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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.

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0 replies
jlacosta
Apr 2, 2025
0 replies
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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
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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
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6 variable inequality
ChuongTk17   3
N 32 minutes ago by ChuongTk17
Source: Own
Given real numbers a,b,c,d,e,f in the interval [-1;1] and positive x,y,z,t such that $$2xya+2xzb+2xtc+2yzd+2yte+2ztf=x^2+y^2+z^2+t^2$$. Prove that: $$a+b+c+d+e+f \leq 2$$
3 replies
ChuongTk17
Nov 29, 2024
ChuongTk17
32 minutes ago
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Arbitrary point on BC and its relation with orthocenter
falantrng   25
N 43 minutes ago by EeEeRUT
Source: Balkan MO 2025 P2
In an acute-angled triangle \(ABC\), \(H\) be the orthocenter of it and \(D\) be any point on the side \(BC\). The points \(E, F\) are on the segments \(AB, AC\), respectively, such that the points \(A, B, D, F\) and \(A, C, D, E\) are cyclic. The segments \(BF\) and \(CE\) intersect at \(P.\) \(L\) is a point on \(HA\) such that \(LC\) is tangent to the circumcircle of triangle \(PBC\) at \(C.\) \(BH\) and \(CP\) intersect at \(X\). Prove that the points \(D, X, \) and \(L\) lie on the same line.

Proposed by Theoklitos Parayiou, Cyprus
25 replies
falantrng
Apr 27, 2025
EeEeRUT
43 minutes ago
J
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Hard inequality
JK1603JK   2
N an hour ago by arqady
Source: unknown?
Let $a,b,c\in R: abc\neq 0$ and $a+b+c=0$ then prove $$|\frac{a-b}{c}|+|\frac{b-c}{a}|+|\frac{c-a}{b}|\ge 6$$
2 replies
JK1603JK
2 hours ago
arqady
an hour ago
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BMO 2024 SL A5
MuradSafarli   2
N an hour ago by ja.


Let \(\mathbb{R}^+ = (0, \infty)\) be the set of positive real numbers.
Find all non-negative real numbers \(c \geq 0\) such that there exists a function \(f : \mathbb{R}^+ \to \mathbb{R}^+\) with the property:
\[ f(y^2f(x) + y + c) = xf(x+y^2) \]for all \(x, y \in \mathbb{R}^+\).

2 replies
MuradSafarli
Apr 27, 2025
ja.
an hour ago
J
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Something nice
KhuongTrang   29
N an hour ago by arqady
Source: own
Problem. Given $a,b,c$ be non-negative real numbers such that $ab+bc+ca=1.$ Prove that

$$\sqrt{a+1}+\sqrt{b+1}+\sqrt{c+1}\le 1+2\sqrt{a+b+c+abc}.$$
29 replies
KhuongTrang
Nov 1, 2023
arqady
an hour ago
J
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hard problem
Cobedangiu   15
N 2 hours ago by arqady
Let $a,b,c>0$ and $a+b+c=3$. Prove that:
$\dfrac{4}{a+b}+\dfrac{4}{b+c}+\dfrac{4}{c+a} \le \dfrac{1}{a}+\dfrac{1}{b}+\dfrac{1}{c}+3$
15 replies
Cobedangiu
Apr 21, 2025
arqady
2 hours ago
J
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One on reals
Rushil   30
N 2 hours ago by Maximilian113
Source: INMO 2001 Problem 3
If $a,b,c$ are positive real numbers such that $abc= 1$, Prove that \[ a^{b+c} b^{c+a} c^{a+b} \leq 1 . \]
30 replies
Rushil
Oct 10, 2005
Maximilian113
2 hours ago
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Bounding is hard
whatshisbucket   20
N 2 hours ago by torch
Source: ELMO 2018 #5, 2018 ELMO SL A2
Let $a_1,a_2,\dots,a_m$ be a finite sequence of positive integers. Prove that there exist nonnegative integers $b,c,$ and $N$ such that $$\left\lfloor \sum_{i=1}^m \sqrt{n+a_i} \right\rfloor =\left\lfloor \sqrt{bn+c} \right\rfloor$$holds for all integers $n>N.$

