Art of Problem Solving
AoPS Online AoPS Online
Math texts, online classes, and more
for students in grades 5-12.
Visit AoPS Online
Books for Grades 5-12 Online Courses
Beast Academy Beast Academy
Engaging math books and online learning
for students ages 6-13.
Visit Beast Academy
Books for Ages 6-13 Beast Academy Online
AoPS Academy AoPS Academy
Small live classes for advanced math
and language arts learners in grades 1-12.
Visit AoPS Academy
Find a Physical Campus Visit the Virtual Campus

Stay ahead of learning milestones! Enroll in a class over the summer!
No tags match your search
M
G
Topic
First Poster
Last Poster
H
k a April Highlights and 2025 AoPS Online Class Information
jlacosta   0
Apr 2, 2025
Spring is in full swing and summer is right around the corner, what are your plans? At AoPS Online our schedule has new classes starting now through July, so be sure to keep your skills sharp and be prepared for the Fall school year! Check out the schedule of upcoming classes below.

WOOT early bird pricing is in effect, don’t miss out! If you took MathWOOT Level 2 last year, no worries, it is all new problems this year! Our Worldwide Online Olympiad Training program is for high school level competitors. AoPS designed these courses to help our top students get the deep focus they need to succeed in their specific competition goals. Check out the details at this link for all our WOOT programs in math, computer science, chemistry, and physics.

Looking for summer camps in math and language arts? Be sure to check out the video-based summer camps offered at the Virtual Campus that are 2- to 4-weeks in duration. There are middle and high school competition math camps as well as Math Beasts camps that review key topics coupled with fun explorations covering areas such as graph theory (Math Beasts Camp 6), cryptography (Math Beasts Camp 7-8), and topology (Math Beasts Camp 8-9)!

Be sure to mark your calendars for the following events:
[list][*]April 3rd (Webinar), 4pm PT/7:00pm ET, Learning with AoPS: Perspectives from a Parent, Math Camp Instructor, and University Professor
[*]April 8th (Math Jam), 4:30pm PT/7:30pm ET, 2025 MATHCOUNTS State Discussion
April 9th (Webinar), 4:00pm PT/7:00pm ET, Learn about Video-based Summer Camps at the Virtual Campus
[*]April 10th (Math Jam), 4:30pm PT/7:30pm ET, 2025 MathILy and MathILy-Er Math Jam: Multibackwards Numbers
[*]April 22nd (Webinar), 4:00pm PT/7:00pm ET, Competitive Programming at AoPS (USACO).[/list]
Our full course list for upcoming classes is below:
All classes run 7:30pm-8:45pm ET/4:30pm - 5:45pm PT unless otherwise noted.

Introductory: Grades 5-10

Prealgebra 1 Self-Paced

Prealgebra 1
Sunday, Apr 13 - Aug 10
Tuesday, May 13 - Aug 26
Thursday, May 29 - Sep 11
Sunday, Jun 15 - Oct 12
Monday, Jun 30 - Oct 20
Wednesday, Jul 16 - Oct 29

Prealgebra 2 Self-Paced

Prealgebra 2
Sunday, Apr 13 - Aug 10
Wednesday, May 7 - Aug 20
Monday, Jun 2 - Sep 22
Sunday, Jun 29 - Oct 26
Friday, Jul 25 - Nov 21

Introduction to Algebra A Self-Paced

Introduction to Algebra A
Monday, Apr 7 - Jul 28
Sunday, May 11 - Sep 14 (1:00 - 2:30 pm ET/10:00 - 11:30 am PT)
Wednesday, May 14 - Aug 27
Friday, May 30 - Sep 26
Monday, Jun 2 - Sep 22
Sunday, Jun 15 - Oct 12
Thursday, Jun 26 - Oct 9
Tuesday, Jul 15 - Oct 28

Introduction to Counting & Probability Self-Paced

Introduction to Counting & Probability
Wednesday, Apr 16 - Jul 2
Thursday, May 15 - Jul 31
Sunday, Jun 1 - Aug 24
Thursday, Jun 12 - Aug 28
Wednesday, Jul 9 - Sep 24
Sunday, Jul 27 - Oct 19

Introduction to Number Theory
Thursday, Apr 17 - Jul 3
Friday, May 9 - Aug 1
Wednesday, May 21 - Aug 6
Monday, Jun 9 - Aug 25
Sunday, Jun 15 - Sep 14
Tuesday, Jul 15 - Sep 30

