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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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A number theory problem
super1978   0
8 minutes ago
Source: Somewhere
Let $a,b,n$ be positive integers such that $\sqrt[n]{a}+\sqrt[n]{b}$ is an integer. Prove that $a,b$ are both the $n$th power of $2$ positive integers.
0 replies
super1978
8 minutes ago
0 replies
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A bit tricky invariant with 98 numbers on the board.
Nuran2010   3
N 17 minutes ago by Nuran2010
Source: Azerbaijan Al-Khwarizmi IJMO TST 2025
The numbers $\frac{50}{1},\frac{50}{2},...\frac{50}{97},\frac{50}{98}$ are written on the board.In each step,two random numbers $a$ and $b$ are chosen and deleted.Then,the number $2ab-a-b+1$ is written instead.What will be the number remained on the board after the last step.
3 replies
Nuran2010
5 hours ago
Nuran2010
17 minutes ago
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A irreducible polynomial
super1978   0
18 minutes ago
Source: Somewhere
Let $f(x)=a_{n}x^n+a_{n-1}x^{n-1}+...+a_{1}x+a_0$ such that $|a_0|$ is a prime number and $|a_0|\geq|a_n|+|a_{n-1}|+...+|a_1|$. Prove that $f(x)$ is irreducible over $\mathbb{Z}[x]$.
0 replies
super1978
18 minutes ago
0 replies
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(2^n + 1)/n^2 is an integer (IMO 1990 Problem 3)
orl   107
N 28 minutes ago by Rayvhs
Source: IMO 1990, Day 1, Problem 3, IMO ShortList 1990, Problem 23 (ROM 5)
Determine all integers $ n > 1$ such that
\[ \frac {2^n + 1}{n^2} \]is an integer.
107 replies
orl
Nov 11, 2005
Rayvhs
28 minutes ago
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ISI UGB 2025 P1
SomeonecoolLovesMaths   4
N 2 hours ago by ZeroAlephZeta
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 $x_0 \in \mathbb{R}$, $f \left( x_0 \right) = x_0$.
4 replies
1 viewing
SomeonecoolLovesMaths
5 hours ago
ZeroAlephZeta
2 hours ago
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UC Berkeley Integration Bee 2025 Bracket Rounds
Silver08   11
N 3 hours ago by quasar_lord
Regular Round

Quarterfinals

Semifinals

3rd Place Match

Finals
11 replies
1 viewing
Silver08
May 9, 2025
quasar_lord
3 hours ago
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nice integral
Martin.s   1
N 4 hours ago by ysharifi
$$ \int_{0}^{\infty} \ln(2t) \ln(\tanh t) \, dt $$
1 reply
Martin.s
Today at 10:33 AM
ysharifi
4 hours ago
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D1028 : A strange result about linear algebra
Dattier   2
N 6 hours ago by ysharifi
Source: les dattes à Dattier
Let $p>3$ a prime number, with $H \subset M_p(\mathbb R), \dim(H)\geq 2$ and $H-\{0\} \subset GL_p(\mathbb R)$, $H$ vector space.

Is it true that $H-\{0\}$ is a group?
2 replies
Dattier
Yesterday at 1:49 PM
ysharifi
6 hours ago
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Mathematical expectation 1
Tricky123   0
Today at 9:51 AM
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
0 replies
Tricky123
Today at 9:51 AM
0 replies
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Double integrals
fermion13pi   1
N Today at 8:11 AM by Svyatoslav
Source: Apostol, vol 2
Evaluate the double integral by converting to polar coordinates:

\[ \int_0^1 \int_{x^2}^x (x^2 + y^2)^{-1/2} \, dy \, dx \]
Change the order of integration and then convert to polar coordinates.

1 reply
fermion13pi
Yesterday at 1:58 PM
Svyatoslav
Today at 8:11 AM
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Roots of a polynomial not in the disc of unity
Fatoushima   1
N Today at 7:59 AM by alexheinis
Show that the polynomial $p_n(z)=\sum_{k=1}^nkz^{n-k}$ has no roots in the disc of unity.
1 reply
Fatoushima
Today at 1:48 AM
alexheinis
Today at 7:59 AM
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Integration Bee Kaizo
Calcul8er   61
N Today at 6:36 AM by Svyatoslav
Hey integration fans. I decided to collate some of my favourite and most evil integrals I've written into one big integration bee problem set. I've been entering integration bees since 2017 and I've been really getting hands on with the writing side of things over the last couple of years. I hope you'll enjoy!
61 replies
Calcul8er
Mar 2, 2025
Svyatoslav
Today at 6:36 AM
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Japanese Olympiad
parkjungmin   2
N Today at 5:26 AM by parkjungmin
It's about the Japanese Olympiad

I can't solve it no matter how much I think about it.