Proposed by Carl Schildkraut
20 replies
whatshisbucket
Jun 28, 2018
torch
2 hours ago
J
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Yet another domino problem
juckter   14
N 3 hours ago by math-olympiad-clown
Source: EGMO 2019 Problem 2
Let $n$ be a positive integer. Dominoes are placed on a $2n \times 2n$ board in such a way that every cell of the board is adjacent to exactly one cell covered by a domino. For each $n$, determine the largest number of dominoes that can be placed in this way.
(A domino is a tile of size $2 \times 1$ or $1 \times 2$. Dominoes are placed on the board in such a way that each domino covers exactly two cells of the board, and dominoes do not overlap. Two cells are said to be adjacent if they are different and share a common side.)
14 replies
juckter
Apr 9, 2019
math-olympiad-clown
3 hours ago
J
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BMO 2024 SL A3
MuradSafarli   6
N 3 hours ago by quacksaysduck

A3.
Find all triples \((a, b, c)\) of positive real numbers that satisfy the system:
\[ \begin{aligned} 11bc - 36b - 15c &= abc \\ 12ca - 10c - 28a &= abc \\ 13ab - 21a - 6b &= abc. \end{aligned} \]
6 replies
MuradSafarli
Apr 27, 2025
quacksaysduck
3 hours ago
J
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BMO 2024 SL A1
MuradSafarli   8
N 3 hours ago by ja.
A1.

Let \( u, v, w \) be positive reals. Prove that there is a cyclic permutation \( (x, y, z) \) of \( (u, v, w) \) such that the inequality:

\[ \frac{a}{xa + yb + zc} + \frac{b}{xb + yc + za} + \frac{c}{xc + ya + zb} \geq \frac{3}{x + y + z} \]
holds for all positive real numbers \( a, b \) and \( c \).
8 replies
MuradSafarli
Apr 27, 2025
ja.
3 hours ago
J
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Medium geometry with AH diameter circle
v_Enhance   94
N 4 hours ago by alexanderchew
Source: USA TSTST 2016 Problem 2, by Evan Chen
Let $ABC$ be a scalene triangle with orthocenter $H$ and circumcenter $O$. Denote by $M$, $N$ the midpoints of $\overline{AH}$, $\overline{BC}$. Suppose the circle $\gamma$ with diameter $\overline{AH}$ meets the circumcircle of $ABC$ at $G \neq A$, and meets line $AN$ at a point $Q \neq A$. The tangent to $\gamma$ at $G$ meets line $OM$ at $P$. Show that the circumcircles of $\triangle GNQ$ and $\triangle MBC$ intersect at a point $T$ on $\overline{PN}$.

Proposed by Evan Chen
94 replies
v_Enhance
Jun 28, 2016
alexanderchew
4 hours ago
J
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problem interesting
Cobedangiu   7
N 4 hours ago by vincentwant
Let $a=3k^2+3k+1 (a,k \in N)$
$i)$ Prove that: $a^2$ is the sum of $3$ square numbers
$ii)$ Let $b \vdots a$ and $b$ is the sum of $3$ square numbers. Prove that: $b^n$ is the sum of $3$ square numbers
7 replies
Cobedangiu
Yesterday at 5:06 AM
vincentwant
4 hours ago
J
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another problem
kjhgyuio   1
N 4 hours ago by lpieleanu
........
1 reply
kjhgyuio
5 hours ago
lpieleanu
4 hours ago
J
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J
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p divides (x-a)(x-b)(x-c)[(x-a)^i(x-b)^j(x-c)^k-1]
MellowMelon   21
N Apr 14, 2025 by Ilikeminecraft
Source: USA TST 2009 #8
Fix a prime number $ p > 5$. Let $ a,b,c$ be integers no two of which have their difference divisible by $ p$. Let $ i,j,k$ be nonnegative integers such that $ i + j + k$ is divisible by $ p - 1$. Suppose that for all integers $ x$, the quantity
\[ (x - a)(x - b)(x - c)[(x - a)^i(x - b)^j(x - c)^k - 1]\]
is divisible by $ p$. Prove that each of $ i,j,k$ must be divisible by $ p - 1$.