Introduction to Algebra B Self-Paced

Introduction to Algebra B
Wednesday, Apr 16 - Jul 30
Tuesday, May 6 - Aug 19
Wednesday, Jun 4 - Sep 17
Sunday, Jun 22 - Oct 19
Friday, Jul 18 - Nov 14

Introduction to Geometry
Wednesday, Apr 23 - Oct 1
Sunday, May 11 - Nov 9
Tuesday, May 20 - Oct 28
Monday, Jun 16 - Dec 8
Friday, Jun 20 - Jan 9
Sunday, Jun 29 - Jan 11
Monday, Jul 14 - Jan 19

Intermediate: Grades 8-12

Intermediate Algebra
Monday, Apr 21 - Oct 13
Sunday, Jun 1 - Nov 23
Tuesday, Jun 10 - Nov 18
Wednesday, Jun 25 - Dec 10
Sunday, Jul 13 - Jan 18
Thursday, Jul 24 - Jan 22

Intermediate Counting & Probability
Wednesday, May 21 - Sep 17
Sunday, Jun 22 - Nov 2

Intermediate Number Theory
Friday, Apr 11 - Jun 27
Sunday, Jun 1 - Aug 24
Wednesday, Jun 18 - Sep 3

Precalculus
Wednesday, Apr 9 - Sep 3
Friday, May 16 - Oct 24
Sunday, Jun 1 - Nov 9
Monday, Jun 30 - Dec 8

Advanced: Grades 9-12

Olympiad Geometry
Tuesday, Jun 10 - Aug 26

Calculus
Tuesday, May 27 - Nov 11
Wednesday, Jun 25 - Dec 17

Group Theory
Thursday, Jun 12 - Sep 11

Contest Preparation: Grades 6-12

MATHCOUNTS/AMC 8 Basics
Wednesday, Apr 16 - Jul 2
Friday, May 23 - Aug 15
Monday, Jun 2 - Aug 18
Thursday, Jun 12 - Aug 28
Sunday, Jun 22 - Sep 21
Tues & Thurs, Jul 8 - Aug 14 (meets twice a week!)

MATHCOUNTS/AMC 8 Advanced
Friday, Apr 11 - Jun 27
Sunday, May 11 - Aug 10
Tuesday, May 27 - Aug 12
Wednesday, Jun 11 - Aug 27
Sunday, Jun 22 - Sep 21
Tues & Thurs, Jul 8 - Aug 14 (meets twice a week!)

AMC 10 Problem Series
Friday, May 9 - Aug 1
Sunday, Jun 1 - Aug 24
Thursday, Jun 12 - Aug 28
Tuesday, Jun 17 - Sep 2
Sunday, Jun 22 - Sep 21 (1:00 - 2:30 pm ET/10:00 - 11:30 am PT)
Monday, Jun 23 - Sep 15
Tues & Thurs, Jul 8 - Aug 14 (meets twice a week!)

AMC 10 Final Fives
Sunday, May 11 - Jun 8
Tuesday, May 27 - Jun 17
Monday, Jun 30 - Jul 21

AMC 12 Problem Series
Tuesday, May 27 - Aug 12
Thursday, Jun 12 - Aug 28
Sunday, Jun 22 - Sep 21
Wednesday, Aug 6 - Oct 22

AMC 12 Final Fives
Sunday, May 18 - Jun 15

F=ma Problem Series
Wednesday, Jun 11 - Aug 27

WOOT Programs
Visit the pages linked for full schedule details for each of these programs!

MathWOOT Level 1
MathWOOT Level 2
ChemWOOT
CodeWOOT
PhysicsWOOT

Programming

Introduction to Programming with Python
Thursday, May 22 - Aug 7
Sunday, Jun 15 - Sep 14 (1:00 - 2:30 pm ET/10:00 - 11:30 am PT)
Tuesday, Jun 17 - Sep 2
Monday, Jun 30 - Sep 22

Intermediate Programming with Python
Sunday, Jun 1 - Aug 24
Monday, Jun 30 - Sep 22

USACO Bronze Problem Series
Tuesday, May 13 - Jul 29
Sunday, Jun 22 - Sep 1

Physics

Introduction to Physics
Wednesday, May 21 - Aug 6
Sunday, Jun 15 - Sep 14
Monday, Jun 23 - Sep 15

Physics 1: Mechanics
Thursday, May 22 - Oct 30
Monday, Jun 23 - Dec 15

Relativity
Sat & Sun, Apr 26 - Apr 27 (4:00 - 7:00 pm ET/1:00 - 4:00pm PT)
Mon, Tue, Wed & Thurs, Jun 23 - Jun 26 (meets every day of the week!)
0 replies
jlacosta
Apr 2, 2025
0 replies
J
H
k i Adding contests to the Contest Collections
dcouchman   1
N Apr 5, 2023 by v_Enhance
Want to help AoPS remain a valuable Olympiad resource? Help us add contests to AoPS's Contest Collections.

