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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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2010 Japan MO Finals
parkjungmin   1
N 12 minutes ago by parkjungmin
Is there anyone who can solve question problem 5?
1 reply
parkjungmin
14 minutes ago
parkjungmin
12 minutes ago
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All-Russian Olympiad
ABCD1728   3
N 27 minutes ago by RagvaloD
When did the first ARMO occur? 2025 is the 51-st, but ARMO on AoPS starts from 1993, there are only 33 years.
3 replies
ABCD1728
an hour ago
RagvaloD
27 minutes ago
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Hard geometry
Lukariman   6
N an hour ago by Lukariman
Given circle (O) and chord AB with different diameters. The tangents of circle (O) at A and B intersect at point P. On the small arc AB, take point C so that triangle CAB is not isosceles. The lines CA and BP intersect at D, BC and AP intersect at E. Prove that the centers of the circles circumscribing triangles ACE, BCD and OPC are collinear.
6 replies
Lukariman
Yesterday at 4:28 AM
Lukariman
an hour ago
J
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Simple but hard
TUAN2k8   1
N an hour ago by Funcshun840
Source: Own
I need synthetic solution:
Given an acute triangle $ABC$ with orthocenter $H$.Let $AD,BE$ and $CF$ be the altitudes of triangle.Let $X$ and $Y$ be reflections of points $E,F$ across the line $AD$, respectively.Let $M$ and $N$ be the midpoints of $BH$ and $CH$, respectively.Let $K=YM \cap AB$ and $L=XN \cap AC$.Prove that $K,D$ and $L$ are collinear.
1 reply
TUAN2k8
3 hours ago
Funcshun840
an hour ago
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lines intersecting motions of an ellipse
FFA21   0
Yesterday at 8:33 PM
Source: OSSM Comp'25 P5 (HSE IMC qualification)
Let $E$ be an infinite set of translated copies (i.e., obtained by parallel translation) of a given ellipse $e$ in the plane, and let $r$ be a fixed straight line. It is known that every straight line parallel to $r$ intersects at least one ellipse from $E$. Prove that there exist infinitely many triples of ellipses from $E$ such that there exists a straight line intersecting all three ellipses in the triple.
0 replies
FFA21
Yesterday at 8:33 PM
0 replies
J
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fibonacci number theory
FFA21   0
Yesterday at 8:21 PM
Source: OSSM Comp'25 P3 (HSE IMC qualification)
$F_n$ fibonacci numbers ($F_1=1, F_2=1$) find all n such that:
$\forall i\in Z$ and $0\leq i\leq F_n$
$C^i_{F_n}\equiv (-1)^i\pmod{F_n+1}$
0 replies
FFA21
Yesterday at 8:21 PM
0 replies
J
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strong polinom
FFA21   0
Yesterday at 8:13 PM
Source: OSSM Comp'25 P2 (HSE IMC qualification)
A polynomial will be called 'strong' if it can be represented as a product of two non-constant polynomials with real non-negative coefficients.
Prove that:
$\exists n$ that $p(x^n)$ 'strong' and $deg(p)>1$ $\implies$ $p(x)$ 'strong'
0 replies
FFA21
Yesterday at 8:13 PM
0 replies
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integrals
FFA21   0
Yesterday at 8:05 PM
Source: OSSM Comp'25 P1 (HSE IMC qualification)
Find all continuous functions $f:[1,8]\to R$ that:
$\int_1^2f(t^3)^2dt+2\int_1^2sin(t)f(t^3)dt=\frac{2}{3}\int_1^8f(t)dt-\int_1^2(t^2-sin(t))^2dt$
0 replies
FFA21
Yesterday at 8:05 PM
0 replies
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Mathematical expectation 1
Tricky123   4
N Yesterday at 7:47 PM by solyaris
X is continuous random variable having spectrum
$(-\infty,\infty) $ and the distribution function is $F(x)$ then
$E(X)=\int_{0}^{\infty}(1-F(x)-F(-x))dx$ and find the expression of $V(x)$

Ans:- $V(x)=\int_{0}^{\infty}(2x(1-F(x)+F(-x))dx-m^{2}$

How to solve help me
4 replies
Tricky123
May 11, 2025
solyaris
Yesterday at 7:47 PM
J
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B.Math 2008-Integration .
mynamearzo   14
N Yesterday at 4:02 PM by Levieee
Source: 10+2
Let $f:\mathbb{R} \to \mathbb{R}$ be a continuous function . Suppose
\[f(x)=\frac{1}{t} \int^t_0 (f(x+y)-f(y))\,dy\]
$\forall x\in \mathbb{R}$ and all $t>0$ . Then show that there exists a constant $c$ such that $f(x)=cx\ \forall x$
14 replies
mynamearzo
Apr 16, 2012
Levieee
Yesterday at 4:02 PM
J
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uniformly continuous of multivariable function
keroro902   1
N Yesterday at 1:42 PM by Mathzeus1024
How can I determine which of the following functions are uniformly continuous on the given domain A?

