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Z[x], P(\sqrt[3]5+\sqrt[3]25)=5+\sqrt[3]5
jasperE3   5
N 27 minutes ago by Assassino9931
Source: VJIMC 2013 2.3
Prove that there is no polynomial $P$ with integer coefficients such that $P\left(\sqrt[3]5+\sqrt[3]{25}\right)=5+\sqrt[3]5$.
5 replies
1 viewing
jasperE3
May 31, 2021
Assassino9931
27 minutes ago
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Putnam 1972 A2
sqrtX   2
N 4 hours ago by KAME06
Source: Putnam 1972
Let $S$ be a set with a binary operation $\ast$ such that
1) $a \ast(a\ast b)=b$ for all $a,b\in S$.
2) $(a\ast b)\ast b=a$ for all $a,b\in S$.
Show that $\ast$ is commutative and give an example where $\ast$ is not associative.
2 replies
sqrtX
Feb 17, 2022
KAME06
4 hours ago
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Limit with sin^2x
Quantum_fluctuations   7
N Today at 7:25 AM by P162008

Evaluate:

$\lim_{x \to 0} \left( 1^{1/\sin^2 x} + 2^{1/\sin^2 x} + 3^{1/\sin^2 x} + . . . + n^{1/\sin^2 x} \right)^{\sin^2 x}$
7 replies
Quantum_fluctuations
Apr 26, 2020
P162008
Today at 7:25 AM
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Decimal number defined recursively by digit sums modulo 10
fermion13pi   2
N Today at 7:20 AM by solyaris
Source: Competição Elon Lages Lima
Consider the real number written in decimal notation:
r = 0.235831...
where, starting from the third digit after the decimal point, each digit is equal to the remainder when the sum of the previous two digits is divided by 10.

Which of the following statements is true?

(a) (10⁶⁰ - 1).r is an integer
(b) (10²⁵ - 1).r is an integer
(c) (10¹⁷ - 1).r is an integer
(d) r is an irrational algebraic number
(e) r is an irrational transcendental number

(Recall that a complex number is called algebraic if it is a root of a non-zero polynomial with integer coefficients.)
2 replies
fermion13pi
Yesterday at 11:14 PM
solyaris
Today at 7:20 AM
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Integrable function: + and - on every subinterval.
SPQ   3
N Today at 7:06 AM by solyaris
Provide a function integrable on [a, b] such that f takes on positive and negative values on every subinterval (c, d) of [a, b]. Prove your function satisfies both conditions.
3 replies
SPQ
Today at 2:40 AM
solyaris
Today at 7:06 AM
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Putnam 1999 A4
djmathman   7
N Today at 7:05 AM by P162008
Sum the series \[\sum_{m=1}^\infty\sum_{n=1}^\infty\dfrac{m^2n}{3^m(n3^m+m3^n)}.\]
7 replies
djmathman
Dec 22, 2012
P162008
Today at 7:05 AM
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Find the greatest possible value of the expression
BEHZOD_UZ   1
N Today at 6:34 AM by alexheinis
Source: Yandex Uzbekistan Coding and Math Contest 2025
Let $a, b, c, d$ be complex numbers with $|a| \le 1, |b| \le 1, |c| \le 1, |d| \le 1$. Find the greatest possible value of the expression $$|ac+ad+bc-bd|.$$
1 reply
BEHZOD_UZ
Yesterday at 11:56 AM
alexheinis
Today at 6:34 AM
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Problem with lcm
snowhite   2
N Today at 6:21 AM by snowhite
Prove that $\underset{n\to \infty }{\mathop{\lim }}\,\sqrt[n]{lcm(1,2,3,...,n)}=e$
Please help me! Thank you!
2 replies
snowhite
Today at 5:19 AM
snowhite
Today at 6:21 AM
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combinatorics
Hello_Kitty   2
N Yesterday at 10:23 PM by Hello_Kitty
How many $100$ digit numbers are there
- not including the sequence $123$ ?
- not including the sequences $123$ and $231$ ?
2 replies
Hello_Kitty
Apr 17, 2025
Hello_Kitty
Yesterday at 10:23 PM
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Sequence of functions
Squeeze   2
N Yesterday at 10:22 PM by Hello_Kitty
Q) let $f_n:[-1,1)\to\mathbb{R}$ and $f_n(x)=x^{n}$ then is this uniformly convergence on $(0,1)$ comment on uniformly convergence on $[0,1]$ where in general it is should be uniformly convergence.