Find instructions and a list of contests to add here: https://artofproblemsolving.com/community/c40244h1064480_contests_to_add
1 reply
dcouchman
Sep 9, 2019
v_Enhance
Apr 5, 2023
J
H
k i Zero tolerance
ZetaX   49
N May 4, 2019 by NoDealsHere
Source: Use your common sense! (enough is enough)
Some users don't want to learn, some other simply ignore advises.
But please follow the following guideline:


To make it short: ALWAYS USE YOUR COMMON SENSE IF POSTING!
If you don't have common sense, don't post.


More specifically:

For new threads:


a) Good, meaningful title:
The title has to say what the problem is about in best way possible.
If that title occured already, it's definitely bad. And contest names aren't good either.
That's in fact a requirement for being able to search old problems.

Examples:
Bad titles:
- "Hard"/"Medium"/"Easy" (if you find it so cool how hard/easy it is, tell it in the post and use a title that tells us the problem)
- "Number Theory" (hey guy, guess why this forum's named that way¿ and is it the only such problem on earth¿)
- "Fibonacci" (there are millions of Fibonacci problems out there, all posted and named the same...)
- "Chinese TST 2003" (does this say anything about the problem¿)
Good titles:
- "On divisors of a³+2b³+4c³-6abc"
- "Number of solutions to x²+y²=6z²"
- "Fibonacci numbers are never squares"


b) Use search function:
Before posting a "new" problem spend at least two, better five, minutes to look if this problem was posted before. If it was, don't repost it. If you have anything important to say on topic, post it in one of the older threads.
If the thread is locked cause of this, use search function.

Update (by Amir Hossein). The best way to search for two keywords in AoPS is to input
[code]+"first keyword" +"second keyword"[/code]
so that any post containing both strings "first word" and "second form".


c) Good problem statement:
Some recent really bad post was:
[quote]$lim_{n\to 1}^{+\infty}\frac{1}{n}-lnn$[/quote]
It contains no question and no answer.
If you do this, too, you are on the best way to get your thread deleted. Write everything clearly, define where your variables come from (and define the "natural" numbers if used). Additionally read your post at least twice before submitting. After you sent it, read it again and use the Edit-Button if necessary to correct errors.


For answers to already existing threads:


d) Of any interest and with content:
Don't post things that are more trivial than completely obvious. For example, if the question is to solve $x^{3}+y^{3}=z^{3}$, do not answer with "$x=y=z=0$ is a solution" only. Either you post any kind of proof or at least something unexpected (like "$x=1337, y=481, z=42$ is the smallest solution). Someone that does not see that $x=y=z=0$ is a solution of the above without your post is completely wrong here, this is an IMO-level forum.
Similar, posting "I have solved this problem" but not posting anything else is not welcome; it even looks that you just want to show off what a genius you are.

e) Well written and checked answers:
Like c) for new threads, check your solutions at least twice for mistakes. And after sending, read it again and use the Edit-Button if necessary to correct errors.



To repeat it: ALWAYS USE YOUR COMMON SENSE IF POSTING!


Everything definitely out of range of common sense will be locked or deleted (exept for new users having less than about 42 posts, they are newbies and need/get some time to learn).

