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k a May Highlights and 2025 AoPS Online Class Information
jlacosta   0
May 1, 2025
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0 replies
jlacosta
May 1, 2025
0 replies
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Old problem
kwin   1
N 3 minutes ago by Nguyenhuyen_AG
Let $ a, b, c > 0$ . Prove that:
$$(a^2+b^2)(b^2+c^2)(c^2+a^2)(ab+bc+ca)^2 \ge 8(abc)^2(a^2+b^2+c^2)^2$$
1 reply
kwin
4 hours ago
Nguyenhuyen_AG
3 minutes ago
J
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LCM genius problem from our favorite author
MS_Kekas   1
N 20 minutes ago by Tintarn
Source: Kyiv City MO 2022 Round 2, Problem 8.1
Find all triples $(a, b, c)$ of positive integers for which $a + [a, b] = b + [b, c] = c + [c, a]$.

Here $[a, b]$ denotes the least common multiple of integers $a, b$.

(Proposed by Mykhailo Shtandenko)
1 reply
MS_Kekas
Jan 30, 2022
Tintarn
20 minutes ago
J
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IMO Solution mistake
CHESSR1DER   0
33 minutes ago
Source: Mistake in IMO 1982/1 4th solution
I found a mistake in 4th solution at IMO 1982/1. It gives answer $660$ and $661$. But right answer is only $660$. Should it be reported somewhere in Aops?
0 replies
CHESSR1DER
33 minutes ago
0 replies
J
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All the numbers to be zero after finitely many operations
orl   9
N 2 hours ago by User210790
Source: IMO Shortlist 1989, Problem 19, ILL 64
A natural number is written in each square of an $ m \times n$ chess board. The allowed move is to add an integer $ k$ to each of two adjacent numbers in such a way that non-negative numbers are obtained. (Two squares are adjacent if they have a common side.) Find a necessary and sufficient condition for it to be possible for all the numbers to be zero after finitely many operations.
9 replies
orl
Sep 18, 2008
User210790
2 hours ago
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Inequalities
sqing   8
N 5 hours ago by sqing
Let $a,b,c >2 $ and $ ab+bc+ca \leq 75.$ Show that
$$\frac{1}{a-2}+\frac{1}{b-2}+\frac{1}{c-2}\geq 1$$Let $a,b,c >2 $ and $ \frac{1}{a}+\frac{1}{b}+\frac{1}{c}\geq \frac{6}{7}.$ Show that
$$\frac{1}{a-2}+\frac{1}{b-2}+\frac{1}{c-2}\geq 2$$
8 replies
sqing
May 13, 2025
sqing
5 hours ago
J
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trigonometric functions
VivaanKam   16
N Today at 1:03 AM by Shan3t
Hi could someone explain the basic trigonometric functions to me like sin, cos, tan etc.
Thank you!
16 replies
VivaanKam
Apr 29, 2025
Shan3t
Today at 1:03 AM
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Minimum number of points
Ecrin_eren   2
N Yesterday at 8:32 PM by Shan3t
There are 18 teams in a football league. Each team plays against every other team twice in a season—once at home and once away. A win gives 3 points, a draw gives 1 point, and a loss gives 0 points. One team became the champion by earning more points than every other team. What is the minimum number of points this team could have?