My I am trying with some contradicton method like chose $\epsilon=1$ and trying to solve$|f_n(a)-f(a)|<\epsilon=1$
Next take a in (0,1) and chose a= 2^1/N but not solution
How to solve like this way help.
2 replies
Squeeze
Apr 18, 2025
Hello_Kitty
Yesterday at 10:22 PM
J
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A in M2(prime), A=B^2 and det(B)=p^2
jasperE3   1
N Yesterday at 9:59 PM by KAME06
Source: VJIMC 2012 1.2
Determine all $2\times2$ integer matrices $A$ having the following properties:

$1.$ the entries of $A$ are (positive) prime numbers,
$2.$ there exists a $2\times2$ integer matrix $B$ such that $A=B^2$ and the determinant of $B$ is the square of a prime number.
1 reply
jasperE3
May 31, 2021
KAME06
Yesterday at 9:59 PM
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J
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R+ Functional Equation
Mathdreams   10
N Apr 15, 2025 by TestX01
Source: Nepal TST 2025, Problem 3
Find all functions $f : \mathbb{R}^+ \rightarrow \mathbb{R}^+$ such that \[f(f(x)) + xf(xy) = x + f(y)\]for all positive real numbers $x$ and $y$.

(Andrew Brahms, USA)
10 replies
Mathdreams
Apr 11, 2025
TestX01
Apr 15, 2025
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R+ Functional Equation
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Source: Nepal TST 2025, Problem 3
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Mathdreams
1466 posts
Mathdreams
#1 Apr 11, 2025, 1:27 PM • 1 Y
Y by khan.academy
Find all functions $f : \mathbb{R}^+ \rightarrow \mathbb{R}^+$ such that \[f(f(x)) + xf(xy) = x + f(y)\]for all positive real numbers $x$ and $y$.

(Andrew Brahms, USA)
This post has been edited 1 time. Last edited by Mathdreams, Apr 11, 2025, 1:28 PM
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megarnie
5593 posts
megarnie
#2 Apr 11, 2025, 1:46 PM • 4 Y
Y by khan.academy, KevinYang2.71, abrahms, Alex-131
The only solutions are $f(x) = \frac cx$ for some constant $c$ and $f\equiv 1$, which clearly work.

Let $P(x,y)$ be the given assertion. Clearly $1$ is the only constant solution, so assume $f$ is not constant.

Claim: $f$ is injective.
Proof: Suppose $f(a) = f(b)$ for some positive reals $a,b$.

$P(x,a)$ with $P(x,b)$ gives that $f(xa) = f(xb)$ for all $x \in \mathbb R^{+}$.

Now, $P(a,x)$ compared with $P(b,x)$ gives $af(ax) - a = b f(bx) - b$, so $a(f(ax) - 1) = b (f(bx) - 1)$. But, since $f(ax) = f(bx)$, we have \[ a(f(ax) - 1) = b(f(ax) - 1) \]Since $f$ isn't constant, we can choose $x$ where $f(ax) \ne 1$, so $a = b$. $\square$

$P(x, f(x)): f(f(x)) + xf(xf(x)) = x + f(f(x))$, so $xf(xf(x)) = x \implies f(xf(x)) = 1$.

$P(1, y): f(f(1)) = 1$.

