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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Wednesday at 3:18 PM
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
Wednesday at 3:18 PM
0 replies
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Bashing??
John_Mgr   0
6 minutes ago
I have learned little about what bashing mean as i am planning to start geo, feels like its less effort required and doesnt need much knowledge about the synthetic solutions?
what do you guys recommend ? also state the major difference of them... especially of bashing pros and cons..
0 replies
1 viewing
John_Mgr
6 minutes ago
0 replies
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1 area = 2025 points
giangtruong13   1
N 11 minutes ago by kiyoras_2001
In a plane give a set $H$ that has 8097 distinct points with area of a triangle that has 3 points belong to $H$ all $ \leq 1$. Prove that there exists a triangle $G$ that has the area $\leq 1 $ contains at least 2025 points that belong to $H$( each of that 2025 points can be inside the triangle or lie on the edge of triangle $G$)X
1 reply
giangtruong13
5 hours ago
kiyoras_2001
11 minutes ago
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A board with crosses that we color
nAalniaOMliO   2
N 14 minutes ago by CHESSR1DER
Source: Belarusian National Olympiad 2025
In some cells of the table $2025 \times 2025$ crosses are placed. A set of 2025 cells we will call balanced if no two of them are in the same row or column. It is known that any balanced set has at least $k$ crosses.
Find the minimal $k$ for which it is always possible to color crosses in two colors such that any balanced set has crosses of both colors.
2 replies
nAalniaOMliO
Mar 28, 2025
CHESSR1DER
14 minutes ago
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Geometry Finale: Incircles and concurrency
lminsl   173
N 21 minutes ago by Parsia--
Source: IMO 2019 Problem 6
Let $I$ be the incentre of acute triangle $ABC$ with $AB\neq AC$. The incircle $\omega$ of $ABC$ is tangent to sides $BC, CA$, and $AB$ at $D, E,$ and $F$, respectively. The line through $D$ perpendicular to $EF$ meets $\omega$ at $R$. Line $AR$ meets $\omega$ again at $P$. The circumcircles of triangle $PCE$ and $PBF$ meet again at $Q$.

Prove that lines $DI$ and $PQ$ meet on the line through $A$ perpendicular to $AI$.

Proposed by Anant Mudgal, India
173 replies
lminsl
Jul 17, 2019
Parsia--
21 minutes ago
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No more topics!
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Menelaus and Length Bashing
rkm0959   2
N Oct 27, 2016 by Ferid.---.
Source: Korean National Junior Olympiad Number 7
In a parallelogram $\Box ABCD$ $(AB < BC)$
The incircle of $\triangle ABC$ meets $\overline {BC}$ and $\overline {CA}$ at $P, Q$.
The incircle of $\triangle ACD$ and $\overline {CD}$ meets at $R$.
Let $S$ = $PQ$ $\cap$ $AD$
$U$ = $AR$ $\cap$ $CS$
$T$, a point on $\overline {BC}$ such that $\overline {AB} = \overline {BT}$

Prove that $AT, BU, PQ$ are concurrent
2 replies
rkm0959
Nov 2, 2014
Ferid.---.
Oct 27, 2016
J
Menelaus and Length Bashing
G H J
Reveal topic tags
geometry
parallelogram
incenter
rhombus
projective geometry
geometry unsolved
L
G H BBookmark kLocked kLocked NReply
Source: Korean National Junior Olympiad Number 7
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rkm0959
1721 posts
rkm0959
#1 Nov 2, 2014, 9:28 AM • 2 Y
Y by Adventure10, Mango247
In a parallelogram $\Box ABCD$ $(AB < BC)$
The incircle of $\triangle ABC$ meets $\overline {BC}$ and $\overline {CA}$ at $P, Q$.
The incircle of $\triangle ACD$ and $\overline {CD}$ meets at $R$.
Let $S$ = $PQ$ $\cap$ $AD$
$U$ = $AR$ $\cap$ $CS$
$T$, a point on $\overline {BC}$ such that $\overline {AB} = \overline {BT}$

Prove that $AT, BU, PQ$ are concurrent
This post has been edited 1 time. Last edited by rkm0959, Jun 7, 2015, 2:51 AM
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TelvCohl
2312 posts
TelvCohl
#2 Nov 2, 2014, 2:05 PM • 1 Y
Y by Adventure10
My solution:

Let $ X=AT \cap PQ $ .
Let $ I $ be the incenter of $ \triangle ABC $ .
Let $ L_S $ be a line passing through $ S $ and parallel to $ AB $ .
Let $ L_R $ be a line passing through $ R $ and parallel to $ BC $ .
Let $ S'=L_S \cap BC, R'=L_R \cap AB, K=L_S \cap L_R $ .
Let $ Y_{\infty} $ be the infinity point with direction $ CD $ .
Let $ Z_{\infty} $ be the infinity point with direction $ AD $ .

Since it's well known that $ B, I, X $ are collinear ,
so it is suffices to prove $ B, I, U $ are collinear .
Since $ KR'=AS=AQ=CR=KS' $ ,
so we get $ KS'BR' $ is a rhombus and $ B, I, K $ are collinear. ... $ (1) $
From Pappus theorem (for $ \{ S,A, Z_{\infty} \} $ and $ \{ R, C, Y_{\infty} \} $ ) we get $ B, K, U $ are collinear. ... $ (2) $
From $ (1) $ and $ (2) $ we get $ B, I, U $ are collinear .

Q.E.D
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Ferid.---.
1008 posts
Ferid.---.
#3 Oct 27, 2016, 4:26 PM • 2 Y
Y by Elcin_bayramli, Adventure10
Any idea with application Menelaus theorem.?
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