Kiran Kedlaya and Peter Shor.
21 replies
MellowMelon
Jul 18, 2009
Ilikeminecraft
Apr 14, 2025
J
p divides (x-a)(x-b)(x-c)[(x-a)^i(x-b)^j(x-c)^k-1]
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Reveal topic tags
modular arithmetic
algebra
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Source: USA TST 2009 #8
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MellowMelon
5850 posts
MellowMelon
#1 Jul 18, 2009, 10:44 PM • 5 Y
Y by Adventure10, jhu08, jmiao, Mango247, cubres
Fix a prime number $ p > 5$. Let $ a,b,c$ be integers no two of which have their difference divisible by $ p$. Let $ i,j,k$ be nonnegative integers such that $ i + j + k$ is divisible by $ p - 1$. Suppose that for all integers $ x$, the quantity
\[ (x - a)(x - b)(x - c)[(x - a)^i(x - b)^j(x - c)^k - 1]\]
is divisible by $ p$. Prove that each of $ i,j,k$ must be divisible by $ p - 1$.

Kiran Kedlaya and Peter Shor.
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JBrere
20 posts
JBrere
#2 Jul 20, 2009, 5:34 AM • 7 Y
Y by qua96, Adventure10, jhu08, jmiao, Mango247, cubres, and 1 other user
Our Equation
\[ (x - a)(x - b)(x - c)[(x - a)^i(x - b)^j(x - c)^k - 1]\]
is always $ 0 \pmod p$.

First we may assume that $ 0 \le i,j,k < p-1$ because if $ i,j,k$ any is greater than or equal to $ p-1$ we may replace it with $ i-p+1, j-p+1, k-p+1$, still preserving the value of $ i+j+k \pmod {p-1}$

Since these are each less than $ p-1$, $ i+j+k < 3(p-1)$

If $ i+j+k = 0$ then we are done. Assume for sake of contradiction they are not.

If $ i+j+k = 2(p-1)$ we substitute $ p-1-i, p-1-j, p-1-k$ for $ i,j,k$ and since this is the inverse of the previous expression $ \pmod p$, which is always $ 1 \pmod p$ for all $ x \ne a,b,c$, the whole polynomial is still $ 0 \pmod p$ for all integers.

So we can assume $ i+j+k = p-1$. Also since the equation is cyclic assume $ i \ge j, i \ge k$ and therefore $ i \ge {(p-1) \over 3}$

Also assume $ p>7$, we have
$ (x - a)(x - b)(x - c)[(x - a)^i(x - b)^j(x - c)^k - 1]$

$ = (x - a)(x - b)(x - c)[(x - a)^i(x - b)^j(x - c)^k - (x-a)^{p-1}]$

$ = (x - a)(x - b)(x - c)[(x-b)^j(x-c)^k - (x-a)^{j+k}]$
(We can divide out by all the repeated roots because the polynomial remains $ 0 \pmod p$ for all integers.)

Now this polynomial has degree $ \le {2p+7 \over 3}$ which for all $ p>7$ is less than $ p$ thus this polynomial (which is clearly not the 0 polynomial since $ a,b,c$ are distinct) has less than $ p$ roots $ \pmod p$ thus it is not $ 0 \pmod p$ for all integers $ x$.