2 replies
Ecrin_eren
Yesterday at 4:09 PM
Shan3t
Yesterday at 8:32 PM
J
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Weird locus problem
Sedro   7
N Yesterday at 8:00 PM by ReticulatedPython
Points $A$ and $B$ are in the coordinate plane such that $AB=2$. Let $\mathcal{H}$ denote the locus of all points $P$ in the coordinate plane satisfying $PA\cdot PB=2$, and let $M$ be the midpoint of $AB$. Points $X$ and $Y$ are on $\mathcal{H}$ such that $\angle XMY = 45^\circ$ and $MX\cdot MY=\sqrt{2}$. The value of $MX^4 + MY^4$ can be expressed in the form $\tfrac{m}{n}$, where $m$ and $n$ are relatively prime positive integers. Find $m+n$.
7 replies
Sedro
May 11, 2025
ReticulatedPython
Yesterday at 8:00 PM
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IOQM P23 2024
SomeonecoolLovesMaths   3
N Yesterday at 4:53 PM by lakshya2009
Consider the fourteen numbers, $1^4,2^4,...,14^4$. The smallest natural numebr $n$ such that they leave distinct remainders when divided by $n$ is:
3 replies
SomeonecoolLovesMaths
Sep 8, 2024
lakshya2009
Yesterday at 4:53 PM
J
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Inequalities
sqing   2
N Yesterday at 4:05 PM by MITDragon
Let $ 0\leq x,y,z\leq 2. $ Prove that
$$-48\leq (x-yz)( 3y-zx)(z-xy)\leq 9$$$$-144\leq (3x-yz)(y-zx)(3z-xy)\leq\frac{81}{64}$$$$-144\leq (3x-yz)(2y-zx)(3z-xy)\leq\frac{81}{16}$$
2 replies
sqing
May 9, 2025
MITDragon
Yesterday at 4:05 PM
J
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Pells equation
Entrepreneur   0
Yesterday at 3:56 PM
A Pells Equation is defined as follows $$x^2-1=ky^2.$$Where $x,y$ are positive integers and $k$ is a non-square positive integer. If $(x_n,y_n)$ denotes the n-th set of solution to the equation with $(x_0,y_0)=(1,0).$ Then, prove that $$x_{n+1}x_n-ky_{n+1}y_n=x_1,$$$$x_n\pm y_n\sqrt k=(x_1\pm y_1\sqrt k)^n.$$
0 replies
Entrepreneur
Yesterday at 3:56 PM
0 replies
J
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Incircle concurrency
niwobin   1
N Yesterday at 2:42 PM by niwobin
Triangle ABC with incenter I, incircle is tangent to BC, AC, and AB at D, E and F respectively.
DT is a diameter for the incircle, and AT meets the incircle again at point H.
Let DH and EF intersect at point J. Prove: AJ//BC.
1 reply
niwobin
May 11, 2025
niwobin
Yesterday at 2:42 PM
J
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Inequalities
sqing   3
N Yesterday at 2:29 PM by rachelcassano
Let $ a,b,c>0 $ . Prove that
$$\frac{a+5b}{b+c}+\frac{b+5c}{c+a}+\frac{c+5a}{a+b}\geq 9$$$$ \frac{2a+11b}{b+c}+\frac{2b+11c}{c+a}+\frac{2c+11a}{a+b}\geq \frac{39}{2}$$$$ \frac{25a+147b}{b+c}+\frac{25b+147c}{c+a}+\frac{25c+147a}{a+b} \geq258$$
3 replies
sqing
May 14, 2025
rachelcassano
Yesterday at 2:29 PM
J
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The centroid of ABC lies on ME [2023 Abel, Problem 1b]
Amir Hossein   3
N Yesterday at 1:45 PM by Captainscrubz
In the triangle $ABC$, points $D$ and $E$ lie on the side $BC$, with $CE = BD$. Also, $M$ is the midpoint of $AD$. Show that the centroid of $ABC$ lies on $ME$.
3 replies
Amir Hossein
Mar 12, 2024
Captainscrubz
Yesterday at 1:45 PM
J
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J
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9th grade 2008 Russian Mathematical Olympiad 6th question
Umut Varolgunes   14
N Feb 10, 2019 by MathInfinite
Source: All Russian 2008, Grade 9, Problem 6
The incircle of a triangle $ABC$ touches the side $AB$ and $AC$ at respectively at $X$ and $Y$. Let $K$ be the midpoint of the arc $\widehat{AB}$ on the circumcircle of $ABC$. Assume that $XY$ bisects the segment $AK$. What are the possible measures of angle $BAC$?
14 replies
Umut Varolgunes
May 21, 2008
MathInfinite
Feb 10, 2019
J
9th grade 2008 Russian Mathematical Olympiad 6th question
G H J
Reveal topic tags
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geometry unsolved
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G H BBookmark kLocked kLocked NReply
Source: All Russian 2008, Grade 9, Problem 6
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Umut Varolgunes
279 posts
Umut Varolgunes
#1 May 21, 2008, 9:28 AM • 2 Y
Y by Adventure10, Mango247
The incircle of a triangle $ABC$ touches the side $AB$ and $AC$ at respectively at $X$ and $Y$. Let $K$ be the midpoint of the arc $\widehat{AB}$ on the circumcircle of $ABC$. Assume that $XY$ bisects the segment $AK$. What are the possible measures of angle $BAC$?
This post has been edited 1 time. Last edited by djmathman, Dec 29, 2015, 4:30 AM
Reason: latex stuff
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HTA
339 posts
HTA
#2 May 21, 2008, 11:34 AM • 2 Y
Y by Adventure10, Mango247
sorry , i can't understand how "XY bisects the segment .. " , maybe I misunderstand somehow ?
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hsiljak
1647 posts
hsiljak
#3 May 21, 2008, 11:51 AM • 2 Y
Y by Adventure10, Mango247
HTA wrote:
sorry , i can't understand how "XY bisects the segment .. " , maybe I misunderstand somehow ?
How I understood it: Line which goes through X and Y bisects the segment AK. I guess there is a triangle in which this can be achieved, but I couldn't construct such an example...

