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k a May Highlights and 2025 AoPS Online Class Information
jlacosta   0
May 1, 2025
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0 replies
jlacosta
May 1, 2025
0 replies
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Number Theory Marathon!!!
starchan   435
N 2 minutes ago by Primeniyazidayi
Source: Possibly Mercury??
Number theory Marathon
Let us begin
P1
435 replies
starchan
May 28, 2020
Primeniyazidayi
2 minutes ago
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one cyclic formed by two cyclic
CrazyInMath   39
N 3 minutes ago by trigadd123
Source: EGMO 2025/3
Let $ABC$ be an acute triangle. Points $B, D, E$, and $C$ lie on a line in this order and satisfy $BD = DE = EC$. Let $M$ and $N$ be the midpoints of $AD$ and $AE$, respectively. Suppose triangle $ADE$ is acute, and let $H$ be its orthocentre. Points $P$ and $Q$ lie on lines $BM$ and $CN$, respectively, such that $D, H, M,$ and $P$ are concyclic and pairwise different, and $E, H, N,$ and $Q$ are concyclic and pairwise different. Prove that $P, Q, N,$ and $M$ are concyclic.
39 replies
CrazyInMath
Apr 13, 2025
trigadd123
3 minutes ago
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Either you get a 9th degree polynomial, or just easily find using inequality
Sadigly   2
N 4 minutes ago by Sadigly
Source: Azerbaijan Senior MO 2025 P2
Find all the positive reals $x,y,z$ satisfying the following equations: $$y=\frac6{(2x-1)^2}$$$$z=\frac6{(2y-1)^2}$$$$x=\frac6{(2z-1)^2}$$
2 replies
Sadigly
43 minutes ago
Sadigly
4 minutes ago
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Continuity of function and line segment of integer length
egxa   4
N 13 minutes ago by jasperE3
Source: All Russian 2025 11.8
Let \( f: \mathbb{R} \to \mathbb{R} \) be a continuous function. A chord is defined as a segment of integer length, parallel to the x-axis, whose endpoints lie on the graph of \( f \). It is known that the graph of \( f \) contains exactly \( N \) chords, one of which has length 2025. Find the minimum possible value of \( N \).
4 replies
egxa
Apr 18, 2025
jasperE3
13 minutes ago
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Range if \omega for No Inscribed Right Triangle y = \sin(\omega x)
ThisIsJoe   0
3 hours ago
For a positive number \omega , determine the range of \omega for which the curve y = \sin(\omega x) has no inscribed right triangle.
Could someone help me figure out how to approach this?
0 replies
ThisIsJoe
3 hours ago
0 replies
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Interesting question from Al-Khwarezmi olympiad 2024 P3, day1
Adventure1000   1
N 4 hours ago by pooh123
Find all $x, y, z \in \left (0, \frac{1}{2}\right )$ such that
$$ \begin{cases} (3 x^{2}+y^{2}) \sqrt{1-4 z^{2}} \geq z; \\ (3 y^{2}+z^{2}) \sqrt{1-4 x^{2}} \geq x; \\ (3 z^{2}+x^{2}) \sqrt{1-4 y^{2}} \geq y. \end{cases} $$Proposed by Ngo Van Trang, Vietnam
1 reply
Adventure1000
Yesterday at 4:10 PM
pooh123
4 hours ago
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one nice!
MihaiT   3
N 4 hours ago by Pin123
Find positiv integer numbers $(a,b) $ s.t. $\frac{a}{b-2} $ and $\frac{3b-6}{a-3}$ be positiv integer numbers.
3 replies
MihaiT
Jan 14, 2025
Pin123
4 hours ago
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Acute Angle Altitudes... say that ten times fast
Math-lover1   1
N 4 hours ago by pooh123
In acute triangle $ABC$, points $D$ and $E$ are the feet of the angle bisector and altitude from $A$, respectively. Suppose that $AC-AB=36$ and $DC-DB=24$. Compute $EC-EB$.
1 reply
Math-lover1
Yesterday at 11:30 PM
pooh123
4 hours ago
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Find a and b such that a^2 = (a-b)^3 + b and a and b are coprimes
picysm   2
N Today at 8:28 AM by picysm
it is given that a and b are coprime to each other and a, b belong to N*
2 replies
picysm
Apr 25, 2025
picysm
Today at 8:28 AM
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Algebra problem
Deomad123   1
N Today at 8:28 AM by lbh_qys
Let $n$ be a positive integer.Prove that there is a polynomial $P$ with integer coefficients so that $a+b+c=0$,then$$a^{2n+1}+b^{2n+1}+c^{2n+1}=abc[P(a,b)+P(b,c)+P(a,c)]$$.
1 reply
Deomad123
May 3, 2025
lbh_qys
Today at 8:28 AM
J
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Palindrome
Darealzolt   1
N Today at 8:01 AM by ehz2701
Find the number of six-digit palindromic numbers that are divisible by \( 37 \).
1 reply
Darealzolt
Today at 4:13 AM
ehz2701
Today at 8:01 AM
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Geometry Proof
strongstephen   17
N Today at 3:59 AM by ohiorizzler1434
Proof that choosing four distinct points at random has an equal probability of getting a convex quadrilateral vs a concave one.
not cohesive proof alert!