Injectivity implies $xf(x) = f(1)$ for all $x$, so $f(x) = \frac{f(1)}{x}$, and setting $c = f(1)$ gives the desired result.
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pco
23508 posts
pco
#3 Apr 11, 2025, 3:08 PM • 4 Y
Y by khan.academy, Maksat_B, Sedro, abrahms
Mathdreams wrote:
Find all functions $f : \mathbb{R}^+ \rightarrow \mathbb{R}^+$ such that \[f(f(x)) + xf(xy) = x + f(y)\]for all positive real numbers $x$ and $y$.
Let $P(x,y)$ be the assertion $f(f(x))+xf(xy)=x+f(y)$
Let $c=f(1)$ and $d=f(2)$

Subtracting $P(x,1)$ from $P(x,2)$, we get $f(2x)=f(x)+\frac{d-c}x$
Subtracting $P(2,1)$ from $P(2,x)$, we get $f(2x)=d+\frac{f(x)-c}2$

Subtracting : $f(x)=2\frac{c-d}x+2d-c$

Plugging $f(x)=\frac ax+b$ in original equation, we get $(a,b)=(\text{anything},0)$ or $(0,1)$ and solutions :
$\boxed{\text{S1 : }f(x)=1\quad\forall x>0}$, which indeed fits

$\boxed{\text{S2 : }f(x)=\frac ax\quad\forall x>0}$, which indeed fits, whatever is $a>0$
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jasperE3
11236 posts
jasperE3
#4 Apr 11, 2025, 5:23 PM • 1 Y
Y by AlexCenteno2007
Let $P(x,y)$ be the assertion $f(f(x))+xf(xy)=x+f(y)$.
$P(x,f(x))\Rightarrow f(xf(x))=1$
$P(f(x),x)\Rightarrow f(f(f(x)))=f(x)$
$P(f(x),y)\Rightarrow f(x)f(yf(x))=f(y)$, in particular we have $f(f(x))=\frac{f(1)}{f(x)}$
$P(x,f(y))\Rightarrow xf(x)^2-(xf(y)+f(1))f(x)+f(y)f(1)=0\Rightarrow f(x)\in\left\{f(y),\frac{f(1)}x\right\}$ for each $x,y\in\mathbb R^+$ (we solved this as a quadratic in $f(x)$)
If $f(x)\ne\frac{f(1)}x$ for some $x$ then by varying $y$ over $\mathbb R^+$ we get that $f$ is constant, and testing, the only constant solution is $\boxed{f(x)=1}$ for all $x$.
Otherwise, $\boxed{f(x)=\frac cx}$ which works for any $c\in\mathbb R^+$.
This post has been edited 1 time. Last edited by jasperE3, Apr 11, 2025, 5:24 PM
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Tony_stark0094
65 posts
Tony_stark0094
#6 Apr 12, 2025, 12:35 AM
Y by
if $f \equiv c$ then $c$ must be $1$ further assume $f$ is not constant:
it's easy to get $f(f(1))=1$
and observe that $f$ is injective:
now $P(x,f(x)): f(f(x))+xf(xf(x))=x+f(f(x)) \implies f(xf(x))=1$
from injectivity $xf(x)=f(1) \implies f(x)=\frac {f(1)}{x}$
hence $f(x)=1 \forall x \in R$ and $f(x)=\frac {f(1)}{x} \forall x \in R$ are the only solutions
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jasperE3
11236 posts
jasperE3
#7 Apr 12, 2025, 1:17 AM
Y by
Tony_stark0094 wrote:
it's easy to get $f(f(1))=1$
and observe that $f$ is injective:

how?
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Tony_stark0094
65 posts
Tony_stark0094
#8 Apr 12, 2025, 1:59 AM
Y by
jasperE3 wrote:
Tony_stark0094 wrote:
it's easy to get $f(f(1))=1$
and observe that $f$ is injective:

how?

$P(1,1): f(f(1))+f(1)=1+f(1) \implies f(f(1))=1$
for injectivity assume $f(a)=f(b)$
then subtract $P(a,1)$ from $P(b,1)$
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jasperE3
11236 posts
jasperE3
#9 Apr 12, 2025, 2:29 AM
Y by
Tony_stark0094 wrote:
jasperE3 wrote:
Tony_stark0094 wrote:
it's easy to get $f(f(1))=1$
and observe that $f$ is injective:

how?