(The text of the problem is practically the same as the text on imo.org.yu...)
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Ahiles
374 posts
Ahiles
#4 May 21, 2008, 1:35 PM • 2 Y
Y by Adventure10, Mango247
Where can we find all problems from this year?
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hsiljak
1647 posts
hsiljak
#5 May 21, 2008, 1:38 PM • 2 Y
Y by Adventure10, Mango247
Here you go, Ahiles...

http://www.imomath.com/othercomp/b348f/RusMO08.pdf
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Umut Varolgunes
279 posts
Umut Varolgunes
#6 May 21, 2008, 2:35 PM • 2 Y
Y by Adventure10, Mango247
yup, imo.org.yu is where i got the question. i wonder if there's anyone knows the question from another source.
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hsiljak
1647 posts
hsiljak
#7 May 21, 2008, 3:00 PM • 2 Y
Y by Adventure10, Mango247
Here's another source: http://olympiads.mccme.ru/vmo/34/2.pdf

But the text is same!
Quote:
Вписанная окружность касается сторон AB и AC треуголь-
ника ABC в точках X и Y соответственно. Точка K сере-
дина дуги AB описанной окружности треугольника ABC.
Оказалось, что прямая XY делит отрезок AK пополам. Че-
му может быть равен угол BAC?
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Umut Varolgunes
279 posts
Umut Varolgunes
#8 May 21, 2008, 5:31 PM • 1 Y
Y by Adventure10
Thanks, hsiljak.
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28121941
152 posts
28121941
#9 May 21, 2008, 7:20 PM • 1 Y
Y by Adventure10
XY bisects a segment means that the line XY pass through the half point of the segment.
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Umut Varolgunes
279 posts
Umut Varolgunes
#10 May 22, 2008, 4:55 PM • 2 Y
Y by Adventure10, Mango247
Sorry, there aren't any typos. :blush: I haven't got an elegant solution but with some calculations i solved the question.
Answer
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¬[ƒ(Gabriel)³²¹º]¼
347 posts
¬[ƒ(Gabriel)³²¹º]¼
#11 May 22, 2008, 5:23 PM • 3 Y
Y by Adventure10, Mango247, Mango247
Call D the point where XY meets AK. Then we must have:

$ 2 \overline{AD} = \overline{AK} \ \Longleftrightarrow \ 2 \frac{r \cot {\frac{A}{2}} \cos{\frac{A}{2}}}{\sin{\frac{B}{2}}} = R \sin {\frac{C}{2}} \ \Longleftrightarrow$
$ \Longleftrightarrow \ \frac{r}{R} \cos^2{\frac{A}{2}}= \sin{\frac{A}{2}} \sin{\frac{B}{2}} \sin{\frac{C}{2}} \ \Longleftrightarrow$
$ \Longleftrightarrow \ \cos^2{\frac{A}{2} = \frac{1}{4} \ \Longrightarrow \frac{A}{2} = \{ \frac{\pi}{3}, \frac{2 \pi}{3}, \frac{4 \pi}{3}, \frac{5 \pi}{3} \} \ \Longrightarrow \ A = \frac{2 \pi}{3}}$
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Virgil Nicula
7054 posts
Virgil Nicula
#12 May 22, 2008, 6:24 PM • 2 Y
Y by Adventure10, Mango247
Nice problem !
anonymous1173 wrote:
The incircle of a triangle $ ABC$ touches the side $ [AB]$ , $ [AC]$ at the points $ X$ , $ Y$ respectively. Let $ K$ be the midpoint of the arc $ AB$

in the circumcircle of $ ABC$ . Assume that $ XY$ bisects the segment $ AK$ . Ascertain the possible measures of angle $ \widehat {BAC}$ .
Proof. Denote the midpoint $ T$ of the segment $ [AK]$ , the intersections $ \begin{array}{c} D\in AB\cap CK\\\ S\in XY\cap CK\end{array}$ . If $ T\in XY$ , then prove easily that $ a>b$ , $ a>c$ .

