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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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Centroid Distance Identity in Triangle
zeta1   2
N 5 minutes ago by zeta1
Let M be any point inside triangle ABC, and let G be the centroid of triangle ABC. Prove that:

\[ |MA|^2 + |MB|^2 + |MC|^2 = |GA|^2 + |GB|^2 + |GC|^2 + 3|MG|^2 \]
2 replies
+1 w
zeta1
an hour ago
zeta1
5 minutes ago
J
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Advanced topics in Inequalities
va2010   4
N 6 minutes ago by sqing
So a while ago, I compiled some tricks on inequalities. You are welcome to post solutions below!
4 replies
va2010
Mar 7, 2015
sqing
6 minutes ago
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Inequality while on a trip
giangtruong13   8
N 12 minutes ago by GeoMorocco
Source: Trip
I find this inequality while i was on a trip, it was pretty fun and i have some new experience:
Let $a,b,c \geq -2$ such that: $a^2+b^2+c^2 \leq 8$. Find the maximum: $$A= \sum_{cyc} \frac{1}{16+a^3}$$
8 replies
giangtruong13
Apr 12, 2025
GeoMorocco
12 minutes ago
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Directed edge chromatic numbers over a tournament
v_Enhance   32
N 13 minutes ago by quantam13
Source: USA January TST for 56th IMO, Problem 2
A tournament is a directed graph for which every (unordered) pair of vertices has a single directed edge from one vertex to the other. Let us define a proper directed-edge-coloring to be an assignment of a color to every (directed) edge, so that for every pair of directed edges $\overrightarrow{uv}$ and $\overrightarrow{vw}$, those two edges are in different colors. Note that it is permissible for $\overrightarrow{uv}$ and $\overrightarrow{uw}$ to be the same color. The directed-edge-chromatic-number of a tournament is defined to be the minimum total number of colors that can be used in order to create a proper directed-edge-coloring. For each $n$, determine the minimum directed-edge-chromatic-number over all tournaments on $n$ vertices.

Proposed by Po-Shen Loh
32 replies
v_Enhance
Mar 22, 2015
quantam13
13 minutes ago
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Collinearity in cyclic quadrilateral
davidlam   7
N Oct 29, 2015 by rkm0959
A convex quadrilateral $ABCD$ with $AC \neq BD$ is inscribed in a circle with center $O$. Let $E$ be the intersection of diagonals $AC$ and $BD$. If $P$ is a point inside $ABCD$ such that $\angle PAB+\angle PCB=\angle PBC+\angle PDC=90^\circ$, prove that $O$, $P$ and $E$ are collinear.
7 replies
davidlam
Dec 2, 2006
rkm0959
Oct 29, 2015
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Collinearity in cyclic quadrilateral
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Reveal topic tags
geometry
circumcircle
symmetry
power of a point
radical axis
geometry unsolved
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davidlam
30 posts
davidlam
#1 Dec 2, 2006, 1:05 PM • 2 Y
Y by Adventure10, Mango247
A convex quadrilateral $ABCD$ with $AC \neq BD$ is inscribed in a circle with center $O$. Let $E$ be the intersection of diagonals $AC$ and $BD$. If $P$ is a point inside $ABCD$ such that $\angle PAB+\angle PCB=\angle PBC+\angle PDC=90^\circ$, prove that $O$, $P$ and $E$ are collinear.
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leepakhin
474 posts
leepakhin
#2 Dec 2, 2006, 2:28 PM • 2 Y
Y by Adventure10, Mango247
Let $\Sigma, \Sigma_{1}, \Sigma_{2}$ be respectively the circumcircles of $ABCD, \triangle PBD, \triangle PAC$. Let also $C_{1}, C_{2}$ be the centres of $\Sigma_{1}, \Sigma_{2}$ respectively.

Consider the radical axes of each two of them. Since the radical axis of $\Sigma, \Sigma_{1}$ is $BD$ and that of $\Sigma, \Sigma_{2}$ is $AC$, the radical axis of $\Sigma_{1}, \Sigma_{2}$ must be concurrent with $AC$ and $BD$, i.e. it passes through $E$. Therefore, the radical axis of $\Sigma_{1}, \Sigma_{2}$ is $PE$.

To prove $O$, $P$, $E$ are collinear, it suffices to prove $O$ has the same power with respect to $\Sigma_{1}$ and $\Sigma_{2}$.