For the $ p=7$ case the above argument holds for all cases except $ i=j=k=2$.
then we have \[ (x-a)(x-b)(x-c)[(x-b)^2(x-c)^2-(x-a)^4]\] Since the $ x^4$ term within the brackets vanishes the polynomial is of degree 6, and is clearly not the zero polynomial $ \pmod 7$. Contradiction
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Ahwingsecretagent
151 posts
Ahwingsecretagent
#3 Jul 21, 2009, 6:28 AM • 5 Y
Y by Adventure10, jhu08, jmiao, Mango247, cubres
Wonderful solution! Thank you. I was trying to use primitive roots which failed.
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anonymouslonely
1142 posts
anonymouslonely
#4 Mar 11, 2013, 5:10 PM • 6 Y
Y by Adventure10, jhu08, jmiao, Mango247, cubres, and 1 other user
in the field $ Z_{p} $ is still true that if $ f $ has a double root $ r $ then $ f'(r)=0 $? :maybe:
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goo
139 posts
goo
#5 Mar 14, 2013, 12:38 AM • 4 Y
Y by Adventure10, jhu08, Mango247, cubres
anonymouslonely wrote:
in the field $ Z_{p} $ is still true that if $ f $ has a double root $ r $ then $ f'(r)=0 $? :maybe:
Yes, this is true. It follows easily from the fact that the product-rule for derivatives works the same in $Z_p[x]$ as it works in $\mathbb{R}[x]$.
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subham1729
1479 posts
subham1729
#6 Apr 30, 2013, 7:12 AM • 4 Y
Y by Adventure10, jhu08, cubres, and 1 other user
Suppose $f(x)=(x-a)(x-b)(x-c)[(x-a)^i(x-b)^j(x-c)^k-1]$.Now putting $x=1,2,.....,p$ and calling $(t-a)\equiv a_t(mod p)$ and $(t-b)\equiv b_t (mod p)$ also $(t-c)\equiv c_t (mod p)$ we obtain $p|(a_t)(b_t)(c_t)[(a_t)^i(b_t)^j(c_t)^k-1]$ where $\{a_t\}=\{b_t\}=\{c_t\}=\{1,2,3,.....,p\}$. Now suppose $\{1,2,3,....,p\}=\{g^{a_1},g^{a_2},........,g^{a_p}\} (mod p)$. Also call $a_t \equiv g^{f_{1}(t)}(mod p )$ also $b_t\equiv g^{f_{2}(t)}(mod p )$ and $c_t\equiv g^{f_{3}(t)}(mod p )$ for all $1\leq t\leq p$.Now certainly we're getting $p-1|if_{1}(t)+jf_{2}(t)+kf_{3}(t)$ for all such $t$.Now $WOLG$ assume $i\geq j\geq k$. Also note as we've $i+j\equiv -k (mod (p-1))$ so we get $p-1|mf_{2}(t)+nf_{3}(t)$ for all such $t$ with $m=i-j,n=i-k$. Now consider a mapping where if $f_{2}(t)=h$ then $f_{3}(t)=X(h)$ for all $1\leq h\leq p$. Thus now for all $h$ we've $p-1|hx+yX(h)$. Now so we've if $p-1$ doesn't divide $y$ then $p-1|(k-1)X(k)-kX(k-1)$ also so, $p-1|X_{p-1}-(p-1)X(1)$.Now basically just summing we obtain $\frac{p(p-1)}{2}-Xp\equiv \frac{p(p-1)}{2} X(1) (mod p)$ and so $p|Xp$.Now note $p-1|pX_{p-1}-p(p-1)$ and obviously so $X_{p-1}=p-1$. Now similarly going on we get $X_{i}=i$ for all $1\leq i\leq p$ if our $y$ is not divisible by $p$.Now as $p>5$ so we can chose a odd prime $q<p$ .Now so we've $p-1|q(x+y)$ but that implies $p-1|x+y$ since $q$ is odd and $gcd(p-1,q)=1$. And hence $p-1|i+j-2k$ also we've $p-1|i+j+k$ and so finally we get $p-1$ divides all of $i,j,k$.
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anantmudgal09
1980 posts
anantmudgal09
#7 Aug 13, 2016, 5:47 PM • 3 Y
Y by Adventure10, jhu08, cubres
Solution. By Fermat's Little Theorem (from here one, we will call it FLT) we see that only considering the residue classes of $i,j,k$ modulo $p-1$ doesn't affect the congruence. Thus, we may assume that $i,j,k$ are in the set $\{0,1,\dots, p-2\}$. Now, $i+j+k < 3(p-1)$ and so the only possible cases are $i+j+k \in \{0,p-1,2(p-1)\}$. In the case when the sum vanishes, we are done. If the sum is $2(p-1)$, we can consider the triple obtained by removing $i,j,k$ from $p-1$ (ensured by FLT). In any case, we may assume that $i+j+k=p-1$. Now the congruence equation \begin{align*} (x-a)^i(x-b)^j(x-c)^k=1 \end{align*}is given to have $p-3$ solutions in the domain $F_p[X]$. Assume that $i$ is the largest of the three exponents. This, by the FLT, boils down to the equation \begin{align*} (x-b)^j(x-c)^k-(x-a)^{j+k} =0 \end{align*}having $p-3$ solutions. This equation is not an identity (distinct variables etc) and has degree at most $j+k-1 \le \frac{2(p-1)}{3}-1$ (leading coefficient vanishes). However, by Lagrange's theorem, this shows that $p-3 \le \frac{2(p-1)}{3}-1$, which clearly fails for $p \ge 7$. The result follows.
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MarkBcc168
1595 posts
MarkBcc168
#8 Oct 19, 2017, 9:34 AM • 4 Y
Y by tenplusten, Adventure10, jhu08, cubres
When you forgot Lagrange's Theorem.