$f \left( x, y \right) = \frac{x^3 + y^2}{x^2 + y}$ , $A = \left\{ \left( x, y \right) \in \mathbb m{R}^2 \left| \right. \left| y \right| \leq \frac{x^2}{2} %Error. "nocomma" is a bad command. , x^2 + y^2 < 1 \right\}$

$g \left( x, y \right) = \frac{y^2 + 4 x^2}{y^2 - 4 x^2 - 1}$, $A = \left\{ \left( x, y \right) \in \mathbb m{R}^2 \left| 0 \leq x^2 - y^2 \leqslant 1 \right\} \right.$
1 reply
keroro902
Nov 2, 2012
Mathzeus1024
Yesterday at 1:42 PM
J
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Investigating functions
mikejoe   1
N Yesterday at 1:08 PM by Mathzeus1024
Source: Edwards and Penney
Investigate the function $f(x) = (x-2) \sqrt{x+1}$
Also determine its domain and range.
1 reply
mikejoe
Nov 2, 2012
Mathzeus1024
Yesterday at 1:08 PM
J
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functional equation
pratyush   2
N Yesterday at 12:41 PM by Mathzeus1024
For the functional equation $f(x-y)=\frac{f(x)}{f(y)}$, if f ' (0)=p and f ' (5)=q, then prove f ' (-5) = q
2 replies
pratyush
Apr 4, 2014
Mathzeus1024
Yesterday at 12:41 PM
J
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ISI UGB 2025 P1
SomeonecoolLovesMaths   7
N Yesterday at 12:28 PM by SatisfiedMagma
Source: ISI UGB 2025 P1
Suppose $f \colon \mathbb{R} \longrightarrow \mathbb{R}$ is differentiable and $| f'(x)| < \frac{1}{2}$ for all $x \in \mathbb{R}$. Show that for some $x_0 \in \mathbb{R}$, $f \left( x_0 \right) = x_0$.
7 replies
SomeonecoolLovesMaths
May 11, 2025
SatisfiedMagma
Yesterday at 12:28 PM
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Inequality in a right triangle
Rijul saini   6
N Jan 17, 2015 by aditya21
Source: INMO 2007 Question 1
In a triangle $ ABC$ right-angled at $ C$ , the median through $ B$ bisects the angle between $ BA$ and the bisector of $ \angle B$. Prove that
\[ \frac{5}{2} < \frac{AB}{BC} < 3\]
6 replies
Rijul saini
Nov 2, 2009
aditya21
Jan 17, 2015
J
Inequality in a right triangle
G H J
Reveal topic tags
inequalities
trigonometry
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geometry unsolved
geometry
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G H BBookmark kLocked kLocked NReply
Source: INMO 2007 Question 1
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Rijul saini
904 posts
Rijul saini
#1 Nov 2, 2009, 11:57 AM • 2 Y
Y by Adventure10, Mango247
In a triangle $ ABC$ right-angled at $ C$ , the median through $ B$ bisects the angle between $ BA$ and the bisector of $ \angle B$. Prove that
\[ \frac{5}{2} < \frac{AB}{BC} < 3\]
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castigioni
616 posts
castigioni
#2 Dec 12, 2009, 5:15 PM • 2 Y
Y by Adventure10, Mango247
The solution is a=2.65896...b
So a/b=2.65896... that is between 3/2 and 3
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Rijul saini
904 posts
Rijul saini
#3 Dec 12, 2009, 5:28 PM • 2 Y
Y by Adventure10, Mango247
castigioni wrote:
The solution is a=2.65896...b
So a/b=2.65896... that is between 3/2 and 3
Please write your full proof...I would really like to see it...
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Rijul saini
904 posts
Rijul saini
#4 Dec 28, 2009, 3:26 AM • 2 Y
Y by Adventure10, Mango247
Hey can't anyone give a full proof of this...
The 2nd post is definitely done by calculator....That is NOT ALLOWED in out national olympiads....
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behdad.math.math
255 posts
behdad.math.math
#5 Dec 29, 2009, 8:23 AM • 2 Y
Y by Adventure10, Mango247
Rijul saini wrote:
In a triangle $ ABC$ right-angled at $ C$ , the median through $ B$ bisects the angle between $ BA$ and the bisector of $ \angle B$. Prove that
\[ \frac {5}{2} < \frac {AB}{BC} < 3\]
$ \angle\frac {B}{4}$ $ =$ $ \alpha$ and $ M$ is the midpoint of $ AC$
We can compute that $ \sin3\alpha$ $ \cos4\alpha$ $ =$ $ \sin\alpha$ ,
We know that $ \frac {c}{sin90}$ $ =$ $ \frac {a}{sin(90 - 4\alpha)}$, Hence $ \frac {c}{a}$ = $ \frac {1}{\cos4\alpha}$ = $ \frac {\sin3\alpha}{\sin\alpha}$ = $ 3 - (\sin\alpha)^2$.
$ \Longrightarrow$ $ \frac {c}{a}$ $ <$ $ 3$.
$ \cos2\alpha$ $ =$ $ \frac {(\frac {c}{a} - 1)}{2}$ $ \Longrightarrow$ $ \frac {a}{c}$ $ =$ $ \cos4\alpha$ $ =$ $ \frac {1}{2}$$ (\frac {c}{a} - 1)^2 - 1$.