Without loss of generality we may let $\angle A$ and $\angle B$ to be not smaller than a right angle. Then point $P$ lies in $\triangle CDE$ and it is outside $\Sigma_{1}$ and $\Sigma_{2}$. By some angle chasing we can prove that $\angle ODC_{1}=90^\circ$, and so the power of $O$ w.r.t $\Sigma_{1}$ is equal to $OC_{1}^{2}-CC_{1}^{2}=OC^{2}$. Similarly, the power of $O$ w.r.t. $\Sigma_{2}$ is also the square of the circumradius of $ABCD$. The result follows.
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Megus
1198 posts
Megus
#3 Dec 2, 2006, 7:26 PM • 2 Y
Y by Adventure10, Mango247
Consider inversion with center $P$ and any power. Then see that our hypothesis implies that $A^{*}B^{*}C^{*}D^{*}$ ($X^{*}$ denotes point $X$ after inversion) is a rectangle. Let $O'$ be center of circumcircle of $A^{*}B^{*}C^{*}D^{*}$. Point $E^{*}$ is the intersection of circumcircles of $PBD$ and $PCA$ and hence lies on line $PO'$ (as $O'$ is the intersection of $A^{*}C^{*}$ and $B^{*}D^{*}$). But well-known fact says that $P,O',O$ are collinear and hence $P,O',O^{*}$ are collinear, so $P,E^{*},O^{*}$ are collinear and hence $P,E,O$ are collinear. :) QED
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modeler
175 posts
modeler
#4 Dec 3, 2006, 1:10 AM • 2 Y
Y by Adventure10, Mango247
Let $A', B', C', D'$ be the intersection point of the circle and $AP, BP, CP, DP$ respectively. By angle tracing, $A'B'C'D'$ is a rectangle. Therefore $O$ is the intersection point of $A'C'$ and $B'D'$. Use central projection to map $P$ to the centre of the circle. Then by symmetry, $P, E, O$ are collinear.
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me@home
2349 posts
me@home
#5 Dec 3, 2006, 7:33 AM • 2 Y
Y by Adventure10, Mango247
Diagram:
hope that helps a little (It helped me...)
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vslmat
154 posts
vslmat
#6 Aug 5, 2012, 11:25 AM • 2 Y
Y by Adventure10, Mango247
Another solution:
Let $AP$ cut the circle at $F$, $BP$ cut the circle at $H$.
$\angle PAB + \angle PCB = \angle PCF = 90^{\circ}$,so $PC$ must cut $OF$ at a point $G$ on the circle.
Similarly, $DP$ must cut $OH$ at $K$ on the circle.
Let $GB$ cut $AK$ at $X$.
By Pascal theorem in $ACGBDK: E = AC \cap BD, P = CG \cap DK, X = AK \cap GB$ are collinear.
By Pascal theorem in $GFAKHB: O = GF \cap KH, P = FA \cap HB, X = GB \cap AK$ are collinear.
So $E, P, X, O$ are collinear
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drmzjoseph
445 posts
drmzjoseph
#7 Oct 29, 2015, 5:53 AM • 4 Y
Y by FabrizioFelen, Pirkuliyev Rovsen, Adventure10, Mango247
If $AP,BP,CP,DP$ cut to $\odot (ABCD)$ at $A',B',C',D'$ respectively. Consider $\mathcal{G}$ the composition of involutions with poles $P,E,P$ that fixed the conic $\odot (ABCD)$ is well-known that is a involution with pole on $EP$. Since $\mathcal{G}(A')=C'$ and $\mathcal{G}(B')=D' \Rightarrow A'C'$ and $B'D'$ are secants at the pole of $\mathcal{G}$. Using the condition $\angle PAB+\angle PCB=\angle PBC+\angle PDC=90^\circ$ we get $A'C'$ and $B'D'$, and are secants at $O$ so $E,P,O$ are collinear.
This post has been edited 1 time. Last edited by drmzjoseph, Oct 29, 2015, 7:57 AM
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rkm0959
1721 posts
rkm0959
#8 Oct 29, 2015, 8:40 AM • 2 Y
Y by Adventure10, Mango247
This was in Korean Postal Coaching..
Let $O_1$ be the pole of $AC$ with respect to $O$.
Draw a circle - with $O_1$ as its center and $O_1A=O_1C$ as its radius.
Then we have $2\angle APC = 2(90+\angle ADC)=180+\angle AOC = 360-\angle AO_1C$, so $P$ lies on the circle $O_1$.
Similarly, $P$ lies on the circle $O_2$. I claim that $O, P, E$ lie on the radical axis of $O_1, O_2$.
First, $O$ lies on the radical axis since $P_{O_1}(O)=OA^2=OB^2=P_{O_2}(O)$.
Also, $E$ lies on the radical axis since $AE \cdot EC = BE \cdot ED$. Therefore, we are done. $\blacksquare$
This post has been edited 1 time. Last edited by rkm0959, Oct 29, 2015, 8:40 AM
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