NOTE: By choosing four distinct points, that means no three points lie on the same line on the Gaussian Plane.
NOTE: The probability of each point getting chosen don’t need to be uniform (as long as it is symmetric about the origin), you just need a way to choose points in the infinite plane (such as a normal distribution)

Start by picking three of the four points. Next, graph the regions where the fourth point would make the quadrilateral convex or concave. In diagram 1 below, you can see the regions where the fourth point would be convex or concave. Of course, there is the centre region (the shaded triangle), but in an infinite plane, the probability the fourth point ends up in the finite region approaches 0.

Next, I want to prove to you the area of convex/concave, or rather, the probability a point ends up in each area, is the same. Referring to the second diagram, you can flip each concave region over the line perpendicular to the angle bisector of which the region is defined. (Just look at it and you'll get what it means.) Now, each concave region has an almost perfect 1:1 probability correspondence to another convex region. The only difference is the finite region (the triangle, shaded). Again, however, the actual significance (probability) of this approaches 0.

If I call each of the convex region's probability P(a), P(c), and P(e) and the concave ones P(b), P(d), P(f), assuming areas a and b are on opposite sides (same with c and d, e and f) you can get:
P(a) = P(b)
P(c) = P(d)
P(e) = P(f)

and P(a) + P(c) + P(e) = P(convex)
and P(b) + P(d) + P(f) = P(concave)

therefore:
P(convex) = P(concave)
17 replies
strongstephen
May 6, 2025
ohiorizzler1434
Today at 3:59 AM
J
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simple trapezoid
gggzul   3
N Today at 2:51 AM by imbadatmath1233
Let $ABCD$ be a trapezoid. By $x$ we denote the angle bisector of angle $X$ . Let $P=a\cap c$ and $Q=b\cap d$. Prove that $ABPQ$ is cyclic.
3 replies
gggzul
May 5, 2025
imbadatmath1233
Today at 2:51 AM
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Calculate the sidelength BC
MTA_2024   1
N Today at 2:44 AM by imbadatmath1233
Let $ABC$ be a triangle such that $AB=2AC$ and $\angle ABC =120°$. Let $D$ be the foot of the interior bissector of $\angle ABC$ (its intersection with $BC$).
If $AD=10$ calculate the sidelength $BC$.
1 reply
MTA_2024
Yesterday at 7:16 PM
imbadatmath1233
Today at 2:44 AM
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Collinear
Pascual2005   9
N Sep 14, 2016 by Virgil Nicula
Source: IberoAmerican Mathematical Olympiad 2004, Problem 5
Given a scalene triangle $ ABC$. Let $ A'$, $ B'$, $ C'$ be the points where the internal bisectors of the angles $ CAB$, $ ABC$, $ BCA$ meet the sides $ BC$, $ CA$, $ AB$, respectively. Let the line $ BC$ meet the perpendicular bisector of $ AA'$ at $ A''$. Let the line $ CA$ meet the perpendicular bisector of $ BB'$ at $ B'$. Let the line $ AB$ meet the perpendicular bisector of $ CC'$ at $ C''$. Prove that $ A''$, $ B''$ and $ C''$ are collinear.
9 replies
Pascual2005
Sep 23, 2004
Virgil Nicula
Sep 14, 2016
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Collinear
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Source: IberoAmerican Mathematical Olympiad 2004, Problem 5
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Pascual2005
1160 posts
Pascual2005
#1 Sep 23, 2004, 10:38 AM • 2 Y
Y by Adventure10, Mango247
Given a scalene triangle $ ABC$. Let $ A'$, $ B'$, $ C'$ be the points where the internal bisectors of the angles $ CAB$, $ ABC$, $ BCA$ meet the sides $ BC$, $ CA$, $ AB$, respectively. Let the line $ BC$ meet the perpendicular bisector of $ AA'$ at $ A''$. Let the line $ CA$ meet the perpendicular bisector of $ BB'$ at $ B'$. Let the line $ AB$ meet the perpendicular bisector of $ CC'$ at $ C''$. Prove that $ A''$, $ B''$ and $ C''$ are collinear.
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darij grinberg
6555 posts
darij grinberg
#2 Sep 23, 2004, 11:30 AM • 2 Y
Y by Adventure10, Mango247
This is an old problem from Igor Sharygin (exercise 3 in his Kvant article "Теоремы Чевы и Менелая"). It is the starting point of a theory about some triangle centers which I later named "Sharygin points".