Consider $ \frac {c}{a}$ $ \leq$ $ \frac {5}{2}$ and this is contradict with the initial consideration, namely, $ \frac {c}{a}$ $ >$ $ \frac {5}{2}$
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tc1729
1221 posts
tc1729
#6 Apr 29, 2012, 8:13 PM • 1 Y
Y by Adventure10
Since $E$ is the midpoint of $AC$, we have $AE=EC=\frac{b}{2}$. Since $BD$ bisects $\angle ABC$, we also have $CD=\frac{ab}{a+c}$. Since $BE$ bisects $\angle ABD$, we have \[\frac{BD^2}{BA^2}=\frac{DE^2}{EA^2}.\] However we have \[\begin{cases}BD^2=BC^2+CD^2=a^2\frac{a^2b^2}{(a+c)^2} \\ DE^2=\left(\frac{b}{2}-\frac{ab}{a+c}\right)^2\end{cases}\] Using these in the above expression and simplifying yields \[a\left[(a+c)^2+b^2\right] = c^2(c-a)^2.\] Using $c^2=a^2+b^2$ and eliminating $b$, we obtain \[c^3-2ac^2-a^2c-2a^3=0.\] Substituting $t=\frac{c}{a}$, we reduce this to a cubic: \[t^3-2t^2-t-2=0.\] Now, consider the function $f(t)=t^3-2t^2-t-2$ for $t>0$, since $c/a\in\mathbb{Z}^{+}$. For $\, we see that $f(t)=t^2(t-20-t-2<0$. We also observe that $f(t)=(t-2)(t^2-1)-4$ is strictly increasing on the interval $(2, \infty)$. It is easy to compute $f(5/2)=-\frac{11}{8}<0$ and $f(3)=4>0$. Hence there is a unique value of $t$ in the interval $(\frac{5}{2}, 3)$ such that $f(t)=0$. Hence \[\frac{5}{2}<\frac{c}{a}<3\] as desired. $\Box$
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aditya21
717 posts
aditya21
#7 Jan 17, 2015, 2:42 PM • 1 Y
Y by Adventure10
my solution

solution =

$\angle\frac {B}{4} = \alpha$ and$ M$ is the midpoint of $AC $
using sine law in triangle $ABE$ and$BEC $, we obtain
that $\sin3\alpha \cos4\alpha = \sin\alpha , $

We know that$ \frac {c}{sin90} = \frac {a}{sin(90 - 4\alpha)}$, Hence
$\frac {c}{a} = \frac {1}{\cos4\alpha} = \frac {\sin3\alpha}{\sin\alpha} = 3 - (\sin\alpha)^2.$
trivially,
$\Longrightarrow \frac {c}{a} < 3.$

now , to prove that $(5/2) < (c/a) = 3- 4sin^2\alpha$
this is equivalent to $sin\alpha< (1/2^{3/2} )$
now we know
$sin\alpha < sin (22.5) < (3^{1/2} - 1)/(2^{3/2}) < 1/(2^{3/2} )$

and we are done :P :D
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