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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
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jlacosta
Apr 2, 2025
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Show that XD and AM meet on Gamma
MathStudent2002   91
N 3 minutes ago by IndexLibrorumProhibitorum
Source: IMO Shortlist 2016, Geometry 2
Let $ABC$ be a triangle with circumcircle $\Gamma$ and incenter $I$ and let $M$ be the midpoint of $\overline{BC}$. The points $D$, $E$, $F$ are selected on sides $\overline{BC}$, $\overline{CA}$, $\overline{AB}$ such that $\overline{ID} \perp \overline{BC}$, $\overline{IE}\perp \overline{AI}$, and $\overline{IF}\perp \overline{AI}$. Suppose that the circumcircle of $\triangle AEF$ intersects $\Gamma$ at a point $X$ other than $A$. Prove that lines $XD$ and $AM$ meet on $\Gamma$.

Proposed by Evan Chen, Taiwan
91 replies
MathStudent2002
Jul 19, 2017
IndexLibrorumProhibitorum
3 minutes ago
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MONT pg 31 example 1.10.40
Jaxman8   2
N 14 minutes ago by nickbaggio
Can somebody explain why it works.
2 replies
Jaxman8
Apr 17, 2025
nickbaggio
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How many non-attacking pawns can be placed on a $n \times n$ chessboard?
DylanN   1
N 15 minutes ago by Dxd7548
Source: 2019 Pan-African Shortlist - C1
A pawn is a chess piece which attacks the two squares diagonally in front if it. What is the maximum number of pawns which can be placed on an $n \times n$ chessboard such that no two pawns attack each other?
1 reply
DylanN
Jan 18, 2021
Dxd7548
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Telescopic Sum
P162008   1
N 43 minutes ago by nabodorbuco2
Compute the value of $\Omega = \sum_{r=1}^{\infty} \frac{14 - 9r - 90r^2 - 36r^3}{7^r r(r + 1)(r + 2)(4r^2 - 1)}$
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Ineq
silouan   2
N Sep 11, 2005 by darij grinberg
Source: Mediterranean MO 2000
Let $P,Q,R,S$ be the midpoints of the sides $BC,CD,DA,AB$ of a convex quadrilateral, respectively. Prove that
\[4(AP^2+BQ^2+CR^2+DS^2)\le 5(AB^2+BC^2+CD^2+DA^2)\]
2 replies
silouan
Aug 26, 2005
darij grinberg
Sep 11, 2005
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Source: Mediterranean MO 2000
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silouan
3952 posts
silouan
#1 Aug 26, 2005, 8:20 PM • 2 Y
Y by Adventure10, Mango247
Let $P,Q,R,S$ be the midpoints of the sides $BC,CD,DA,AB$ of a convex quadrilateral, respectively. Prove that
\[4(AP^2+BQ^2+CR^2+DS^2)\le 5(AB^2+BC^2+CD^2+DA^2)\]
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MysticTerminator
3697 posts
MysticTerminator
#2 Aug 26, 2005, 9:46 PM • 2 Y
Y by Adventure10, Mango247
consider the midpoints $M, N$ of $\overline{AC}, \overline{BD}$. As the distance $\overline{MN} \ge 0$, we have (using vectors), $4(\vec{A} + \vec{C} - \vec{B} - \vec{D})^2 \ge 0 \Rightarrow$ $4\vec{A}^2 + 4\vec{B}^2 + 4\vec{C}^2 + 4\vec{D}^2 + 8\vec{A} \cdot \vec{C} + 8\vec{B} \cdot \vec{D} \ge 8\vec{A} \cdot \vec{B} + 8\vec{B} \cdot \vec{C} + 8\vec{C} \cdot \vec{D} + 8\vec{D} \cdot \vec{A}$ $\Rightarrow 10\vec{A}^2 + 10\vec{B}^2 + 10\vec{C}^2 + 10\vec{D}^2 - 10\vec{A} \cdot \vec{B} - 10\vec{B} \cdot \vec{C} - 10\vec{C} \cdot \vec{D} - 10\vec{D} \cdot \vec{A} \ge 6\vec{A}^2 + 6\vec{B}^2 + 6\vec{C}^2 + 6\vec{D}^2 - 2\vec{A} \cdot \vec{B} - 2\vec{B} \cdot \vec{C} - 2\vec{C} \cdot \vec{D} - 2\vec{D} \cdot \vec{A} - 8\vec{A} \cdot \vec{C} - 8\vec{B} \cdot \vec{D}$ $\Rightarrow 5(\overline{AB}^2 + \overline{BC}^2 + \overline{CD}^2 + \overline{DA}^2) \ge 4(\overline{AP}^2 + \overline{BQ}^2 + \overline{CR}^2 + \overline{DS}^2)$
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darij grinberg
6555 posts
darij grinberg
#3 Sep 11, 2005, 12:12 PM • 2 Y
Y by Adventure10, Mango247
Problem. Let A, B, C, D be four arbitrary points in the plane, and let P, Q, R, S be the midpoints of the segments BC, CD, DA, AB. Prove that