Crazy Solution
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yayups
1614 posts
yayups
#9 Feb 18, 2019, 5:56 AM • 5 Y
Y by pavel kozlov, Adventure10, jhu08, Mango247, cubres
bad solution:

Removing the fluff, what we are given is that
\[(x-a)^i(x-b)^j(x-c)^k\equiv 1\pmod{p}\]for all $x\in\mathbb{F}_p\setminus\{a,b,c\}$. Also, we might as well take the $i,j,k$ mod $p-1$ because of Fermat's little theorem. Furthermore, we may send $(i,j,k)\to(-i,-j,-k)$ if we wish to becauase $1^{-1}\equiv 1\pmod{p}$.

By taking mod $p-1$, we may assume WLOG that $0\le i\le j\le k\le p-2$. We see that $i+j+k=0,p-1,2(p-1)$ since $p-1\mid i+j+k$. If $i+j+k=0$, we're actually done, so for sake of contradiction, suppose not. Now, if $i+j+k=2(p-1)$, then send $(i,j,k)\to(p-1-k,p-1-j,p-1-i)\pmod{p-1}$. So potentially re-ordering again, we may assume $0\le i\le j\le k\le p-2$, and $i+j+k=p-1$. Finally, send $k\to k-(p-1)$, so now we have $0\le|i|,|j|,|k|\le p-2$, $i,j\ge 0$, and $-k=i+j$.

Thus, we have
\[(x-a)^i(x-b)^j\equiv(x-c)^{i+j}\pmod{p}\]for all $x\not\equiv a,b,c\pmod{p}$. Let $P(x)=(x-a)^i(x-b)^j-(x-c)^{i+j}$.By letting $x=a$, we see that this polynomial is not identically $0$ (here we are working over $\mathbb{F}_p$). Thus, $1\le\deg P\le k-1$, but $P(x)$ has $p-3$ roots (which are $\mathbb{F}_p\setminus\{a,b,c\}$). Therefore, $P(x)$ factors into $p-3$ linear factors, so in fact $p-3\le k-1$. But $k-1\le p-3$, so in fact $p-3=k-1$, so $k=p-2$. It is not hard to see that this means
\[(x-a)^i(x-b)^{1-i}(x-c)^{-1}\equiv 1\pmod{p}\]for all $x\not\equiv a,b,c\pmod{p}$. Thus, $(x-a)^i-(x-b)^{i-1}(x-c)\equiv 0\pmod{p}$ for all $x\not\equiv a,b,c\pmod{p}$, so by similar logic to above, we have $i-1\ge p-3$, so $i=p-2$ as well.