$P(1,1): f(f(1))+f(1)=1+f(1) \implies f(f(1))=1$
for injectivity assume $f(a)=f(b)$
then subtract $P(a,1)$ from $P(b,1)$

and what if $f(a)=f(b)=1$ (which is indeed the particular case $f(xf(x))=f(f(1))=1$ that you use injectivity for)
This post has been edited 1 time. Last edited by jasperE3, Apr 12, 2025, 7:35 AM
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ThatApollo777
73 posts
ThatApollo777
#10 Apr 12, 2025, 2:15 PM
Y by
Claim : the only solutions are $f(x) = 1$ and $f(x) = \frac{c}{x}$.
Pf : Its easy to check these work, we now show these are only solutions.

Claim 1: If $f$ is not injective, its identically $1$.
Let $P(x, y)$ be the assertion. $$P(1,1) \implies f(f(1)) = 1$$Assuming $f(a) = f(b)$ for $a \neq b$. Let $r = \frac{b}{a} \neq 1$. $$P(a, y) - P(b, y) \implies a(f(ay) - 1) = b(f(by)-1)$$Putting $y = \frac{f(1)}{a}$ we can conclude: $$f(rf(1)) = 1$$$$P(\frac{x}{f(1)}, f(1)) - P(\frac{x}{f(1)}, rf(1)) \implies f(x) = f(rx)$$$$P(x, \frac{t}{x}) - P(rx, \frac{t}{x}) \implies f(t) = 1$$Since $r \neq 1$.

Now, assuming $f$ is injective consider $$P(x, \frac{f(1)}{x}) : f(f(x)) = f(\frac{f(1)}{x}) \implies f(x) = \frac{f(1)}{x}$$
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cursed_tangent1434
597 posts
cursed_tangent1434
#11 Apr 15, 2025, 7:20 AM
Y by
The answers are $f(x) = 1$ for all $x\in \mathbb{R}^+$ and $f(x)= \frac{c}{x}$ for all $x\in \mathbb{R}^+$ for some fixed constant $c \in \mathbb{R}^+$. It’s easy to see that these functions satisfy the given equation. We now show these are the only solutions. Let $P(x,y)$ be the assertion that $f(f(x))+xf(xy)=x+f(y)$ for positive real numbers $x$ and $y$.

In what follows we assume that $f$ is not constant one. Say there does now exist some $x_0 \ne 1$ such that $f(x_0) \ne 1$ (i.e for all $x_0\ne 1$ we have $f(x_0)=1$). As $f$ is not constant one this indicates that $f(1) \ne 1$. Then, $P\left(x,\frac{1}{x}\right)$ yields,
\begin{align*} f(f(x)) + xf(1) &= x+f\left(\frac{1}{x}\right)\\ f(1) + xf(1) &= x+1 \\ (x+1)f(1) &= x+1 \end{align*}which is a clear contradiction since $x+1>0$ and $f(1) \ne 1$. Thus, there indeed exists some $x_0 \ne 1$ such that $f(x_0) \ne 1$. Now, $P(1,1)$ implies that
\[f(f(1))+f(1)=1+f(1)\]from which we have $f(f(1))=1$. We now make the following observation.

Claim : The function $f$ is injective.

Proof : We first show that it is injective at all points except 1. For this, note that if there exists $t_1 \ne t_2 $ such that $f(t_1) =f(t_2) \ne 1$. Then, $P(t_1,1)$ and $P(t_2,1)$ yeild,
\[f(f(t_1))+t_1f(t_1)=t_1+f(1)\]\[f(f(t_2))+t_2f(t_2)=t_2+f(1)\]whose difference implies
\[(t_1-t_2)f(t_1)=t_1-t_2\]which since $f(t_1) \ne 1$ implies that $t_1=t_2$ which is a contradiction. Hence, $f$ is indeed injective at all points except 1.

