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k a May Highlights and 2025 AoPS Online Class Information
jlacosta   0
May 1, 2025
May is an exciting month! National MATHCOUNTS is the second week of May in Washington D.C. and our Founder, Richard Rusczyk will be presenting a seminar, Preparing Strong Math Students for College and Careers, on May 11th.

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0 replies
jlacosta
May 1, 2025
0 replies
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Interesting inequalities
sqing   3
N 4 minutes ago by sqing
Source: Own
Let $ a,b,c,d\geq 0 , a+b+c+d \leq 4.$ Prove that
$$a(kbc+bd+cd) \leq \frac{64k}{27}$$$$a (b+c) (kb c+ b d+ c d) \leq \frac{27k}{4}$$Where $ k\geq 2. $
3 replies
sqing
Yesterday at 12:44 PM
sqing
4 minutes ago
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Functional equation with powers
tapir1729   14
N 7 minutes ago by Mathandski
Source: TSTST 2024, problem 6
Determine whether there exists a function $f: \mathbb{Z}_{> 0} \rightarrow \mathbb{Z}_{> 0}$ such that for all positive integers $m$ and $n$,
\[f(m+nf(m))=f(n)^m+2024! \cdot m.\]Jaedon Whyte
14 replies
tapir1729
Jun 24, 2024
Mathandski
7 minutes ago
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Inspired by lbh_qys
sqing   3
N 7 minutes ago by sqing
Source: Own
Let $ a, b $ be real numbers such that $ (a-3)(b-3)(a-b)\neq 0 $ and $ a + b =6 . $ Prove that
$$ \left( \frac{a+k-1}{b - 3} + \frac{b+k-1}{3 - a} + \frac{k+2}{a - b} \right)^2 + 2(a^2 + b^2 )\geq6(k+8)$$Where $ k\in N^+.$
3 replies
sqing
May 20, 2025
sqing
7 minutes ago
J
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Number theory for people who love theory
Assassino9931   2
N 41 minutes ago by MathLuis
Source: Bulgaria RMM TST 2019
Prove that there is no positive integer $n$ such that $2^n + 1$ divides $5^n-1$.
2 replies
Assassino9931
Jul 31, 2024
MathLuis
41 minutes ago
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How can I know the sequences's convergence value?
Madunglecha   5
N Yesterday at 10:50 AM by teomihai
What is the convergence value of the sequence??
(n^2)*ln(n+1/n)-n
5 replies
Madunglecha
Wednesday at 6:56 AM
teomihai
Yesterday at 10:50 AM
J
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Prove the statement
Butterfly   12
N Yesterday at 9:44 AM by oty
Given an infinite sequence $\{x_n\} \subseteq [0,1]$, there exists some constant $C$, for any $r>0$, among the sequence $x_n$ and $x_m$ could be chosen to satisfy $|n-m|\ge r $ and $|x_n-x_m|<\frac{C}{|n-m|}$.
12 replies
Butterfly
May 7, 2025
oty
Yesterday at 9:44 AM
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Classifying Math with Symbols Based on Behavior
Midevilgmer   2
N Yesterday at 4:06 AM by Midevilgmer
I have been working on a new math idea that prioritizes the behavior of numbers, equations, and expressions rather than their exact values. Numbers are described using symbols like P (Positive), N (Negative), Z (Zero), I (Imaginary), and D (Decimal). The goal is to create a system that uses symbols that allows you to perform operations like P*D and P+N and determine the behavioral outcomes based on the properties involved. For example, instead of identifying a number as 3, you would describe it as a positive, odd, whole, prime number, allowing you work with those traits individually or together. I would like to mention that I already have created an Addition, Subtraction, Multiplication, Division, Square Root, Exponent, and Factorial table that shows how these different behaviors work in basic operations. Finally, I want to mention that my current background includes a knowledge of geometry, algebra, and a very little amount of calculus. Any thoughts or ideas would be appreciated.
2 replies
Midevilgmer
Yesterday at 12:55 AM
Midevilgmer
Yesterday at 4:06 AM
J
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36x⁴ + 12x² - 36x + 13 > 0
fxandi   3
N Yesterday at 1:48 AM by fxandi
Prove that for any real $x \geq 0$ holds inequality $36x^4 + 12x^2 - 36x + 13 > 0.$
3 replies
fxandi
May 5, 2025
fxandi
Yesterday at 1:48 AM
J
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Weird integral
Martin.s   2
N Yesterday at 12:43 AM by ADus
\[ \int_{-\frac{\pi}{2}}^{\frac{\pi}{2}} \frac{1 - e^{-2} \cos\left(2\left(u + \tan u\right)\right)} {1 - 2e^{-2} \cos\left(2\left(u + \tan u\right)\right) + e^{-4}} \, \mathrm{d}u \]
2 replies
Martin.s
May 20, 2025
ADus
Yesterday at 12:43 AM
J
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IMC 2018 P4
ThE-dArK-lOrD   18
N Wednesday at 8:50 PM by jonh_malkovich
Source: IMC 2018 P4
Find all differentiable functions $f:(0,\infty) \to \mathbb{R}$ such that
$$f(b)-f(a)=(b-a)f’(\sqrt{ab}) \qquad \text{for all}\qquad a,b>0.$$
Proposed by Orif Ibrogimov, National University of Uzbekistan
18 replies
ThE-dArK-lOrD
Jul 24, 2018
jonh_malkovich
Wednesday at 8:50 PM
J
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convergence
Soupboy0   2
N Wednesday at 6:33 PM by fruitmonster97
If the function $\zeta(n) = \frac{1}{1^n}+\frac{1}{2^n}+\frac{1}{3^n}+....$ diverges for $n=1$ (harmonic sequence) but converges for $n=2$ because $\frac{\pi^2}{6}$, is there a value between $n=1$ and $n=2$ such that $\zeta(n)$ converges