If there are people who are good at math

Please help me.
2 replies
parkjungmin
Yesterday at 6:51 PM
parkjungmin
Today at 5:26 AM
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Japanese high school Olympiad.
parkjungmin   0
Today at 5:25 AM
It's about the Japanese high school Olympiad.

If there are any students who are good at math, try solving it.
0 replies
parkjungmin
Today at 5:25 AM
0 replies
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J
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Integral solutions
KDS   4
N Apr 10, 2025 by Maximilian113
Source: Romania TST 1993
Prove that the equation $ (x+y)^n=x^m+y^m$ has a unique solution in integers with $ x>y>0$ and $ m,n>1$.
4 replies
KDS
Jul 12, 2009
Maximilian113
Apr 10, 2025
J
Integral solutions
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number theory
diophantine
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Source: Romania TST 1993
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KDS
171 posts
KDS
#1 Jul 12, 2009, 10:45 AM • 1 Y
Y by Adventure10
Prove that the equation $ (x+y)^n=x^m+y^m$ has a unique solution in integers with $ x>y>0$ and $ m,n>1$.
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shoki
843 posts
shoki
#2 Aug 29, 2009, 11:57 PM • 2 Y
Y by Adventure10, Mango247
some hints
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IAmTheHazard
5001 posts
IAmTheHazard
#3 Apr 23, 2022, 6:08 PM • 3 Y
Y by Mango247, Mango247, Mango247
I will instead characterize every solution $(x,y,m,n)$ given that $x,y>0$ and $m,n \geq 1$this is the version of the problem I received.

Clearly $(x,y,m,n)=(x,y,1,1)$ works, and by size we require $n\geq m$ hence no other solution exists for $n=1$, so assume $n>1$. Then as a consequence of Zsigmondy there must exist some prime dividing $x^n+y^n$ that doesn't divide $x+y$ and thus $(x+y)^m$, unless:
  • $(x,y)=(k,2k)$ for some $k$, and $n=3$ hence $m \in \{1,2\}$. Then either $3k=9k^3$ which is impossible or $9k^2=9k^3 \implies k=1$, which yields $(x,y,m,n)=(1,2,2,3)$ and its permutation $(2,1,2,3)$.
  • $(x,y)=(k,k)$ for some $k$, so $2^mk^m=2k^n$ from which we find that $k$ must be a power of $2$, say $2^j$. Then
    $$2^{m+mj}=2^{nj+1} \implies j=\frac{m-1}{n-m},$$from which we extract the very ugly answer $\left(2^\frac{m-1}{n-m},2^\frac{m-1}{n-m},m,n\right)$ for all $(m,n)$ such that $n-m \mid m-1$.
Since everything is reversible, it follows that the solutions are $(x,y,m,n)=(x,y,1,1)$ $,(1,2,2,3),(2,1,2,3)$, and $\left(2^\frac{m-1}{n-m},2^\frac{m-1}{n-m},m,n\right)$ for all $(m,n)$ such that $n-m \mid m-1$. $\blacksquare$ (clearly, this implies the original problem)
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pinkpig
3761 posts
pinkpig
#4 Nov 15, 2023, 12:43 AM
Y by
probably wrong sol
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Maximilian113
575 posts
Maximilian113
#5 Apr 10, 2025, 3:22 AM
Y by
Nearly identical to #3, so this is for storage.
Quote:
Solve in positive integers the equation $$(x+y)^m=x^n+y^n.$$
Observe that $m=1 \iff n=1,$ and this clearly yields a solution. So assume that $m, n \geq 2.$ Observe that by size $n > m.$

Now, if $x=y=k$ we get $$2^nk^n=2k^m \iff k=2^{\frac{m-1}{n-m}},$$which indeed is a solution as long as $(n-m) | (m-1).$

WLOG assume that $x>y.$ Then let $d=\gcd(x, y), x=da, y=db.$ We get $$d^m(a+b)^m = d^n(a^n+b^n) \implies (a+b)^m = d^{n-m} (a^n+b^n).$$By Zsigmondy's Theorem there is prime dividing $a^n+b^n$ but not $a+b,$ which is a contradiction, unless we have $2^3+1$ in which $a=2, b=1, n=3.$ This would give $$3^m=d^{3-m} \cdot 9,$$and testing possibilities yields $m=2$ so $(x, y, m, n) = (1, 2, 2, 3), (2, 1, 2, 3).$

To summarize, the solutions are $$(x, y, m, n) = (x, y, 1, 1), (1, 2, 2, 3), (2, 1, 2, 3), \left( 2^{\frac{m-1}{n-m}}, 2^{\frac{m-1}{n-m}}, m, n \right)$$for $(m, n)$ that yields integer values for the last one.
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