The above rules will be applied from next monday (5. march of 2007).
Feel free to discuss on this here.
49 replies
ZetaX
Feb 27, 2007
NoDealsHere
May 4, 2019
J
H
The smallest of sum of elements
hlminh   1
N 10 minutes ago by nguyenhuybao_06
Let $S=\{1,2,...,2014\}$ and $X\subset S$ such that for all $a,b\in X,$ if $a+b\leq 2014$ then $a+b\in X.$ Find the smallest of sum of all elements of $X.$
1 reply
hlminh
21 minutes ago
nguyenhuybao_06
10 minutes ago
J
H
Inequalities
Scientist10   0
18 minutes ago
If $x, y, z \in \mathbb{R}$, then prove that the following inequality holds:
\[ \sum_{\text{cyc}} \sqrt{1 + \left(x\sqrt{1 + y^2} + y\sqrt{1 + x^2}\right)^2} \geq \sum_{\text{cyc}} xy + 2\sum_{\text{cyc}} x \]
0 replies
Scientist10
18 minutes ago
0 replies
J
H
NT from ukr contest
mshtand1   3
N 18 minutes ago by ravengsd
Source: Ukrainian TST for RMM 2021(2) and EGMO 2022 P2
Find the greatest positive integer $n$ such that there exist positive integers $a_1, a_2, ..., a_n$ for which the following holds $a_{k+2} = \dfrac{(a_{k+1}+a_k)(a_{k+1}+1)}{a_k}$ for all $1 \le k \le n-2$.
Proposed by Mykhailo Shtandenko and Oleksii Masalitin
3 replies
mshtand1
Oct 2, 2021
ravengsd
18 minutes ago
J
H
Posted before ,but no solution
Nuran2010   1
N 18 minutes ago by Nuran2010
Source: 1220 Number Theory Problems
Find all positive integers $n$ where $49n^3+42n^2+11n+1$ is a perfect cube
1 reply
Nuran2010
Apr 11, 2025
Nuran2010
18 minutes ago
J
H
APMO 2012 #3
syk0526   30
N 32 minutes ago by EVKV
Source: APMO 2012 #3
Determine all the pairs $ (p , n )$ of a prime number $ p$ and a positive integer $ n$ for which $ \frac{ n^p + 1 }{p^n + 1} $ is an integer.
30 replies
syk0526
Apr 2, 2012
EVKV
32 minutes ago
J
H
Problem 1
SpectralS   146
N an hour ago by YaoAOPS
Given triangle $ABC$ the point $J$ is the centre of the excircle opposite the vertex $A.$ This excircle is tangent to the side $BC$ at $M$, and to the lines $AB$ and $AC$ at $K$ and $L$, respectively. The lines $LM$ and $BJ$ meet at $F$, and the lines $KM$ and $CJ$ meet at $G.$ Let $S$ be the point of intersection of the lines $AF$ and $BC$, and let $T$ be the point of intersection of the lines $AG$ and $BC.$ Prove that $M$ is the midpoint of $ST.$

(The excircle of $ABC$ opposite the vertex $A$ is the circle that is tangent to the line segment $BC$, to the ray $AB$ beyond $B$, and to the ray $AC$ beyond $C$.)

Proposed by Evangelos Psychas, Greece
146 replies
SpectralS
Jul 10, 2012
YaoAOPS
an hour ago
J
H
Number theory or function ?
matematikator   15
N an hour ago by YaoAOPS
Source: IMO ShortList 2004, algebra problem 3
Does there exist a function $s\colon \mathbb{Q} \rightarrow \{-1,1\}$ such that if $x$ and $y$ are distinct rational numbers satisfying ${xy=1}$ or ${x+y\in \{0,1\}}$, then ${s(x)s(y)=-1}$? Justify your answer.

Proposed by Dan Brown, Canada
15 replies
matematikator
Mar 18, 2005
YaoAOPS
an hour ago
J
H
hard problem
Cobedangiu   7
N an hour ago by arqady
Let $a,b,c>0$ and $a+b+c=3$. Prove that:
$\dfrac{4}{a+b}+\dfrac{4}{b+c}+\dfrac{4}{c+a} \le \dfrac{1}{a}+\dfrac{1}{b}+\dfrac{1}{c}+3$
7 replies
Cobedangiu
Apr 21, 2025
arqady
an hour ago
J
H
Bounding number of solutions for floor function equation
Ciobi_   1
N 2 hours ago by sarjinius
Source: Romania NMO 2025 9.3
Let $n \geq 2$ be a positive integer. Consider the following equation: \[ \{x\}+\{2x\}+ \dots + \{nx\} = \lfloor x \rfloor + \lfloor 2x \rfloor + \dots + \lfloor 2nx \rfloor\]a) For $n=2$, solve the given equation in $\mathbb{R}$.
b) Prove that, for any $n \geq 2$, the equation has at most $2$ real solutions.
1 reply
Ciobi_
Apr 2, 2025
sarjinius
2 hours ago
J
H
nice system of equations
outback   4
N 2 hours ago by Raj_singh1432
Solve in positive numbers the system

