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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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0 replies
jlacosta
Apr 2, 2025
0 replies
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Sum of squared areas of polyhedron's faces...
Miquel-point   0
a minute ago
Source: KoMaL B. 5453
The faces of a convex polyhedron are quadrilaterals $ABCD$, $ABFE$, $CDHG$, $ADHE$ and $EFGH$ according to the diagram. The edges from points $A$ and $G$, respectively are pairwise perpendicular. Prove that \[[ABCD]^2+[ABFE]^2+[ADHE]^2=[BCGF]^2+[CDHG]^2+[EFGH]^2,\]where $[XYZW]$ denotes the area of quadrilateral $XYZW$.
0 replies
Miquel-point
a minute ago
0 replies
J
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Beatty sequences of continued fractions
Miquel-point   0
4 minutes ago
Source: KoMaL A. 903
Let the irrational number
\[\alpha =1-\cfrac{1}{2a_1-\cfrac{1}{2a_2-\cfrac{1}{2a_3-\cdots}}}\]where coefficients $a_1, a_2, \ldots$ are positive integers, infinitely many of which are greater than $1$. Prove that for every positive integer $N$ at least half of the numbers $\lfloor \alpha\rfloor, \lfloor 2\alpha\rfloor, \ldots, \lfloor N\alpha\rfloor$ are even.

Proposed by Géza Kós, Budapest
0 replies
Miquel-point
4 minutes ago
0 replies
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Turbo's en route to visit each cell of the board
Lukaluce   11
N 6 minutes ago by Davud29_09
Source: EGMO 2025 P5
Let $n > 1$ be an integer. In a configuration of an $n \times n$ board, each of the $n^2$ cells contains an arrow, either pointing up, down, left, or right. Given a starting configuration, Turbo the snail starts in one of the cells of the board and travels from cell to cell. In each move, Turbo moves one square unit in the direction indicated by the arrow in her cell (possibly leaving the board). After each move, the arrows in all of the cells rotate $90^{\circ}$ counterclockwise. We call a cell good if, starting from that cell, Turbo visits each cell of the board exactly once, without leaving the board, and returns to her initial cell at the end. Determine, in terms of $n$, the maximum number of good cells over all possible starting configurations.

Proposed by Melek Güngör, Turkey
11 replies
Lukaluce
Today at 11:01 AM
Davud29_09
6 minutes ago
J
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Counting the jumps of Luca, the lazy flea
Miquel-point   0
10 minutes ago
Source: KoMaL A. 904
Let $n$ be a given positive integer. Luca, the lazy flea sits on one of the vertices of a regular $2n$-gon. For each jump, Luca picks an axis of symmetry of the polygon, and reflects herself on the chosen axis of symmetry. Let $P(n)$ denote the number of different ways Luca can make $2n$ jumps such that she returns to her original position in the end, and does not pick the same axis twice. (It is possible that Luca's jump does not change her position, however, it still counts as a jump.)
a) Find the value of $P(n)$ if $n$ is odd.
b) Prove that if $n$ is even, then
\[P(n)=(n-1)!\cdot n!\cdot \sum_{d\mid n}\left(\varphi\left(\frac{n}d\right)\binom{2d}{d}\right).\]
Proposed by Péter Csikvári and Kartal Nagy, Budapest
0 replies
Miquel-point
10 minutes ago
0 replies
J
No more topics!
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O, H, D', E' concylic if and only if A,D',E' are collinear
WakeUp   4
N Dec 17, 2013 by mihai miculita
Source: Hong Kong National Olympiad 2013 Problem 3
Let $ABC$ be a triangle with $CA>BC>AB$. Let $O$ and $H$ be the circumcentre and orthocentre of triangle $ABC$ respectively. Denote by $D$ and $E$ the midpoints of the arcs $AB$ and $AC$ of the circumcircle of triangle $ABC$ not containing the opposite vertices. Let $D'$ be the reflection of $D$ about $AB$ and $E'$ the reflection of $E$ about $AC$. Prove that $O,H,D',E'$ are concylic if and only if $A,D',E'$ are collinear.
4 replies
WakeUp
Dec 16, 2013
mihai miculita
Dec 17, 2013
J
O, H, D', E' concylic if and only if A,D',E' are collinear
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Reveal topic tags
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geometry unsolved
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Source: Hong Kong National Olympiad 2013 Problem 3
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WakeUp
1347 posts
WakeUp
#1 Dec 16, 2013, 4:32 PM • 2 Y
Y by Adventure10, Mango247
Let $ABC$ be a triangle with $CA>BC>AB$. Let $O$ and $H$ be the circumcentre and orthocentre of triangle $ABC$ respectively. Denote by $D$ and $E$ the midpoints of the arcs $AB$ and $AC$ of the circumcircle of triangle $ABC$ not containing the opposite vertices. Let $D'$ be the reflection of $D$ about $AB$ and $E'$ the reflection of $E$ about $AC$. Prove that $O,H,D',E'$ are concylic if and only if $A,D',E'$ are collinear.
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sicilianfan
944 posts
sicilianfan
#2 Dec 16, 2013, 5:20 PM • 1 Y
Y by Adventure10
We use complex numbers. WLOG, assume that the circumcircle of $\triangle ABC$ is the unit circle and that $a=1$. Then note that since $DM \perp AB$ where $m=\frac{1+b}{2}$, we must have \[\frac{2d-b-1}{2(b-1)}=-\frac{2/d-1/b-1}{2(1/b-1)} \implies d=\sqrt{b}\] Now it is well known that the reflection of a point $z$ over a chord $AB$ on the unit circle is $a+b-ab\bar z$. Thus $d'=1+b-b\sqrt{b}$. Similarly, $e'=1+c-c\sqrt{c}$. To make computations easier, we can let $b=b_1^2$ and $c=c_1^2$ so then $d'=1+b_1^2-b_1^3$ and $e'=1+c_1^2-c_1^3$. Now all that remains is to bash out the conditions for collinearity and concyclity which get slightly ugly, but are still very manageable in the time limit.