Here is a solution of the problem:

Let the tangents to the circumcircle of triangle ABC at the points A, B, C meet the lines BC, CA, AB at the points X, Y, Z, respectively. It is well-known that these points X, Y, Z are collinear. Now, we will prove that A" = X, B" = Y and C" = Z; this will clearly solve the problem.

Since the point B" lies on the perpendicular bisector of the segment BB', the triangle BB"B' is isosceles. Thus, < B"BB' = < B"B'B. Hence,

< B"BA = < B"BB' - < ABB' = < B"B'B - < ABB' = < AB'B - < ABB'
= (180 - < ABB' - < BAB') - < ABB' = 180 - 2 < ABB' - < BAB'
= 180 - 2 B/2 - A = 180 - B - A = C = < BCA.

On the other hand, since the line BY is tangent to the circumcircle of triangle ABC, we have < YBA = < BCA (by the secant-tangent angle theorem). Together with < B"BA = < BCA, this implies < YBA = < B"BA, and hence the point Y lies on the line BB". Since we also know that both points Y and B" lie on the line CA, it follows that B" = Y. Similarly, C" = Z and A" = X. This completes the solution.

Darij
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khashi70
239 posts
khashi70
#3 May 23, 2007, 11:18 AM • 3 Y
Y by Adventure10, Mango247, Mango247
Consider that $\angle CBA > \angle BCA$ now we have $\angle A''AA'=\angle A''A'A=\angle BAC/2+\angle ACB$
$\longrightarrow \angle A''AB=\angle ACB$ , so $\triangle A''AB$ and $\triangle A''AC$ are similiar and we have :
$\frac{A''B}{A''A}=\frac{A''A}{A''C}=\frac{AB}{AC}\longrightarrow$ $\frac{A''B}{A''C}=\frac{AB^{2}}{AC^{2}}$ .
similiary we get that : $\frac{B''C}{B''A}=\frac{BC^{2}}{BA^{2}}$ and $\frac{C''A}{C''B}=\frac{CA^{2}}{CB^{2}}$ .
now we can check the Menelaus' theorem easily !
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Virgil Nicula
7054 posts
Virgil Nicula
#4 May 24, 2007, 7:54 AM • 2 Y
Y by Adventure10, Mango247
This nice, easy and old problem belongs to the clasical synthetical geometry.