$ x_1+\frac{1}{x_2}=4, x_2+\frac{1}{x_3}=1, x_3+\frac{1}{x_4}=4, ..., x_{99}+\frac{1}{x_{100}}=4, x_{100}+\frac{1}{x_1}=1$
4 replies
outback
Oct 8, 2008
Raj_singh1432
2 hours ago
J
H
Two circles, a tangent line and a parallel
Valentin Vornicu   103
N 3 hours ago by zuat.e
Source: IMO 2000, Problem 1, IMO Shortlist 2000, G2
Two circles $ G_1$ and $ G_2$ intersect at two points $ M$ and $ N$. Let $ AB$ be the line tangent to these circles at $ A$ and $ B$, respectively, so that $ M$ lies closer to $ AB$ than $ N$. Let $ CD$ be the line parallel to $ AB$ and passing through the point $ M$, with $ C$ on $ G_1$ and $ D$ on $ G_2$. Lines $ AC$ and $ BD$ meet at $ E$; lines $ AN$ and $ CD$ meet at $ P$; lines $ BN$ and $ CD$ meet at $ Q$. Show that $ EP = EQ$.
103 replies
Valentin Vornicu
Oct 24, 2005
zuat.e
3 hours ago
J
H
Inequalities
idomybest   3
N 3 hours ago by damyan
Source: The Interesting Around Technical Analysis Three Variable Inequalities
The problem is in the attachment below.
3 replies
idomybest
Oct 15, 2021
damyan
3 hours ago
J
H
Function on positive integers with two inputs
Assassino9931   2
N 3 hours ago by Assassino9931
Source: Bulgaria Winter Competition 2025 Problem 10.4
The function $f: \mathbb{Z}_{>0} \times \mathbb{Z}_{>0} \to \mathbb{Z}_{>0}$ is such that $f(a,b) + f(b,c) = f(ac, b^2) + 1$ for any positive integers $a,b,c$. Assume there exists a positive integer $n$ such that $f(n, m) \leq f(n, m + 1)$ for all positive integers $m$. Determine all possible values of $f(2025, 2025)$.
2 replies
Assassino9931
Jan 27, 2025
Assassino9931
3 hours ago
J
H
Normal but good inequality
giangtruong13   4
N 3 hours ago by IceyCold
Source: From a province
Let $a,b,c> 0$ satisfy that $a+b+c=3abc$. Prove that: $$\sum_{cyc} \frac{ab}{3c+ab+abc} \geq \frac{3}{5} $$
4 replies
giangtruong13
Mar 31, 2025
IceyCold
3 hours ago
J
H
J
H
Find a given number of divisors of ab
proglote   9
N Mar 29, 2025 by zuat.e
Source: Brazil MO 2013, problem #2
Arnaldo and Bernaldo play the following game: given a fixed finite set of positive integers $A$ known by both players, Arnaldo picks a number $a \in A$ but doesn't tell it to anyone. Bernaldo thens pick an arbitrary positive integer $b$ (not necessarily in $A$). Then Arnaldo tells the number of divisors of $ab$. Show that Bernaldo can choose $b$ in a way that he can find out the number $a$ chosen by Arnaldo.
9 replies
proglote
Oct 24, 2013
zuat.e
Mar 29, 2025
J
Find a given number of divisors of ab
G H J
Reveal topic tags
combinatorics proposed
combinatorics
number theory
L
G H BBookmark kLocked kLocked NReply
Source: Brazil MO 2013, problem #2
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
proglote
958 posts
proglote
#1 Oct 24, 2013, 9:51 PM • 3 Y
Y by Davi-8191, Adventure10, Mango247
Arnaldo and Bernaldo play the following game: given a fixed finite set of positive integers $A$ known by both players, Arnaldo picks a number $a \in A$ but doesn't tell it to anyone. Bernaldo thens pick an arbitrary positive integer $b$ (not necessarily in $A$). Then Arnaldo tells the number of divisors of $ab$. Show that Bernaldo can choose $b$ in a way that he can find out the number $a$ chosen by Arnaldo.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
mavropnevma
15142 posts
mavropnevma
#2 Oct 24, 2013, 11:46 PM • 6 Y
Y by nikolapavlovic, test20, pablock, channing421, Adventure10, Mango247
Let us say the primes that divide at least one element from $A$ are $p_0,p_1,\ldots,p_k$. An element $a\in A$ can be represented then as $a=\prod_{j=0}^k p_j^{\alpha_j}$, with $\alpha_j \geq 0$. When $b=\prod_{j=0}^k p_j^{\beta_j}$, the number of divisors of $ab$ is $\tau(ab) = \prod_{j=0}^k (1+ \alpha_j + \beta_j)$. Let us plug in $\beta_j = x^{2^j}$; then $P(x) = \prod_{j=0}^k (1+\alpha_j + x^{2^j})$ is a polynomial in $x$ of degree $2^{k+1} - 1$, where the coefficient of $x^{2^{k+1} - 2^j - 1}$ is precisely $1+\alpha_j$. In fact, if we take $n > \prod_{j=0}^k (1+\alpha_j)$, then $P(n)$ is the writing in basis $n$ of some (huge) integer, and all "digits" can be determined, namely also the values $\alpha_j$. So all is left to do is to take $n > \prod_{j=0}^k (1+a_j)$, where $a_j = \max_{A} \alpha_j$, and $\beta_j = n^{2^j}$.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
nikolapavlovic
1246 posts
nikolapavlovic
#3 Feb 5, 2017, 3:02 PM • 2 Y
Y by Adventure10, Mango247
Let $\tau()$ denote the divisors counting function.All the numbers in $A$ can be represented as $\prod_{i=1}^n {p_i}^{\alpha_i}$ where n is finite and we allow $\alpha_i=0$.
Lemma:By multiplying all the numbers with $\prod_{i=1}^n p_i^N$ for large $N$ Arnaldo can assure that $\tau:A\rightarrow N$ becomes injective if it isn't already.
Proof:
We can asign a polynomial to $\forall a\in A$, $\tau(a\cdot \prod_{i=1}^n p_i^N)$ as $P(X)=\prod_{i=1}^n (X+\alpha_i+1+N)$ now as all vectors $(\alpha_1,\alpha_2,\dots ,\alpha_n)$ are different so are the asigned polys so they can sare values only finitely many times so as $A$ is finite by picking very large $N$ all polys will have different values at that point which implies the Lemma.