Show easily that $ XD=\frac{(a-b)(p-c)}{a+b}$ . Apply the Menelaus' theorem to the transversals :

$ \left\{\begin{array}{cccccc} \overline {SYT}\mathrm {\ in\ }\triangle\ ACK : & \frac {SK}{SC}\cdot\frac {YC}{YA}\cdot\frac {TA}{TK}=1 & \implies & \frac {SK}{p-a}=\frac {SC}{p-c}=\frac {CK}{a-c} & \implies & SC=\frac {p-c}{a-c}\cdot CK\\\\ \overline {SYX}\mathrm {\ in\ }\triangle\ ACD : & \frac {SD}{SC}\cdot\frac {YC}{YA}\cdot\frac {XA}{XD}=1 & \implies & \frac {SD}{a-b}=\frac {SC}{a+b}=\frac {CD}{2b} & \implies & SC=\frac {a+b}{2b}\cdot CD\end{array}\right\|\implies$

$ \frac {p-c}{a-c}\cdot CK=\frac {a+b}{2b}\cdot CD\implies\frac {p-c}{a-c}\cdot CK\cdot CD=\frac {a+b}{2b}\cdot CD^2$ . From the well-known relations $ \boxed {\begin{array}{c} CK\cdot CD=ab\\\\ CD=\frac {2}{a+b}\cdot\sqrt {abp(p-c)}\end{array}}$

obtain $ \frac {p-c}{a-c}\cdot ab=\frac {a+b}{2b}\cdot \frac {4abp(p-c)}{(a+b)^2}$ $ \implies$ $ b(a+b)=(a-c)(a+b+c)$ $ \implies$ $ a^2=b^2+c^2+bc$ $ \implies$ $ m(\widehat {BAC})=120^{\circ}$ .
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cyshine
236 posts
cyshine
#13 Feb 15, 2009, 6:22 PM • 2 Y
Y by Adventure10, Mango247
Wow, guys, I know the trigonometric solutions are quite short, but this is only an angle-chaser.

I'll just give an outline of the solution (it's all angle chasing).

[geogebra]d985fbfae4112099967f34b883f01a8be04a4de7[/geogebra]

First, let $ L$ be the midpoint of arc $ AC$. Then $ KL$ is parallel to $ XY$. Moreover, $ AX = XE$, $ E$ being the intersection of $ KL$ and $ AB$.

Second, $ KEIB$ is cyclic, so $ \angle IEA = 180^\circ - \angle A$.

Finally, since $ IX$ is both altitude and median of triangle $ AIE$, this triangle is isosceles, so $ \angle EAI = \angle IEA \iff \frac{\angle A}2 = 180^\circ - \angle A\iff \angle A = 120^\circ$.

PS: just an aside: for some reason, the Geogebra command 'incircle' doesn't work in my computer (and a forum search showed this to be the case for some other posters); I redid the picture by constructing the angle bisectors.
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Flakky
130 posts
Flakky
#14 Feb 15, 2009, 9:13 PM • 1 Y
Y by Adventure10
Too much work for nothing!!!
Just observe that $ \triangle AXS \sim \triangle CIB$ ($ S=XY \cap AK$). Hence $ AS=\frac{AX.BC}{CI}$, but $ AS=1/2.KI \Longrightarrow 1/2KI.CI=\frac{AX.BC}{CI}.$ Also we know that $ KI.CI=2Rr \Longrightarrow Rr=a(p-a) \Leftrightarrow 1=4cos^2(\frac{A}{2})$ $ \Longrightarrow A=120^\circ$
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MathInfinite
187 posts
MathInfinite
#15 Feb 10, 2019, 1:44 PM • 2 Y
Y by Adventure10, Mango247
Another synthetic approach.

Let $L$ be the midpoint of $\widehat{AC}$ and let $I$ be incentre of $\Delta ABC$.
By Fact 5, we have $IK = AK$ and $IL = AL$.
So, $KL$ is perpendicular bisector of $AI$. Also $XY$ is perpendicular to $AI$.
Thus $KL \parallel XY$.
Let $AI \cap XY = T$.
It is not difficult to see that $3AT = IT$. So, $\boxed{\angle{BAC} = 120^{\circ}}$ $\blacksquare$
This post has been edited 2 times. Last edited by MathInfinite, Feb 10, 2019, 1:45 PM
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