(i dont know the answer could someone please help me)
2 replies
Soupboy0
Wednesday at 6:13 PM
fruitmonster97
Wednesday at 6:33 PM
J
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a^2=3a+2imatrix 2*2
zolfmark   3
N Wednesday at 2:00 PM by Mathzeus1024
A
matrix 2*2

A^2=3A+2i
A^3=mA+Li


i means identity matrix,

find constant m ، L
3 replies
zolfmark
Feb 23, 2019
Mathzeus1024
Wednesday at 2:00 PM
J
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polynomial having a simple root
FFA21   1
N Wednesday at 1:59 PM by Doru2718
Source: MSU algebra olympiad 2025 P4
$f(x)\in R[x]$ show that $f(x)+i$ has at least one root of multiplicity one
1 reply
FFA21
May 20, 2025
Doru2718
Wednesday at 1:59 PM
J
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non-solvable group has subgroup that is not isomorphic to any normal subgroup
FFA21   1
N Wednesday at 1:45 PM by Doru2718
Source: MSU algebra olympiad 2025 P7
Show that in every finite non-solvable group there is a subgroup that is not isomorphic to any normal subgroup
1 reply
FFA21
May 20, 2025
Doru2718
Wednesday at 1:45 PM
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J
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Triangle geometry, bisecting chords
darij grinberg   3
N Sep 1, 2004 by grobber
Source: BWM 2004, 2nd round, problem 3
Given two circles $k_1$ and $k_2$ which intersect at two different points $A$ and $B$. The tangent to the circle $k_2$ at the point $A$ meets the circle $k_1$ again at the point $C_1$. The tangent to the circle $k_1$ at the point $A$ meets the circle $k_2$ again at the point $C_2$. Finally, let the line $C_1C_2$ meet the circle $k_1$ in a point $D$ different from $C_1$ and $B$.

Prove that the line $BD$ bisects the chord $AC_2$.
3 replies
darij grinberg
Sep 1, 2004
grobber
Sep 1, 2004
J
Triangle geometry, bisecting chords
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Reveal topic tags
geometry
ratio
similar triangles
geometry proposed
L
G H BBookmark kLocked kLocked NReply
Source: BWM 2004, 2nd round, problem 3
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darij grinberg
6555 posts
darij grinberg
#1 Sep 1, 2004, 10:10 PM • 2 Y
Y by Adventure10, Mango247
Given two circles $k_1$ and $k_2$ which intersect at two different points $A$ and $B$. The tangent to the circle $k_2$ at the point $A$ meets the circle $k_1$ again at the point $C_1$. The tangent to the circle $k_1$ at the point $A$ meets the circle $k_2$ again at the point $C_2$. Finally, let the line $C_1C_2$ meet the circle $k_1$ in a point $D$ different from $C_1$ and $B$.