Now Arnaldo picks $b=\prod_{i=1}^n p_i^N$ and so Arnaldo finds out $\tau(a\cdot \prod_{i=1}^n p_i^N)$ and as $\tau$ is injective Arnaldo can findout $a\cdot \prod_{i=1}^n p_i^N$ and so we re done.
This post has been edited 3 times. Last edited by nikolapavlovic, Feb 5, 2017, 3:59 PM
Reason: droped q
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
bobthesmartypants
4337 posts
bobthesmartypants
#4 Feb 5, 2017, 7:21 PM • 2 Y
Y by Adventure10, Mango247
solution
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
randomusername
1059 posts
randomusername
#5 Feb 20, 2017, 9:06 AM • 3 Y
Y by ULTRABIG, Adventure10, Mango247
CRT method.

Let $P$ be the set of prime divisors of some $a\in A$, and let $E=\{v_p(a)|p\in P,a\in A\}$. Assign to each pair $(p,e)\in P\times E$ a unique prime number $q(p,e)>\max E+1$.

Now fix $p$. Choose $x_p$ by CRT in a way that
  • $q(p,e)|x_p+e+1$ for each $e\in E$,
  • $q(p',e)|x_p$ for any $p'\in P\setminus\{p\}$ and for each $e\in E$.
Then $x_p+e+1$ cannot be divisible by $q(p',e')$ for any $(p',e')\neq (p,e)$, because else $q(p',e')$ would divide an integer in $[1;\max E+1]$, a contradiction because we chose the $q$'s to be large enough.

