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k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Wednesday at 3:18 PM
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0 replies
jlacosta
Wednesday at 3:18 PM
0 replies
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inequality ( 4 var
SunnyEvan   1
N 3 minutes ago by SunnyEvan
Let $ a,b,c,d \in R $ , such that $ a+b+c+d=4 . $ Prove that :
$$ a^4+b^4+c^4+d^4+3 \geq \frac{7}{4}(a^3+b^3+c^3+d^3) $$$$ a^4+b^4+c^4+d^4+ \frac{252}{25} \geq \frac{88}{25}(a^3+b^3+c^3+d^3) $$equality cases : ?
1 reply
SunnyEvan
5 hours ago
SunnyEvan
3 minutes ago
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Inspired by JK1603JK
sqing   6
N 5 minutes ago by sqing
Source: Own
Let $ a,b,c\geq 0 $ and $ab+bc+ca=1.$ Prove that$$\frac{abc-2}{abc-1}\ge \frac{4(a^2b+b^2c+c^2a)}{a^3b+b^3c+c^3a+1} $$
6 replies
sqing
Today at 3:31 AM
sqing
5 minutes ago
J
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Geometry problem
kjhgyuio   1
N an hour ago by Mathzeus1024
Source: smo
In trapezium ABCD,AD is parallel to BC and points E and F are midpoints of AB and DC respectively. If
Area of AEFD/Area of EBCF =√3 + 1/3-√3 and the area of triangle ABD is √3 .find the area of trapezium ABCD
1 reply
kjhgyuio
Apr 1, 2025
Mathzeus1024
an hour ago
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D1018 : Can you do that ?
Dattier   1
N an hour ago by Dattier
Source: les dattes à Dattier
We can find $A,B,C$, such that $\gcd(A,B)=\gcd(C,A)=\gcd(A,2)=1$ and $$\forall n \in \mathbb N^*, (C^n \times B \mod A) \mod 2=0 $$.

For example :

$C=20$
$A=47650065401584409637777147310342834508082136874940478469495402430677786194142956609253842997905945723173497630499054266092849839$

$B=238877301561986449355077953728734922992395532218802882582141073061059783672634737309722816649187007910722185635031285098751698$

Can you find $A,B,C$ such that $A>3$ is prime, $C,B \in (\mathbb Z/A\mathbb Z)^*$ with $o(C)=(A-1)/2$ and $$\forall n \in \mathbb N^*, (C^n \times B \mod A) \mod 2=0 $$?
1 reply
Dattier
Mar 24, 2025
Dattier
an hour ago
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Inequalities
sqing   0
Today at 3:52 AM
Let $ a,b,c> 0 $ and $ \frac{a}{a^2+ab+c}+\frac{b}{b^2+bc+a}+\frac{c}{c^2+ca+b} \geq 1$. Prove that
$$ a+b+c\leq 3 $$
0 replies
sqing
Today at 3:52 AM
0 replies
J
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Excalibur Identity
jjsunpu   8
N Today at 2:08 AM by MineCuber
proof is below
8 replies
jjsunpu
Yesterday at 3:27 PM
MineCuber
Today at 2:08 AM
J
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New geometry problem
titaniumfalcon   1
N Today at 1:51 AM by mathprodigy2011
Post any solutions you have, with explanation or proof if possible, good luck!
1 reply
titaniumfalcon
Yesterday at 10:40 PM
mathprodigy2011
Today at 1:51 AM
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Geo Mock #7
Bluesoul   1
N Yesterday at 8:20 PM by vanstraelen
Consider $\triangle{ABC}$ with $\angle{A}=90^{\circ}$ and $AB=10$. Let $D$ be a point on $AB$ such that $BD=6$. Suppose that the angle bisector of $\angle{C}$ is tangent to the circle with diameter $BD$ and say it intersects $AB$ at point $E$. Find the length of $BE$.
1 reply
Bluesoul
Apr 1, 2025
vanstraelen
Yesterday at 8:20 PM
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Number of solutions
Ecrin_eren   3
N Yesterday at 8:00 PM by rchokler
The given equation is:

x³ + 4y³ + 2y = (2024 + 2y)(xy + 1)

The question asks for the number of integer solutions.

