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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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Finding Max!
goldeneagle   4
N 40 minutes ago by aidan0626
Source: Iran 3rd round 2013 - Algebra Exam - Problem 2
Real numbers $a_1 , a_2 , \dots, a_n$ add up to zero. Find the maximum of $a_1 x_1 + a_2 x_2 + \dots + a_n x_n$ in term of $a_i$'s, when $x_i$'s vary in real numbers such that $(x_1 - x_2)^2 + (x_2 - x_3)^2 + \dots + (x_{n-1} - x_n)^2 \leq 1$.
(15 points)
4 replies
goldeneagle
Sep 11, 2013
aidan0626
40 minutes ago
J
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Inequalities
produit   0
41 minutes ago
Find the lowest value of C for which there exists such sequence
1 = x_0 ⩾ x_1 ⩾ x_2 ⩾ . . . ⩾ x_n ⩾ . . .
that for any positive integer n
x_{0}^2/x_{1}+x_{1}^{2}/x_{2}+ . . . +x_{n}^2/x_{n+1}< C.
0 replies
produit
41 minutes ago
0 replies
J
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Easy Number Theory
math_comb01   38
N an hour ago by lakshya2009
Source: INMO 2024/3
Let $p$ be an odd prime and $a,b,c$ be integers so that the integers $$a^{2023}+b^{2023},\quad b^{2024}+c^{2024},\quad a^{2025}+c^{2025}$$are divisible by $p$.
Prove that $p$ divides each of $a,b,c$.
$\quad$
Proposed by Navilarekallu Tejaswi
38 replies
math_comb01
Jan 21, 2024
lakshya2009
an hour ago
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number of positive divisors is equal to n/5
falantrng   4
N an hour ago by Adywastaken
Source: Azerbaijan NMO 2024. Senior P2
Let $d(n)$ denote the number of positive divisors of the natural number $n$. Find all the natural numbers $n$ such that $$d(n) = \frac{n}{5}$$.
4 replies
falantrng
Jul 8, 2024
Adywastaken
an hour ago
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No more topics!
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Hard FE R^+
DNCT1   5
N Apr 21, 2025 by jasperE3
Find all functions $f:\mathbb{R^+}\to\mathbb{R^+}$ such that
$$f(3x+f(x)+y)=f(4x)+f(y)\quad\forall x,y\in\mathbb{R^+}$$
5 replies
DNCT1
Dec 30, 2020
jasperE3
Apr 21, 2025
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Hard FE R^+
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DNCT1
235 posts
DNCT1
#1 Dec 30, 2020, 12:45 PM • 2 Y
Y by toanhocmuonmau123, Mango247
Find all functions $f:\mathbb{R^+}\to\mathbb{R^+}$ such that
$$f(3x+f(x)+y)=f(4x)+f(y)\quad\forall x,y\in\mathbb{R^+}$$
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DNCT1
235 posts
DNCT1
#2 Dec 31, 2020, 1:29 AM • 2 Y
Y by Mango247, Mango247
I just can prove that $f(x)\geq x\quad\forall x\in\mathbb{R^+}.$ $\quad$ Any idea ?
This post has been edited 1 time. Last edited by DNCT1, Dec 31, 2020, 1:29 AM
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TuZo
19351 posts
TuZo
#3 Dec 31, 2020, 3:32 PM
Y by
DNCT1 wrote:
I just can prove that $f(x)\geq x\quad\forall x\in\mathbb{R^+}.$ $\quad$ Any idea ?

How you proved this?
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Mgh
60 posts
Mgh
#4 Dec 31, 2020, 4:22 PM
Y by
TuZo wrote:
DNCT1 wrote:
I just can prove that $f(x)\geq x\quad\forall x\in\mathbb{R^+}.$ $\quad$ Any idea ?

How you proved this?

Consider there is a positive integer x fod which $ x-f (x) $ is greter than zero, now $ p (x, x-f (x) $gives contradiction. I thinks it's good to write it:$ f (x)=x+g (x) $
This post has been edited 1 time. Last edited by Mgh, Dec 31, 2020, 4:23 PM
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DNCT1
235 posts
DNCT1
#5 Jan 1, 2021, 4:56 PM
Y by
Well, here's a solution which I have
Let $P(x,y)$ be the assertion of $f(3x+f(x)+y)=f(4x)+f(y)\quad\forall x,y\in\mathbb{R^+}$

Assume there exist $x_0\in\mathbb{R^+}$ such that $f(x_0)<x_0$ so
$$P(x_0,x_0-f(x_0))\implies f(x_0-f(x_0))=0\quad(\text{impossible})$$Hence we have $f(x)\geq x\quad\forall x\in\mathbb{R^+}$.