Therefore, for $(p',e')$ and $(p,e)$ in $P\times E$, we have
\[ q(p',e')|x_p+e+1\qquad \Leftrightarrow \qquad (p',e')=(p,e). \]So letting $b=\prod_{p\in P}p^{x_p}$, for any $a=\prod_{p\in P}p^{e_p}$, the prime $q(p,e)$ divides
\[ d(ab)=\prod_{p\in P}(e_p+x_p+1) \]if and only if $(p,e)=(p,e_p)$ for some $p$. Thus, the set of primes $q(p,e)$ which divide $d(ab)$ uniquely determine the prime factorization of $a$.
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
guptaamitu1
656 posts
guptaamitu1
#6 Sep 29, 2021, 4:23 PM
Y by
If $|A| = 1$, we are easily done. So now assume $|A| \ge 2$. Consider set
$$P = \{p: p \text{ is a prime } ; ~ \exists ~ x,y \in A \text{ such that } v_p(x) \ne v_p(y) \}$$Let $P = \{p_1,p_2,\ldots,p_k\}$. Assume for the sake of contradiction that any $b = p_1^{\alpha_1} p_2^{\alpha_2} \cdots p_k^{\alpha_k}$ (where $\alpha_1,\alpha_2,\ldots,\alpha_k$ are non-negative integers) doesn't work . Define sets
$$S_i = \left\{\frac{v_{p_i}(x) + \alpha_i+1}{v_{p_i}(y) + \alpha_i+1}:x,y \in A ~;~ v_{p_i}(x) > v_{p_i}(y) \right\} ~~ \forall ~ i = 1,2,\ldots,k$$Choose $\alpha_1,\alpha_2,\ldots,\alpha_k$ such that
$$\Big(\min(S_i)\Big)^{\frac12} \ge \max(S_{i+1}) ~~ \forall ~ i =1,2,\ldots,k$$(this can be done by picking $\alpha_1$ randomly and after choosing $\alpha_i$ taking $\alpha_{i+1}$ to be large enough).
Now we can choose two numbers $a_1,a_2 \in A$ such that $a_1b,a_2b$ have the same number of divisors. This implies
$$\prod_{i=1}^k \Big(v_{p_i}(a_1) + \alpha_i + 1 \Big) = \prod_{i=1}^k \Big(v_{p_i}(a_2) + \alpha_i + 1 \Big)$$Let $t \in \{1,2,\ldots,k \}$ be least such that $v_{p_t}(a_1) \ne v_{p_t}(a_2)$ ($t$ must exist as $a_1 \ne a_2$). Wlog, $v_{p_t}(a_1) > v_{p_t}(a_2)$. Then,
$$\frac{v_{p_t}(a_1) + \alpha_t + 1}{v_{p_t}(a_2) + \alpha_t + 1} = \prod_{i=t+1}^k \frac{v_{p_i}(a_2) + \alpha_i + 1}{v_{p_i}(a_1) + \alpha_i + 1}$$But this is a contradiction as
$$\frac{v_{p_t}(a_1) + \alpha_t + 1}{v_{p_t}(a_2) + \alpha_t + 1} \ge S_t = S_t^{\frac12} \cdot S_t^{\frac14} \cdot S_t^\frac18 > \prod_{i=t+1}^k \max(S_i) \ge \prod_{i=t+1}^k \frac{v_{p_i}(a_2) + \alpha_i + 1}{v_{p_i}(a_1) + \alpha_i + 1}$$This completes the proof of the problem. $\blacksquare$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
IAmTheHazard
5001 posts
IAmTheHazard
#7 Sep 19, 2022, 3:34 PM
Y by
Suppose the primes dividing elements of $A$ are $p_1,\ldots,p_n$, where $n$ is finite as $A$ is finite. Then every element of $A$ can be represented as $\prod_{i=1}^n p_I^{e_i}$ where we allow $e_i=0$. If each $e_i$ is bounded above by $M/1000$ across every element of $A$, then I claim that taking
$$b=\prod_{i=1}^n p_i^{M^{M^i}-1}$$works, i.e. $\tau(ab)$ is injective across $a \in A$. Indeed suppose $\tau(xb)=\tau(yb)$, and pick the least $i$ such that $\nu_{p_i}(x) \neq \nu_{p_i}(y)$, which exists else $x=y$, and suppose $\nu_{p_i}(x)>\nu_{p_i}(y)$. The idea is to look at $\tfrac{\tau(xb)}{\tau(yb)}$. By the divisor count formula, $p_i$ contributes a factor of at least
$$\frac{M^{M^i}+M/1000}{M^{M^i}+(M/1000-1)}=1+\frac{1}{M^{M^i}+(M/1000-1)}:=X$$to this fraction. Thus
$$\prod_{j=i+1}^n \frac{\nu_{p_j}(yb)+1}{\nu_{p_j}(xb)+1} \geq X.$$On the other hand, we have
$$\frac{\nu_{p_j}(yb)+1}{\nu_{p_j}(xb)+1} \leq \frac{M^{M^j}+M/1000}{M^{M^j}}=1+\frac{M/1000}{M^{M^j}}.$$Since $M^{M^j}$ grows very quickly as $M \geq 1000$ (if each $e_i$ is zero the problem is trivial), the product of this over all $j>i$ must be less than $X$. More concretely (though not entirely), this product should be
$$1+\frac{M/1000}{M^{M^{i+1}}}+O\left(\frac{M/1000}{M^{M^{i+2}}}\right)=1+\frac{M/1000}{M^{M^{i+1}}}+O\left(\frac{1}{M^{M^{i+2}-1}}\right),$$which is "significantly" less than $X$ in terms of distance from $1$. Hence $\tau(ab)$ is injective as desired, so given the value of $\tau(ab)$ we can extract $a$ and we're done. $\blacksquare$
This post has been edited 1 time. Last edited by IAmTheHazard, Nov 27, 2022, 10:33 PM
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
thdnder
194 posts
thdnder
#9 Mar 10, 2024, 12:30 PM
Y by
Let $a_1, a_2, \dots, a_n$ be the numbers in the set $A$. Let $p_1, p_2, \dots, p_k$ be the primes that divide one of $a_1, a_2, \dots, a_n$ and finally let $N$ be the large enough number. We only have to choose $b$ such that $\tau(a_1b), \tau(a_2b), \dots, \tau(a_nb)$ are different numbers, then Bernaldo immediately points out the number Arnaldo chose. Take $b = p_1^{N}p_2^{N}\cdots p_k^{N}$. Then assume for some $a_i = p_1^{a_1}p_2^{a_2}\cdots p_k^{a_k}$ and $a_j = p_1^{b_1}p_2^{b_2}\cdots p_k^{a_k}$, we have $\tau(a_ib) = \tau(a_jb)$. Then we have $(N + 1 + a_1)(N + 1 + a_2) \cdots (N + 1 + a_k) = (N + 1 + b_1)(N + 1 + b_2) \cdots (N + 1 + b_k)$, which means that $N$ is the root of polynomial $(x + 1 + a_1)(x + 1 + a_2) \cdots (x + 1 + a_k) - (x + 1 + b_1)(x + 1 + b_2) \cdots (x + 1 + b_k)$, contradicting the fact that $N$ is sufficiently large. Thus we're done. $\blacksquare$
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
HamstPan38825
8857 posts
HamstPan38825
#10 Jan 3, 2025, 1:59 AM
Y by
We assume Bernaldo has a quantum supercomputer. Let $q_1, q_2, \dots, q_n$ be all the primes that divide some element of $N$. Suppose that for each prime $q_i$, the possible powers that $q_i$ appears in some $a \in A$ are given by $k_{i1}, k_{i2}, \dots, k_{i\ell_i}$. Consider a sequence of distinct large primes $p_{ij}$ for $1 \leq i \leq n$ and $1 \leq j \leq \ell_i$ for each such $i$.

