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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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Constant Angle Sum
i3435   6
N a few seconds ago by bin_sherlo
Source: AMASCIWLOFRIAA1PD (mock oly geo contest) P3
Let $ABC$ be a triangle with circumcircle $\Omega$, $A$-angle bisector $l_A$, and $A$-median $m_A$. Suppose that $l_A$ meets $\overline{BC}$ at $D$ and meets $\Omega$ again at $M$. A line $l$ parallel to $\overline{BC}$ meets $l_A$, $m_A$ at $G$, $N$ respectively, so that $G$ is between $A$ and $D$. The circle with diameter $\overline{AG}$ meets $\Omega$ again at $J$.

As $l$ varies, show that $\angle AMN + \angle DJG$ is constant.

MP8148
6 replies
i3435
May 11, 2021
bin_sherlo
a few seconds ago
J
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NEPAL TST 2025 DAY 2
Tony_stark0094   8
N 16 minutes ago by cursed_tangent1434
Consider an acute triangle $\Delta ABC$. Let $D$ and $E$ be the feet of the altitudes from $A$ to $BC$ and from $B$ to $AC$ respectively.

Define $D_1$ and $D_2$ as the reflections of $D$ across lines $AB$ and $AC$, respectively. Let $\Gamma$ be the circumcircle of $\Delta AD_1D_2$. Denote by $P$ the second intersection of line $D_1B$ with $\Gamma$, and by $Q$ the intersection of ray $EB$ with $\Gamma$.

If $O$ is the circumcenter of $\Delta ABC$, prove that $O$, $D$, and $Q$ are collinear if and only if quadrilateral $BCQP$ can be inscribed within a circle.

$\textbf{Proposed by Kritesh Dhakal, Nepal.}$
8 replies
Tony_stark0094
Apr 12, 2025
cursed_tangent1434
16 minutes ago
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Interesting inequalities
sqing   4
N 22 minutes ago by sqing
Source: Own
Let $ a,b,c\geq 0 $ and $ ab+bc+ca+abc=4$ . Prove that
$$k(a+b+c) -ab-bc\geq 4\sqrt{k(k+1)}-(k+4)$$Where $ k\geq \frac{16}{9}. $
$$ \frac{16}{9}(a+b+c) -ab-bc\geq \frac{28}{9}$$
4 replies
+1 w
sqing
3 hours ago
sqing
22 minutes ago
J
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NEPAL TST DAY 2 PROBLEM 2
Tony_stark0094   6
N 34 minutes ago by cursed_tangent1434
Kritesh manages traffic on a $45 \times 45$ grid consisting of 2025 unit squares. Within each unit square is a car, facing either up, down, left, or right. If the square in front of a car in the direction it is facing is empty, it can choose to move forward. Each car wishes to exit the $45 \times 45$ grid.

Kritesh realizes that it may not always be possible for all the cars to leave the grid. Therefore, before the process begins, he will remove $k$ cars from the $45 \times 45$ grid in such a way that it becomes possible for all the remaining cars to eventually exit the grid.

What is the minimum value of $k$ that guarantees that Kritesh's job is possible?