$4\left(AP^2+BQ^2+CR^2+DS^2\right)\leq 5\left(AB^2+BC^2+CD^2+DA^2\right)$.

Solution. Here is a different way to write MysticTerminator's solution, without explicitely using vectors but with a formula for the length of a median of a triangle:

Lemma 1. If $m_a$ is the length of the median from the vertex A of a triangle ABC, then $4m_a^2=2b^2+2c^2-a^2$.

Applying Lemma 1 to the triangle ABC, whose median from the vertex A is the segment AP (in fact, P is the midpoint of the side BC of this triangle), we get

$4\cdot AP^2=2\cdot AC^2+2\cdot AB^2-BC^2$.

Similarly,

$4\cdot BQ^2=2\cdot BD^2+2\cdot BC^2-CD^2$;
$4\cdot CR^2=2\cdot AC^2+2\cdot CD^2-DA^2$;
$4\cdot DS^2=2\cdot BD^2+2\cdot DA^2-AB^2$.

Adding these four equations yields

$4\cdot AP^2+4\cdot BQ^2+4\cdot CR^2+4\cdot DS^2=\left(2\cdot AC^2+2\cdot AB^2-BC^2\right)$
$+\left(2\cdot BD^2+2\cdot BC^2-CD^2\right)+\left(2\cdot AC^2+2\cdot CD^2-DA^2\right)+\left(2\cdot BD^2+2\cdot DA^2-AB^2\right)$.

This simplifies to

$4\left(AP^2+BQ^2+CR^2+DS^2\right)=4\cdot\left(AC^2+BD^2\right)+\left(AB^2+BC^2+CD^2+DA^2\right)$.

Now, let M and N be the midpoints of the segments AC and BD, respectively. Then, the segment MN is the median from the vertex N of triangle ANC (since M is the midpoint of the segment AC); thus, by Lemma 1, we have

$4\cdot MN^2=2\cdot AN^2+2\cdot CN^2-AC^2$.

On the other hand, the segment AN is the median from the vertex A of triangle ABD (since N is the midpoint of the segment BD); hence, Lemma 1 yields $4\cdot AN^2=2\cdot AB^2+2\cdot DA^2-BD^2$. Similarly, $4\cdot CN^2=2\cdot BC^2+2\cdot CD^2-BD^2$. Adding these two equations, we get

$4\cdot AN^2+4\cdot CN^2=\left(2\cdot AB^2+2\cdot DA^2-BD^2\right)+\left(2\cdot BC^2+2\cdot CD^2-BD^2\right)$
$=2\cdot\left(AB^2+BC^2+CD^2+DA^2-BD^2\right)$.

Division by 2 yields $2\cdot AN^2+2\cdot CN^2=AB^2+BC^2+CD^2+DA^2-BD^2$, and thus

$4\cdot MN^2=2\cdot AN^2+2\cdot CN^2-AC^2=AB^2+BC^2+CD^2+DA^2-BD^2-AC^2$
$=\left(AB^2+BC^2+CD^2+DA^2\right)-\left(AC^2+BD^2\right)$.

Since $MN^2\geq 0$, we thus have $\left(AB^2+BC^2+CD^2+DA^2\right)-\left(AC^2+BD^2\right)\geq 0$, so that $AC^2+BD^2\leq AB^2+BC^2+CD^2+DA^2$. Thus,

$4\left(AP^2+BQ^2+CR^2+DS^2\right)=4\cdot\left(AC^2+BD^2\right)+\left(AB^2+BC^2+CD^2+DA^2\right)$
$\leq 4\cdot\left(AB^2+BC^2+CD^2+DA^2\right)+\left(AB^2+BC^2+CD^2+DA^2\right)=5\left(AB^2+BC^2+CD^2+DA^2\right)$,

and the problem is solved.

darij
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