Proof. Denote $X\in AA\cap BC$. Observe that $\{\begin{array}{c}m(\widehat{XAA'})=m(\widehat{XAB})+m(\widehat{BAA'})=C+\frac{A}{2}\\\ m(\widehat{XA'A})=m(\widehat{A'AC})+m(\widehat{A'CA})=\frac{A}{2}+C\end{array}$ $\implies$

$\widehat{XAA'}\equiv\widehat{XA'A}$ $\implies$ $\triangle AXA'$ is isosceles. In conclusion $X\equiv A''$ a.s.o.
This post has been edited 1 time. Last edited by Virgil Nicula, Sep 12, 2013, 5:33 PM
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icx
103 posts
icx
#5 May 25, 2007, 6:23 PM • 2 Y
Y by Adventure10, Mango247
Well i tried an ugly vectorial proof. Sorry for eventual mistakes, i am not into the style.

Click to reveal hidden text
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orl
3647 posts
orl
#6 Jan 1, 2009, 2:23 PM • 2 Y
Y by Adventure10, Mango247
Approach by mihai miculita:

Let $ A_1; B_1; C_1$ the intersections of external bisectors of angles $ A; B; C$ with the opposite sides. The circles of diametres $ [A'A_1], [B'B_1], [C'C_1]$ is the Appollonius circles of $ \triangle{ABC}$ and the points $ A", B", C"$ is the Appolonian circles centres $ \Rightarrow$ the points $ A", B", C"$ coliniar!
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vittasko
1327 posts
vittasko
#7 Jan 1, 2009, 10:34 PM • 1 Y
Y by Adventure10
Also, it has been posted as An interesting line of a triangle, by nayel.

Kostas Vittas.
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mathreyes
109 posts
mathreyes
#8 Sep 8, 2013, 6:51 PM • 2 Y
Y by Adventure10, Mango247
Sorry for reviving, but...

Let the $A$-tangent to $(ABC)$ meet $\overleftrightarrow{BC}$ in $A^{*}$, then $\measuredangle A^{*}A'A=\measuredangle A'AC+\measuredangle A'CA=\measuredangle BAA'+\measuredangle BAA^{*}=\measuredangle A^{*}AA'$, so $\Delta A^{*}AA'$ is $A^{*}$-isosceles thus perpendicular bisector of $\overline{AA'}$ passes through $A^{*}$. This shows that $A^{*}=A''$.
As we know, $A^{*}$, $B^{*}$ and $C^{*}$ form the Lemoine's line of $\Delta ABC$, so $A''$, $B''$ and $C''$ are colinear.
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Guendabiaani
778 posts
Guendabiaani
#10 Sep 13, 2016, 10:35 PM • 1 Y
Y by Adventure10
Note that $\angle A''AB = \angle A''AA' - \angle A/2 = 180^{\circ}-\angle B - \angle A/2 - \angle A/2 = \angle C$ so $A''A$ is tangent to $(ABC)$ at $A$.

Let $X,Y,Z$ be the points on $BC,CA,AB$ respectively such that $AX,BY,CZ$ are symmedians. Let $T$ be the intersection of the tangents to $(ABC)$ at $B,C$. Then $A'' \in BC$ the polar of $T$ so $T$ is in the polar of $A''$. Similarly $A$ lies in the polar of $A''$ because $A''A$ is tangent to $(ABC)$.

Therefore $AT$ is the polar of $A''$ and it is well known that $AT$ is the symmedian so $X$ is also in the polar of $A''$. Thus by a well known lemma we have $(B,C;X,A'') = -1$.

We know that $AX,BY,CZ$ are concurrent at the symmedian point of $\triangle ABC$ so $YZ \cap BC = A_1$ satisfies $(B,C;X,A_1) = -1$. Therefore $A'' = YZ \cap BC$ and similarly $B'' = XZ \cap AC, C'' = XY \cap AB$.

Since $AX,BY,CZ$ concur we know that triangles $ABC$ and $XYZ$ are perspective meaning $AB \cap XY, BC \cap YZ, CA \cap XZ = A'',B'',C''$ are collinear as desired.
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Virgil Nicula
7054 posts
Virgil Nicula
#11 Sep 14, 2016, 10:02 PM • 2 Y
Y by Adventure10, Mango247
See P5 from here
This post has been edited 1 time. Last edited by Virgil Nicula, Sep 15, 2016, 8:47 PM
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