I will edit in the full solution when I find time.
This post has been edited 2 times. Last edited by sicilianfan, Dec 22, 2013, 8:54 PM
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MMEEvN
252 posts
MMEEvN
#3 Dec 16, 2013, 6:05 PM • 2 Y
Y by Adventure10, Mango247
First by simple angle chasing we can observe that both $AD'HB$ and $AHE'C$ are con-cyclic
$\angle D'HE'=\angle AHE'-\angle AHD'=(180-\angle ACE')-\angle ABD' =180 -\frac{(B+C)}{2}$
.If $A,D',E'$ are collinear,
$\angle BAD'+\angle CAD'=A \Rightarrow \frac{(B+C)}{2}=A$ .From easy angle chase $D'OE= 180-A \Rightarrow D'HE'O$ are concyclic .
If $H,D',E' ,O$ are cocncyclic.$\angle D'HE=\angle D'OE \Rightarrow \frac{(B+C)}{2}=A \Rightarrow \angle BAD'+\angle CAE'=A$
Done!
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SayanRoychowdhuri
203 posts
SayanRoychowdhuri
#4 Dec 16, 2013, 6:14 PM • 1 Y
Y by Adventure10
As $ AC>AB $ we arrange the following lines up to down $ BN,BE,CD,CM $ w.r.t $ O $ the circumcenter of $ \triangle ABC $ ,where $ M,N $ are intersections of circumcircle with $ CH,BH $ respectievly, due to this order clearly we have $ BE=CD\Leftrightarrow\angle BNE=\angle DMC $ and clearly we have $ HMDD' $ and $ HE'EN $ are isoscleses trapizoids, hence we have $ A,D',D $ are coliner$ \Leftrightarrow CE\parallel BD\Leftrightarrow BE=CD\Leftrightarrow \angle BNE=\angle DMC $ or $ \angle HE'O=\angle DD'H\Leftrightarrow $ $ D',H,E',O $ are concyclic, done!
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mihai miculita
666 posts
mihai miculita
#5 Dec 17, 2013, 4:45 PM • 2 Y
Y by Adventure10, Mango247
NOTE: $A=\dfrac{B+C}{2}\Leftrightarrow 2.A=B+C\Leftrightarrow 3.A=A+B+C=180^0\Leftrightarrow \boxed{A=60^0}.$
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