$\textbf{Proposed by Shining Sun. USA}$
6 replies
Tony_stark0094
Apr 12, 2025
cursed_tangent1434
34 minutes ago
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No more topics!
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Symmedian line
April   89
N Apr 7, 2025 by Avron
Source: All Russian Olympiad - Problem 9.2, 10.2
Let be given a triangle $ ABC$ and its internal angle bisector $ BD$ $ (D\in BC)$. The line $ BD$ intersects the circumcircle $ \Omega$ of triangle $ ABC$ at $ B$ and $ E$. Circle $ \omega$ with diameter $ DE$ cuts $ \Omega$ again at $ F$. Prove that $ BF$ is the symmedian line of triangle $ ABC$.
89 replies
April
May 10, 2009
Avron
Apr 7, 2025
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Symmedian line
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Reveal topic tags
geometry
circumcircle
incenter
ratio
symmetry
geometric transformation
L
G H BBookmark kLocked kLocked NReply
Source: All Russian Olympiad - Problem 9.2, 10.2
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April
1270 posts
April
#1 May 10, 2009, 3:49 PM • 8 Y
Y by Amir Hossein, dave_mathsguru, 799786, itslumi, Adventure10, Mango247, fuzzball2023, and 1 other user
Let be given a triangle $ ABC$ and its internal angle bisector $ BD$ $ (D\in BC)$. The line $ BD$ intersects the circumcircle $ \Omega$ of triangle $ ABC$ at $ B$ and $ E$. Circle $ \omega$ with diameter $ DE$ cuts $ \Omega$ again at $ F$. Prove that $ BF$ is the symmedian line of triangle $ ABC$.
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mathVNpro
469 posts
mathVNpro
#2 May 10, 2009, 5:14 PM • 6 Y
Y by Olemissmath, Psyduck909, Adventure10, Mango247, fuzzball2023, ehuseyinyigit
Let $ M_b$ be midpoint of $ AC$.
We have $ \angle FAM_b = \angle FBC$, $ \angle AM_bF\equiv \angle DM_bF = \angle DEF = \angle BEF = \angle BCF$
$ \Rightarrow \triangle FAM_b\sim \triangle FBC$, $ (i)$. Thus, through the spiral similarity with center $ F$, denote this $ f$ then:
$ f: \triangle FAM_b\mapsto \triangle FBC$
$ \Rightarrow f: A\mapsto B$, $ M_b\mapsto C$
$ \Rightarrow f: A\mapsto M_b$, $ B\mapsto C$
$ \Rightarrow f: \triangle FAB\mapsto \triangle FM_bC$, $ (1)$
But it is easy to notice that: $ \triangle BAF\sim \triangle BM_bC$ (a.a), $ (2)$
$ (1),(2)\Rightarrow \triangle CM_bB\sim \triangle FM_bC$
$ \Rightarrow \frac {CB}{CF} = \frac {CM_b}{FM_b} = \frac {M_bB}{M_bC}$, $ (*)$.
With the same argument, we get $ \triangle BAM_b\sim \triangle BFC$
$ \Rightarrow \triangle BAM_b\sim \triangle AFM_b$ (thanks to $ (i)$).
$ \Rightarrow \frac {BA}{AF} = \frac {M_bB}{M_bA}$, $ (**)$
But $ M_bA = M_bC \Rightarrow \frac {BA}{BC} = \frac {FA}{FC}$ (Combine $ (*)\&(**)$)
$ \Longrightarrow ABCF$ is a harmonic quadrilateral. Therefore, $ BF$ passes through the Pole of $ AC$ wrt $ (O)$, where $ O$ is the circumcenter of $ \triangle ABC$. Then we will get the result of the problem.
Our proof is completed then :lol:
This post has been edited 1 time. Last edited by mathVNpro, May 11, 2009, 4:56 AM
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silouan
3952 posts
silouan
#3 May 10, 2009, 6:41 PM • 6 Y
Y by ultralako, Adventure10, Mango247, fuzzball2023, and 2 other users
Let $ M$ the midpoint of $ AC$ , $ O$ the circumcenter of $ \Omega$ and let the tangent to $ \Omega$ at $ B$ meets $ AC$ at $ R$ .
Then $ BOMR$ is cyclic (let $ Q$ its circumcenter) . Then $ R,Q,O$ are collinear . So if the circumcircle of $ BOMR$ meets $ \Omega$ at $ F'$ , then $ BF'\bot RO$ . So by polars $ RF'$ is tangent to $ \Omega$ . By well known theorem we have that $ BF'$ is the $ B$ symmedian. Finally if $ BE$ meets the circumcircle of $ BOMR$ at $ S$ , then $ SM=SF$ . But also because $ RF'=RB$ we have that $ D$ is the incenter of $ F'BM$ so $ SD=SM=SF$ and because $ DM\bot ME$ we also have $ SD=SM=SF=SE$ . This shows that $ MDF'E$ is cyclic and so $ F\equiv F'$ and we are done .
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yetti
2643 posts
yetti
#4 May 10, 2009, 6:54 PM • 4 Y
Y by Adventure10, Mango247, and 2 other users
External bisector of $ \angle B$ cuts $ CA$ at $ Y.$ $ I, I_b$ are incenter and B-excenter of $ \triangle ABC.$ $ (E)$ is a circle with center $ E$ and radius $ EA = EC = EI = EI_b.$ The cross ratio $ (B, D, I, I_b)$ is harmonic and $ E$ the midpoint of $ II_b$ $ \Longrightarrow$ $ \overline{BD} \cdot \overline{BE} = \overline{BI}\cdot \overline{BI_b}$ $ \Longrightarrow$ $ BY \perp BDE$ is radical axis of $ \omega, (E).$ Pairwise radical axes $ EF, CA, BY$ of $ \Omega, \omega, (E)$ meet at their radical center $ Y.$ Since $ DF \perp EFY$ and $ BY \perp BDE,$ $ BDFY$ is cyclic. Its circumcircle is the B-Apollonius circle of $ \triangle ABC$ $ \Longrightarrow$ $ BF$ is the B-symmedian.
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Virgil Nicula
7054 posts
Virgil Nicula
#5 May 11, 2009, 2:26 AM • 6 Y
Y by Amir Hossein, Adventure10, Mango247, fuzzball2023, and 2 other users
PP. Let be given a triangle $ ABC$ and its internal angle bisector $ BD$ $ (D\in BC)$ . The line $ BD$ intersects the circumcircle $ \Omega$ of
$\triangle ABC$ at $ B$ and $ E$ . Circle $ \omega$ with diameter $ DE$ cuts $ \Omega$ again at $ F$. Prove that $ BF$ is the symmedian line of triangle $ ABC$ .