3 replies
Ecrin_eren
Yesterday at 11:27 AM
rchokler
Yesterday at 8:00 PM
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Geo Mock #8
Bluesoul   1
N Yesterday at 7:06 PM by vanstraelen
Consider acute triangle $ABC$. Denote $M$ as the midpoint of $AB$, and let $O$ be a point on segment $CM$ such that $\angle{AOB}=120^{\circ}$. Find the length of $CM$ given $AO=5, BO=8, \angle{BAC}=60^{\circ}$.
1 reply
Bluesoul
Apr 1, 2025
vanstraelen
Yesterday at 7:06 PM
J
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An inequality
jokehim   6
N Yesterday at 4:47 PM by imnotgoodatmathsorry
Let $a,b,c \in \mathbb{R}: a+b+c=3$ then prove $$\color{black}{\frac{a^2}{a^{2}-2a+3}+\frac{b^2}{b^{2}-2b+3}+\frac{c^2}{c^{2}-2c+3}\ge \frac{3}{2}.}$$
6 replies
jokehim
Mar 21, 2025
imnotgoodatmathsorry
Yesterday at 4:47 PM
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Geometry problem
Raul_S_Baz   2
N Yesterday at 4:13 PM by Raul_S_Baz
IMAGE
2 replies
Raul_S_Baz
Wednesday at 8:49 PM
Raul_S_Baz
Yesterday at 4:13 PM
J
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Cyclic inequality
JK1603JK   0
Yesterday at 3:40 PM
Given non-negative real numbers $a,b,c$ satisfying $ab+bc+ca=1.$ Prove that $$\frac{abc-1}{abc-2}\ge \frac{a^2b+b^2c+c^2a}{a^3b+b^3c+c^3a+1}.$$Equality holds at $a=b=1,c=0$ and its cyclic permutations.
0 replies
JK1603JK
Yesterday at 3:40 PM
0 replies
J
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Easy Problem
MathleteMystic   2
N Yesterday at 3:05 PM by Mathematicalprodigy37
Prove that among n integers we can always choose some of them whose sum is a multiple on n.

I do have a solution to this, but could someone write a more descriptive one, please? Something like the logic behind it...
2 replies
MathleteMystic
Yesterday at 1:20 PM
Mathematicalprodigy37
Yesterday at 3:05 PM
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J
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Indian Mathematical Olympiad 1988 - Problem 8
Leon   3
N Dec 1, 2010 by jonasrla
A river flows between two houses $ A$ and $ B$, the houses standing some distances away from the banks. Where should a bridge be built on the river so that a person going from $ A$ to $ B$, using the bridge to cross the river may do so by the shortest path? Assume that the banks of the river are straight and parallel, and the bridge must be perpendicular to the banks.
3 replies
Leon
Aug 14, 2009
jonasrla
Dec 1, 2010
J
Indian Mathematical Olympiad 1988 - Problem 8
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Reveal topic tags
vector
geometry proposed
geometry
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Leon
256 posts
Leon
#1 Aug 14, 2009, 12:08 PM • 2 Y
Y by Adventure10, Mango247
A river flows between two houses $ A$ and $ B$, the houses standing some distances away from the banks. Where should a bridge be built on the river so that a person going from $ A$ to $ B$, using the bridge to cross the river may do so by the shortest path? Assume that the banks of the river are straight and parallel, and the bridge must be perpendicular to the banks.
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Bugi
1857 posts
Bugi
#2 Aug 14, 2009, 12:35 PM • 2 Y
Y by Adventure10, Mango247
Translate A into C by vector $ \vec{PQ}$, where PQ is the bridge, with Q and B on one side of the river

Then the path is $ AP+PQ+QB=AC+CQ+QB\ge AQ+QB$, with equality when A,C,Q are collinear.

Construction: Construct C as described, one end of the bridge is intersection of straight path between C and B, other is easily derived.
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sumanguha
485 posts
sumanguha
#3 Dec 1, 2010, 4:15 AM • 1 Y
Y by Adventure10
let the river flows along y axis.

see where ever we create the bridge the person must go through a path (a polygonal path) which consists of three line segments of which the middle one has a constant length(wrt to the position of the bridge).
so enough to minimize the total length of the rest two segments.
it is then equivalent to the following question
we can squeeze the river so that two ends of the bridge coincides.then what is the shortest path from A to B ?
it is the line joining A and B.
let the perpendicular distance from river bank to A is $\ h_{A} $
let the perpendicular distance from river bank to A is $\ h_{B} $
let the horizontal distance between A and B is $\ h $
then consider a straight line starting from A which is inclined towards B (wrt x-axis) at an angle $\theta $
where $\theta= arctan(\frac{h}{h_{A}+h_{B}})$
let that line intersect the river bank at the point C.
create the bridge at the point C.
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jonasrla
36 posts
jonasrla
#4 Dec 1, 2010, 11:59 AM • 2 Y
Y by Adventure10, Mango247
See the drawing to understand my notations:

$l, a, b, X$ and $Y$ are constants. The distance changes as soon as m and n changes.
Assume that the mininal path is such that this relation is valid: $\frac{m}{a}=\frac{Y}{a+b}=\frac{n}{b}$

To prove it's mininal let's assume the oposite, there's a path shorter than the one I showed:

$\sqrt{a^2+(\frac{aY}{a+b})^2}+l+\sqrt{b^2+(\frac{bY}{a+b})^2}>\sqrt{a^2+m^2}+l+\sqrt{b^2+n^2} \Rightarrow \sqrt{(a+b)^2+Y^2}>\sqrt{a^2+m^2}+\sqrt{b^2+n^2} \\ \Rightarrow a^2+b^2+m^2+n^2+2ab+2mn>a^2+b^2+m^2+n^2+2\sqrt{a^2+m^2}\sqrt{b^2+n^2} \Rightarrow ab+mn> \sqrt{a^2+m^2}\sqrt{b^2+n^2} \\ \Rightarrow a^2 b^2+m^2 n^2+2abmn>a^2 b^2+m^2 n^2 + a^2 n^2+b^2 m^2 \Rightarrow (an-bm)^2<0$
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