With this observation in hand, consider $x_0 \ne 1$ such that $f(x_0) \ne 1$ and $\alpha$ such that $f(\alpha)=1$. Then, from $P\left(x_0 , \frac{\alpha}{x_0}\right)$ we have
\begin{align*} f(f(x_0)) + x_0f(\alpha) &= x_0 + f\left(\frac{\alpha}{x_0}\right)\\ f(f(x_0)) &= f\left(\frac{\alpha}{x_0}\right) \end{align*}Now,
\[f(f(f(x_0))) = f\left(f\left(\frac{\alpha}{x_0}\right)\right)=f(x_0)\]which since $f(x_0) \ne 1$ implies $f(f(x_0))=x_0 \ne 1$. Thus,
\begin{align*} f(f(x_0)) &= f\left(\frac{\alpha}{x_0}\right)\\ f(x_0) &= \frac{\alpha}{x_0} \end{align*}In particular, if there exists $\alpha_1,\alpha_2 \in \mathbb{R}^+$ such that $f(\alpha_1)=f(\alpha_2)=1$ we have
\[\frac{\alpha_1}{x_0} = f(x_0) = \frac{\alpha_2}{x_0}\]which implies $\alpha_1=\alpha_2$ proving the claim.

Thus, $f$ is injective and
\[f(x) = \frac{f(1)}{x}\]for all $x \ne f(1)$ and $f(f(1))=1$. This implies that indeed $f(x) = \frac{c}{x}$ for some fixed constant $c \in \mathbb{R}^+$ as desired.
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TestX01
339 posts
TestX01
#12 Apr 15, 2025, 8:11 AM
Y by
cutie patootie problem

We claim either $f$ is one or $\frac{c}{x}$. These clearly work. Let $P(x,y)$ denote the assertion.
Firstly, $P(1,1)$ gives $f(f(1))=1$.
$P(x,1)$ yields $f(f(x))+xf(x)=x+f(1)$. Hence $f(f(x))=xf(1)-xf(x)$. Thus, subbing back, $xf(xy)+f(1)-xf(x)=f(y)$. Now take $x\to f(1)$ so we get
\[f(1)f(f(1)y)=f(y)\]Now, we will take $y\to f(1)y$ in $xf(xy)+f(1)-xf(x)=f(y)$ to get $\frac{xf(xy)}{f(1)}+f(1)-xf(x)=\frac{f(y)}{f(1)}$. Comparing this with $xf(xy)+f(1)-xf(x)=f(y)$, we have
\[xf(xy)\left(\frac{1}{f(1)}-1\right)=f(y)\left(\frac{1}{f(1)}-1\right)\]This gives us two cases. Either $f(1)=1$ or $xf(xy)=f(y)$ for all $x,y$. In the latter case, we would have $xf(x)=f(1)$, and $f(x)=\frac{c}{x}$ which is a solution.

Now, suppose $f(1)=1$. Then, taking $P\left(x,\frac{1}{x}\right)$, we have $f(f(x))+x=x+f\left(\frac{1}{x}\right)$ hence $f(f(x))=f\left(\frac{1}{x}\right)$. Assume that $f$ is not always constant, as if it was constant then we would have $cx=x$ hence $c=1$ as desired. We shall prove that $f$ is injective, which would finish as then cancelling one $f$ we get $f(x)=\frac{1}{x}$.

Let $f(a)=f(b)$ such that WLOG $\frac{b}{a}>1$. Take $y=a,b$, so we have $f(f(x))+xf(ax)=x+f(a)$ and $f(f(x))+xf(bx)=x+f(b)$. Subtracting we have
\[x(f(ax)-f(bx))=f(a)-f(b)=0\]Hence, as $x\neq 0$, we have
\[f(ax)=f(bx)\quad f(x)=f(cx)\]where $c=\frac{b}{a}>1$ by scaling down $x$.

Now, consider $P(cx,y)$ so we get $f(f(x))+cxf(xy)=cx+f(y)$. Comparing with $P(x,y)$ we have
\[xf(xy)(c-1)=x(c-1)\]Yet $c-1>0$. Thus, we have $xf(xy)=x$ or $f(xy)=1$. Taking $y=1$ gives $f(x)=1$ for all $x$, a contradiction as we have dealt with constant $f$.

Thus, $f$ must be injective, and we are done.
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