Lemma. Let $ ABC$ be a triangle with the circumcircle $ w$ . Denote the following points : the middlepoint $ M$ of the side $ [BC]$ ;

the point $ D\in (BC)$ for which $ \angle DAB\equiv\angle DAC$ ; the point $ E$ for which $ \{A,E\} = AD\cap w$ ; the $ A$-symmedian $ AL$ ,

where $ L\in (BC)$ ; the point $ S$ for which $ \{A,S\} = AL\cap w$ . Then $ SD\perp SE$ , i.e. the quadrilateral $ MDSE$ is cyclically.

Proof. Denote $ XX$ - the tangent in $ X\in w$ to $ w$ . Denote $ T\in BB\cap CC$ . Observe that $ \overline {MET}\perp BC$ and $ \angle ASB\equiv\angle ACB$ .

From the first well-known property, $ T\in \overline {ALS}$ and the line $ \overline{ALST}$ is the $ A$-symmedian in $ \triangle ABC$ $ \Longrightarrow$ $ \left\|\begin{array}{c} \angle BAS\equiv\angle MAC \\ \ \angle SAE\equiv\angle DAM\end{array}\right\|$ .

From the second well-known property, the division $ \{A,S;L,T\}$ is harmonically. Since $ ML\perp MT$ results $ \angle DMA\equiv\angle DMS$ .

Show easily that $ \triangle BAS\sim\triangle MAC$ (a.a.) . Thus, $ \frac {AB}{AS} = \frac {AM}{AC}$ , i.e. $ AS\cdot AM = AB\cdot AC$ .

From the third well-known property $ AD\cdot AE = AB\cdot AC$, obtain $ \boxed {AS\cdot AM = AD\cdot AE = AB\cdot AC}$ , i.e. $ \frac {AS}{AE} = \frac {AD}{AM}$ .

Since $ \angle SAE\equiv\angle DAM$ obtain $ \triangle SAE\sim\triangle DAM$ and in consequence, $ \angle DMA\equiv\angle SEA$ . Since $ \angle DMA\equiv\angle DMS$

and $ \angle SEA\equiv\angle SED$ obtain $ \angle DMS\equiv\angle SED$ , i.e. the quadrilateral $ MDSE$ is cyclically. In conclusion, $ SD\perp SE$ .

Remark. Here are another interesting metrical relations : $ \left\|\begin{array}{ccc} ABS\sim CMS & \implies & \boxed {SB\cdot SC = SA\cdot SM} \\ \\ AMC\sim CMS & \implies & \boxed {MA\cdot MS = MB^2}\end{array}\right\|$ .