Prove that the line $BD$ bisects the chord $AC_2$.
This post has been edited 2 times. Last edited by darij grinberg, Oct 13, 2005, 11:16 AM
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juancarlos
161 posts
juancarlos
#2 Sep 1, 2004, 10:58 PM • 2 Y
Y by Adventure10, Mango247
Let $M$ be the point of intersection of the lines $BD$ and $AC_2$. We have to show that this point $M$ is the midpoint of the segment $AC_2$.
Now, $<C_1AB=<BC_2A=<BDC_2, <AC_1B=<BAC_2$, also: $MC_2B$ and $MDC_2$ are similar triangles: $MB.MD=MC_2^2$
As $AM$ is tangent to $k_1$: $AM^2=MB.MD$
Hence: $AM=MC_2$. QED.
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darij grinberg
6555 posts
darij grinberg
#3 Sep 1, 2004, 11:09 PM • 2 Y
Y by Adventure10, Mango247
This is a very nice proof.

Here is my solution (I know that there are many different solutions, I've myself found three or four, but this is the one I have submitted):

Let N and M be the midpoints of the chords $AC_1$ and $AC_2$, respectively. We will first show that the points A, B, N, M lie on one circle.

We will work with directed angles modulo 180°. Since the line $AC_2$ is the tangent to the circle $k_1$ at the point A, the tangent-chordal angle theorem yields $\measuredangle \left( AB;\;AC_{2}\right) =\measuredangle BC_{1}A$. In other words, $\measuredangle BAC_{2}=\measuredangle BC_{1}A$. Similarly, $\measuredangle BAC_{1}=\measuredangle BC_{2}A$, or, in other words, $\measuredangle BC_{2}A=\measuredangle BAC_{1}$. Together with $\measuredangle BAC_{2}=\measuredangle BC_{1}A$, this yields that the triangles $BAC_2$ and $BC_1A$ are directly similar. Now, corresponding points in directly similar triangles form equal angles. The points M and N are corresponding points in our two directly similar triangles $BAC_2$ and $BC_1A$, since M is the midpoint of the side $AC_2$ of the former triangle, while N is the midpoint of the side $C_1A$ of the latter one. Hence, $\measuredangle AMB=\measuredangle C_{1}NB$. But $\measuredangle C_{1}NB=\measuredangle ANB$. Thus, $\measuredangle AMB=\measuredangle ANB$, and it follows that the points A, B, N, M lie on one circle. This, in turn, yields $\measuredangle ABM=\measuredangle ANM$.

Now, since the points N and M are the midpoints of the sides $AC_1$ and $AC_2$ of triangle $AC_1C_2$, we have $NM\parallel C_{1}C_{2}$. Hence, $\measuredangle ANM=\measuredangle AC_{1}C_{2}$. Together with $\measuredangle ABM=\measuredangle ANM$, this gives $\measuredangle ABM=\measuredangle AC_{1}C_{2}$.

Now, since the points A, B, D, $C_1$ all lie on the circle $k_1$, we have $\measuredangle ABD=\measuredangle AC_{1}D$, so $\measuredangle ABD=\measuredangle AC_{1}D=\measuredangle AC_{1}C_{2}=\measuredangle ABM$. And this entails that the points B, D and M lie on one line. In other words, the line BD passes through the midpoint M of the chord $AC_2$, i. e. it bisects this chord. Qed..

By the way, this problem has already been posted at MathLinks.

Darij
This post has been edited 4 times. Last edited by darij grinberg, Oct 13, 2005, 10:41 AM
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grobber
7849 posts
grobber
#4 Sep 1, 2004, 11:45 PM • 2 Y
Y by Adventure10, Mango247
Let $d$ be the line through $D$ and parallel to $AC_2$. We have to show that $DC_1,d,DA,DB$ form a harmonic quadruple, and after working on this a bit we reduce it to $\frac{BC_1}{BA}=\frac{AC_2}{AC_1}$, which is easy to prove (it's in fact the ratio of the radii of the two circles).

Well, it's not that short, but this is the main idea :).
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