We will construct $b$ by considering its $q_i$-adic valuation for each $i$. In particular, for $r_i = \nu_{q_i}(b)$, we will force $r_i \equiv -k_{ij}-1 \pmod{ p_{ij}}$ for each $j$ and $1$ mod any other prime $p$ in our sequence. It follows that if $p_{ij} \mid \nu_{q_i}(ab) + 1$, we must have exactly $k_{ij}$ factors of $q_i$ in $a$, and also vice versa; otherwise, we are by construction guaranteed to have $p_{ij} \nmid \nu_{q_i}(ab) + 1$ if the primes are sufficiently large.

It follows that by considering the prime factorization of $\prod_{i=1}^n \left(\nu_{q_i}(ab) + 1\right) = \tau(ab)$, we can determine $\nu_{q_i}(a)$ for every prime $q_i$. As the $q_i$ encompass all primes that divide some element of $A$, this fixes $a$. (Albeit, it would probably take Bernaldo some work.)
Z K Y
The post below has been deleted. Click to close.
This post has been deleted. Click here to see post.
zuat.e
43 posts
zuat.e
#11 Mar 29, 2025, 5:44 PM
Y by
Let $\{p_i\}(1\geq i\geq k)$ be all primes dividing elements of $A$ and define $T_i=\{\alpha_i:v_{p_i}(x)=\alpha_i\mbox{ with }x\in A\}$.
We construct $b=\prod_{i=1}^kp_i^{h_i}$ which satisfy that if $x\in T_j$, then $\exists p\mbox{ prime }\mid x +h_j$ and $p\nmid y+h_i+1$ for all $i$, where $y\in T_i$.
It suffices to show we can construct such $\{h_i\}$, since it would yield $d(ab)\neq d(cb)$ when $a\neq c$.
Suppose the elements of $T_i$ are $x_{i1}, x_{i2},\dots,x_{i\mid T_i\mid}$; then we can prove the existence of $h_{i1}$ in the following manner:
\[\left\{\begin{array}{ll} h_{i1}\equiv-x_{i1}-1\pmod{q_{i1}} \\ h_{i1}\equiv-x_{i2}-1\pmod{q_{i2}} \\ \dots\\ h_{i1}\equiv-x_{i\mid T_i\mid}-1\pmod{q_{i\mid T_i\mid}}\\ h_{i1}\not\equiv-(1+\{x_{i1}, x_{i2}, \dots, x_{i\mid T_i\mid}\}) \pmod{q_{jk}} \end{array}\right.\]for previous $j$ ($j<i$).
This always has solutions for big enough $q_{mn}$ by $CRT$.
This post has been edited 2 times. Last edited by zuat.e, Mar 29, 2025, 6:06 PM
Z K Y
N Quick Reply
G
H
=
a