By $P(x,y)$ there exxists $a,b\in\mathbb{R^+}$ such that
$$f(x+a)=f(x)+b\quad\forall x\in\mathbb{R^+}.$$So we also have $f(x+na)=f(x)+nb\quad\forall x\in\mathbb{R^+},n\in\mathbb{N^+}$
$$P(x+a,y)\implies f(3x+3a+f(x)+b+y)=f(4x)+f(y)+4b\quad\forall x,y\in\mathbb{R^+}$$$$P(x,y+4a)\implies f(3x+f(x)+y+4a)=f(4x)+f(y)+4b\quad\forall x,y\in\mathbb{R^+}$$And by two equations we have
$$f(3x+3a+f(x)+b+y)=f(3x+f(x)+y+4a)\quad\forall x,y\in\mathbb{R^+}$$If $a\neq b$ we assume that $a<b$ and $y$ such that $y>4a+3+f(1)$
$$P(1,y-4a-3-f(1))\implies f(y)=f(y+b-a)\quad\forall y\in\mathbb{R^+},y>4a+3+f(1)$$Hence $f$ must be period $a-b$ with $x>4a+3+f(1)$ but we have $f(x)\geq x\quad\forall x\in\mathbb{R^+}$ that implies $f$ must be period $0$ (absurd).$\quad$ Hence $a=b$.
Otherwise we have $f(h)=f(h+n(b-a))\quad\forall n\in\mathbb{N^+}$ for some $h>4a+3+f(1)$ so $d=f(h)\geq h+n(b-a)$ so choose $n\in\mathbb{N^+}$ such that $n>\frac{d}{b-a}$ we get the contracdition.
And so we have
$$f(4x)=f(x)+3x\quad\forall x\in\mathbb{R^+}$$$P(x,y)$ becomes
$$f(f(x)+y)=f(x)+f(y)\quad\forall x,y\in\mathbb{R^+}$$$$P(x,y-3x)\implies f(f(x)+y)=f(4x)+f(y-3x)=f(x)+3x+f(y-3x)\quad\forall x,y\in\mathbb{R^+}, y>3x$$And so $$3x+f(y-3x)=f(y)\quad\forall x,y\in\mathbb{R^+}, y>3x$$$$\implies f(y)-f(y-x)=x\quad\forall x,y\in\mathbb{R^+}, y>x (1)$$Let $y\to x+1$ in $(1)$ we have $f$ is linear $\forall x>1$ or $f(x)=x+f(1)-1\quad\forall x>1$
By $(1)$ we let $(x,y)\to (1-x,1)$ we have $f(x)=x+f(1)-1\quad\forall 0<x<1$ and it's also true with $x=1$.
And so
$$\boxed{\text{Solution:}\quad f(x)=x+f(1)-1\quad\forall x\in\mathbb{R^+}}$$
This post has been edited 2 times. Last edited by DNCT1, Jan 1, 2021, 5:02 PM
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jasperE3
11317 posts
jasperE3
#6 Apr 21, 2025, 12:59 AM • 1 Y
Y by truongphatt2668
Let $P(x,y)$ be the assertion $f(3x+f(x)+y)=f(4x)+f(y)$.

Claim 1: $f(x)\ge x$ for all $x$
Suppose $f(u)<u$ for some $u$, then:
$P(u,u-f(u))\Rightarrow f(u-f(u))=0$ which is impossible.

Claim 2: if $f(x+a)=f(x)+b$ for all $x>0$, given some $a,b>0$, then $f(x+b)=f(x)+b$
Note that $f(x+na)=f(x)+nb$ for $n\in\mathbb N$, by simple induction. Then:
$P(x+a,y)\Rightarrow f(3x+f(x)+y+b)=f(4x)+f(y)+b$
$P(x,y+b)\Rightarrow f(3x+f(x)+y+b)=f(4x)+f(y+b)$
and the claim is proven.

Claim 3: $f$ is injective.
Suppose $f(a)=f(b)$ for some $a>b>0$.
$P(x,a)\Rightarrow f(3x+f(x)+a)=f(4x)+f(a)$
$P(x,b)\Rightarrow f(3x+f(x)+b)=f(4x)+f(a)$
Fix $x$ and apply claim $2$ to $P(x,y)$, we get $f(f(4x)+y)=f(4x)+f(y)$, which implies $f(f(x)+y)=f(x)+f(y)$. Then:
$$f(x)+f(3x+a)=f(3x+f(x)+a)=f(3x+f(x)+b)=f(x)+f(3x+b)$$so $f(3x+a)=f(3x+b)$. This transforms to $f(x+a-b)=f(x)$ for all $x>b$. Let $x>b$, then:
$P(x,y+a-b)\Rightarrow f(3x+f(x)+y)=f(3x+f(x)+y+a-b)=f(4x)+f(y+a-b)\Rightarrow f(y)=f(y+a-b)$ so $f$ is periodic in general
By induction, $f(x)=f(x+n(a-b))$ for $n\in\mathbb N$, but by Claim 1 we have:
$$f(x)\ge x+n(a-b),$$taking $n\to\infty$ gives a contradiction.

Finish:
Recall that $f(f(x)+y)=f(x)+f(y)$, so swapping $x,y$ and using injectivity gives $\boxed{f(x)=x+c}$ which works for any constant $c>0$.
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