $ABC$ is, noting $B$ is sent to $A$. (use the ratio definition again)

Finally, send $H$ to $\infty_\ell$. $C$ is now the foot of $A$ onto $\ell$, and $B$ is the foot of $A$ onto $E\infty_\ell$. It suffices to show that the centroid of $ABC$ is the foot of $O'$ onto the perpendicular to $\ell$ through $A$. Let us project these ratios through $\infty_\ell$, so equivalently, if $C'=AE\cap \ell$, and $O_1$ is $\infty_\ell O'\cap AE$, then we want $O_1$ to be the centroid of $AEC'$
https://i.imgur.com/RvEvgbO.png
Using vector definition of centroid, we just need $AO_1=\frac{AE+AC'}{3}$. But construct $A'$ as reflection of $A$ over $EF$, and $O_2$ as the intersection of $\infty_\ell$ with $AE$. One easily checks $AA'=3AO'$, and hence $AO_2=3AO_1$. but by parallelograms, as $A'F\parallel AE$, and $FC'\parallel A'O_2$, $O_2C'=A'F$. Hence, $3AO_1=AO_2=C'O_2+AC'=A'F+AC'=AE+AC'$.

Thus, we have checked our $(1+2+0)+1$ cases, and we conclude our mmp and the problem is true for every $H$!
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TestX01
330 posts
TestX01
#8 Jan 15, 2025, 3:58 AM
Y by
https://www.desmos.com/calculator/jqqv1abttq

We coord bash with the above setup, using the orthocentric phrasing as I have done in my previous phrasing. When we wish to show the concurrence, then dilate by $3$. Now, we want the following points collinear:
\[\left(\frac{k-\sqrt{3}}{k+\frac{1}{c}}-\frac{c+\sqrt{3}}{c+\frac{1}{k}},\frac{2\sqrt{3}+c-k}{kc+1}\right)\quad \left(\frac{3k+3c}{k-c},\frac{6ck}{k-c}+3\sqrt{3}\right)\quad \left(0,2\sqrt{3}\right)\]This is equivalent to
\[\frac{\frac{6ck}{k-c}+\sqrt{3}}{\frac{3k+3c}{k-c}}=\frac{\frac{2\sqrt{3}+c-k}{kc+1}-2\sqrt{3}}{\frac{k-\sqrt{3}}{k+\frac{1}{c}}-\frac{c+\sqrt{3}}{c+\frac{1}{k}}}\]Simplifying,
\[\frac{6ck+\sqrt{3}\left(k-c\right)}{3k+3c}=\frac{\left(\frac{2\sqrt{3}+c-k}{kc+1}-2\sqrt{3}\right)}{\frac{ck-\sqrt{3}c-ck-\sqrt{3}k}{ck+1}}\]Or
\[\frac{6ck+\sqrt{3}\left(k-c\right)}{3k+3c}=-\frac{2\sqrt{3}+c-k-2\sqrt{3}ck-2\sqrt{3}}{\sqrt{3}\left(k+c\right)}\]Rearranging
\[6ck+\sqrt{3}\left(k-c\right)=-\sqrt{3}\left(c-k-2\sqrt{3}ck\right)\]Which is true upon expansion.

Hence we are done.
This post has been edited 1 time. Last edited by TestX01, Jan 15, 2025, 3:59 AM
Reason: link to desmos
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TestX01
330 posts
TestX01
#9 Jan 15, 2025, 4:20 AM
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Let $ABC$ be a triangle with incentre $I$, and $D,E,F$ be an equilateral triangle on the angle bisectors of $ABC$. Prove the centre of $DEF$ is on the $OI$ line ($O$ is circumcentre)

As I have shown above, the same is true for altitudes, where the centre lies on $OH$ line. What other triangle centers satisfy a similar property?

Also, for my first solution, we reduce the degree of $G$ by just adding the linear terms individually to be linear ;)
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