The proposed problem is an immediate consequence of the above lemma. See PP13 from here
This post has been edited 4 times. Last edited by Virgil Nicula, Aug 11, 2014, 1:54 AM
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jayme
9775 posts
jayme
#6 May 11, 2009, 5:22 AM • 3 Y
Y by AlastorMoody, Adventure10, fuzzball2023
Dear Mathlinkers,
1. Let A' be the midpoint of BC, X, Y the second meetpoint of AA', EA' with the circumcircle of ABC and Te the tangent to this circumcircle at E.
2. Te // DA'
3. The circle with diameter ED passes through A'
4. By a converse of Reim's theorem applied to this circle and the circumcircle, FD goes through Y;
5. By a converse of Pascal's theorem applied to EAXFYTe, FX //DA' (BC)
and we are done...
Sincerely
Jean-Louis
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Agr_94_Math
881 posts
Agr_94_Math
#7 May 11, 2009, 6:19 AM • 3 Y
Y by Adventure10, Mango247, ehuseyinyigit
Very nice application of Reim's Theorem jayme.Though a very obvious result, it has great application in many synthetic geometry results.
Thanks.
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mathVNpro
469 posts
mathVNpro
#8 May 11, 2009, 10:26 AM • 2 Y
Y by Adventure10, Mango247
jayme wrote:
Dear Mathlinkers,
1. Let A' be the midpoint of BC, X, Y the second meetpoint of AA', EA' with the circumcircle of ABC and Te the tangent to this circumcircle at E.
2. Te // DA'
3. The circle with diameter ED passes through A'
4. By a converse of Reim's theorem applied to this circle and the circumcircle, FD goes through Y;
5. By a converse of Pascal's theorem applied to EAXFYTe, FX //DA' (BC)
and we are done...
Sincerely
Jean-Louis
Do you have any document about Reim's theorem, Jayme? I am so excited about this. :blush:
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jayme
9775 posts
jayme
#9 May 11, 2009, 11:29 AM • 3 Y
Y by Adventure10, Mango247, fuzzball2023
See for example my website
http://perso.orange.fr/jl.ayme then: A propos
You will see all the possibility.
Sincerely
Jean-Louis
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ma 29
40 posts
ma 29
#10 May 11, 2009, 12:02 PM • 16 Y
Y by MexicOMM, Wizard_32, Durjoy1729, HolyMath, Siddharth03, Greenleaf5002, myh2910, snakeaid, centslordm, Jalil_Huseynov, Adventure10, Mango247, GustavoPudim, fuzzball2023, and 2 other users
Dear friends.
I have a short solution for the nice problem,here :) .
//cdn.artofproblemsolving.com/images/4a3755e6df266a6313f50f6a8a6c7c8845715061.jpg

Denote by $ A'$ the midpoint of segment $ AC$.

$ EO$ meets $ (O)$ again at $ P$

By ${ \angle {DFE} = 90^0}$ ,we have $ F,D,P$ are collinear.

From $ BPEF$ is cyclic and $ BDA'P$ is cylic ,we have :

$ \angle {EBF} = \angle {EPF} = \angle{DBA'}$.

Therefor,$ BF$is the symmedian line of the triangle $ BAC$.
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armpist
527 posts
armpist
#11 May 11, 2009, 1:38 PM • 3 Y
Y by Adventure10, Mango247, and 1 other user
All are very nice solutions indeed, I must admit.



T.Y.
M.T.
This post has been edited 1 time. Last edited by armpist, May 11, 2009, 8:29 PM
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Virgil Nicula
7054 posts
Virgil Nicula
#12 May 11, 2009, 4:21 PM • 2 Y
Y by Adventure10, Mango247
After the Ma29's shortest proof, this problem seems very simple ...
In the another proofs appeared many nice properties of this configuration.
Thanks to all for their interest and proofs.
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ma 29
40 posts
ma 29
#13 May 13, 2009, 8:58 AM • 2 Y
Y by Adventure10, Mango247
Hello my friends.
I think all proof above are very nice. :)
Here is another solution to this problem:
//cdn.artofproblemsolving.com/images/c51085c9ea4036fa17fa17def72321254472bf4e.jpg

Denote $ V = EF \cap AC$.

We have :$ \bar {VD} .\bar{VA'} = \bar{VF}.\bar{VE} = \bar{VA}.\bar{VC}$ (1)

But $ A'$ is the midpoint of segment $ AC$.(2)

From (1) ,(2) and Maclaurin's theorem , we obtain the division $ {VDAC}$ is harmonically,so $ V,B,P$ are collinear.

Denote $ Q = BC\cap {PA}$ and denote by $ H$ the intersection of two tangent to $ (O)$ at $ A,C$ ,respectively.

We have $ Q,D,H$ lie on the polar of $ V$ wrt $ (O)$,i.e $ Q,D,H$ are collinear.

By Pascal's theorem applied to six point $ A,A,P,C,B,F$ ,we obtain $ B,F,H$ are collinear.

Therefore ,$ BF$ is the symedian line of the triangle $ ABC$.
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bravado
19 posts
bravado
#14 May 13, 2009, 10:30 PM • 2 Y
Y by Adventure10, Mango247
It can also be viewed as an easy application of : http://www.mathlinks.ro/viewtopic.php?p=1082899#1082899

Indeed, from the above problem it follows that the line $ FM$ (where $ M$ is the midpoint of $ AC$) meets the circumcircle of $ \triangle{ABC}$ at a point $ T$ such that $ BT||AC$. By symmetry,
\[ \angle{MBC} = \angle{MTA} = \angle{ABF}. \]
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Virgil Nicula
7054 posts
Virgil Nicula
#15 May 14, 2009, 8:32 PM • 2 Y
Y by Adventure10, Mango247
We can use my found property at the proposed problem from here.
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