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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
Spring is in full swing and summer is right around the corner, what are your plans? At AoPS Online our schedule has new classes starting now through July, so be sure to keep your skills sharp and be prepared for the Fall school year! Check out the schedule of upcoming classes below.

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0 replies
jlacosta
Apr 2, 2025
0 replies
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2011-gon
3333   25
N 25 minutes ago by Marcus_Zhang
Source: All-Russian 2011
A convex 2011-gon is drawn on the board. Peter keeps drawing its diagonals in such a way, that each newly drawn diagonal intersected no more than one of the already drawn diagonals. What is the greatest number of diagonals that Peter can draw?
25 replies
3333
May 17, 2011
Marcus_Zhang
25 minutes ago
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Navid FE on R+
Assassino9931   0
40 minutes ago
Source: Bulgaria Balkan MO TST 2025
Determine all functions $f: \mathbb{R}^{+} \to \mathbb{R}^{+}$ such that
\[ f(x)f\left(x + 4f(y)\right) = xf\left(x + 3y\right) + f(x)f(y) \]for any positive real numbers $x,y$.
0 replies
Assassino9931
40 minutes ago
0 replies
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Combinatorics on progressions
Assassino9931   0
42 minutes ago
Source: Bulgaria Balkan MO TST 2025
Let \( p > 1 \) and \( q > 1 \) be coprime integers. Call a set $a_1 < a_2 < \cdots < a_{p+q}$ balanced if the numbers \( a_1, a_2, \ldots, a_p \) form an arithmetic progression with difference \( q \), and the numbers \( a_p, a_{p+1}, \ldots, a_{p+q} \) form an arithmetic progression with difference \( p \).

In terms of $p$ and $q$, determine the maximum size of a collection of balanced sets such that every two of them have a non-empty intersection.
0 replies
Assassino9931
42 minutes ago
0 replies
J
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Linear recurrence fits with factorial finitely often
Assassino9931   0
an hour ago
Source: Bulgaria Balkan MO TST 2025
Let $k\geq 3$ be an integer. The sequence $(a_n)_{n\geq 1}$ is defined via $a_1 = 1$, $a_2 = k$ and
\[ a_{n+2} = ka_{n+1} + a_n \]for any positive integer $n$. Prove that there are finitely many pairs $(m, \ell)$ of positive integers such that $a_m = \ell!$.
0 replies
Assassino9931
an hour ago
0 replies
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No more topics!
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easy problem!
MRF2017   4
N Mar 22, 2016 by mjuk
Source: Kazakhstan national olympiad 2016 Final Round,grade 11,P4
In isosceles triangle $ABC$($CA=CB$),$CH$ is altitude and $M$ is midpoint of $BH$.Let $K$ be the foot of the perpendicular from $H$ to $AC$ and $L=BK \cap CM$ .Let the perpendicular drawn from $B$ to $BC$ intersects with $HL$ at $N$.Prove that $\angle ACB=2 \angle BCN$.(M. Kunhozhyn)
4 replies
MRF2017
Mar 22, 2016
mjuk
Mar 22, 2016
J
easy problem!
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Reveal topic tags
geometry proposed
geometry
altitude
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G H BBookmark kLocked kLocked NReply
Source: Kazakhstan national olympiad 2016 Final Round,grade 11,P4
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MRF2017
237 posts
MRF2017
#1 Mar 22, 2016, 10:43 AM • 2 Y
Y by Adventure10, Mango247
In isosceles triangle $ABC$($CA=CB$),$CH$ is altitude and $M$ is midpoint of $BH$.Let $K$ be the foot of the perpendicular from $H$ to $AC$ and $L=BK \cap CM$ .Let the perpendicular drawn from $B$ to $BC$ intersects with $HL$ at $N$.Prove that $\angle ACB=2 \angle BCN$.(M. Kunhozhyn)
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george_54
1585 posts
george_54
#2 Mar 22, 2016, 5:56 PM • 2 Y
Y by Adventure10, Mango247
It suffices to show that $CM \bot HN$. Click to reveal hidden text
Attachments:
This post has been edited 1 time. Last edited by george_54, Mar 22, 2016, 5:57 PM
Reason: figure
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TacH
64 posts
TacH
#3 Mar 22, 2016, 6:29 PM • 1 Y
Y by Adventure10
Using George_54 figure , easy to see that $AB$ is tangent to circumcircle of $\triangle{CKH}$ so let the this circle cut $CM$ again at $L'$
we have $ML'$ x $MC = MH^2 = MB^2$ so $\angle{MHL'} = \angle{HCL'}$ and $\angle{MBL'} = \angle{L'CB}$
thus we get $\angle{HL'B} = 180-w$
but since $\angle{KL'H} = w$ we must have $K,L',B$ collinear so $L' = L$
thus we get $\angle{CLH} = 90$ so $C,N,B,L$ is cyclic , so $\angle{ACB} = 2\angle{KCH} = 2\angle{KLH}= 2\angle{BCN} $
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halloffame
11 posts
halloffame
#4 Mar 22, 2016, 6:53 PM • 2 Y
Y by Adventure10, Mango247
It is well know that there is a unique angle $\phi$ such that $\frac{sin\phi}{sin(\alpha-\phi)}=k$ for some constant $k$ and $\alpha$.
Now note that $\triangle CHK$ is similar to $\triangle CBH$ so $\frac{BC}{CH}=\frac{BH}{KH}$ and when we apply sine theorems to $\triangle BCH$ and $\triangle BKH$ (and also the sine theorem for 2 angles built by median in $\triangle BCH$) we get that $\angle HKB=\angle HCM=\angle HCL$ so $CKHL$ is cyclic so $\angle CLH=90$ so $CLBN$ is cyclic. Now let $KH$ and $BN$ intersect at $X$. We have that $CKXB$ is cyclic so $\angle HXN=180-\angle ACB$. Also note that $HX$ and $BX$ are tangents to the circumcircle of $\triangle CHB$ so $CX$ is symmedian in that triangle so we get $ \angle HCX=\angle MCB=\angle XNH$ so $XHCN$ is also cyclic so $\angle HCN=180-\angle HXN=\angle ACB$ so we have $\angle BCN=\angle ACH$ so we are finished.
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mjuk
196 posts
mjuk
#5 Mar 22, 2016, 7:24 PM • 2 Y
Y by Adventure10, Mango247
Obviously $\bigtriangleup HAK\sim \bigtriangleup CBH\rightarrow \frac{HA}{AK}=\frac{BC}{BH}\rightarrow \frac{BA}{AK}=\frac{BC}{BH}$ and $\angle BAK=\angle CBM\rightarrow \bigtriangleup BAK\sim \bigtriangleup CBM$.
$\angle HKL=\angle AHK-\angle ABK=\angle BCH-\angle BCM=\angle HCL\rightarrow$ $HLCK$ is cyclic$\rightarrow \angle CLN=90^{\circ}\rightarrow CLBN$ is cyclic $\rightarrow \angle ACB=2\angle KCH=2\angle KLH=2\angle BLN=2\angle BCN.$
This post has been edited 2 times. Last edited by mjuk, Mar 22, 2016, 7:26 PM
Reason: typo
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