So we have $i=k=-1$, so $j=2$. Thus,
\[(x-b)^2\equiv (x-a)(x-c)\pmod{p}\]for all $x\not\equiv a,b,c\pmod{p}$, so $-2bx+b^2\equiv -(a+c)x+ac\pmod{p}$ for those same $x$ values. If $p>5$, we must then have that $2b\equiv a+c\pmod{p}$ and $b^2\equiv ac\pmod{p}$. Therefore,
\[(a-c)^2=(a+c)^2-4ac\equiv 4b^2-4b^2\equiv 0\pmod{p},\]so $a\equiv c\pmod{p}$, which is the desired contradiction. $\blacksquare$
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pinetree1
1207 posts
pinetree1
#10 Apr 13, 2019, 12:15 AM • 4 Y
Y by Adventure10, jhu08, Mango247, cubres
Here's a cleaner finish than using Lagrange.

First we may assume that $i, j, k < p-1$ by FLT, so $i+j+k\in \{0, p-1, 2(p-1)\}$.
  • If $i+j+k = 0$, we're done.
  • If $i+j+k = 2(p-1)$, send $i\to (p-1)-i$ (and similarly for $j$ and $k$) so that $i+j+k=p-1$. This does not affect the hypothesis by FLT.
Hence we can assume $i+j+k=p-1$. Let
$$f(x) = (x-a)^i(x-b)^j(x-c)^k - 1,$$so by hypothesis $f$ vanishes everywhere except at $a, b, c$. This implies $\sum_{x=0}^{p-1} f(x) \equiv -3\pmod p$.

However, $f$ is monic with degree $p-1$, and thus $\sum_{x=0}^{p-1} f(x) \equiv -1\pmod p$, contradiction.

Here are the details for the last step. If we let $g = f-x^{p-1}$ have degree less than $p-1$, we can write
$$\sum_{x=0}^{p-1} f(x) = \sum_{x=0}^{p-1} x^{p-1} + \sum_{x=0}^{p-1} g(x) \equiv -1\pmod p,$$where we are using the fact that if a polynomial $P$ has degree less than $p-1$, then $\sum_x P(x) \equiv 0\pmod p$. Of course this follows from the fact that
$$1^k+2^k+\dots +(p-1)^k\equiv 0\pmod p$$if $p-1\nmid k$.
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math_pi_rate
1218 posts
math_pi_rate
#11 Apr 13, 2019, 7:40 AM • 4 Y
Y by Adventure10, jhu08, Mango247, cubres
Nice problem! The idea involved is truly magnificent. Here's my solution: If $i \geq p-1$, then replace $i \rightarrow i-(p-1)$, and note that the given condition remains invariant due to Fermat's Little Theorem. So WLOG assume that $0 \leq i,j,k \leq p-2$ (from now on we will take $i,j,k$ modulo $p-1$). Then we have $i+j+k=0,p-1,2(p-1)$. If $i+j+k=0$, then we must have $i,j,k=0$, which is what we needed. If $i+j+k=2(p-1)$, then replace $i \rightarrow p-1-i$, and similarly for others, to get the same condition (again with the help of FLT). So we can assume that $i+j+k=p-1$ and $0 \leq i,j,k \leq p-2$.

Now, the given condition is equivalent to saying that $$(x-a)^i(x-b)^j(x-c)^k \equiv 1 \pmod{p} \text{ } \forall x \in \mathbb{F}_p \setminus \{a,b,c\}$$$$\Rightarrow (x-a)^i(x-b)^j \equiv (x-c)^{i+j} \pmod{p} \text{ } \forall x \in \mathbb{F}_p \setminus \{a,b,c\}$$where we use FLT along with the fact that $k=(p-1)-(i+j)$. This means that the polynomial $G(x)=(x-a)^i(x-b)^j-(x-c)^{i+j}$ has $p-3$ roots (where we have $G \in \mathbb F_p[x]$). As degree of $G$ is at most $i+j-1$, so we have $$i+j-1 \geq p-3 \Rightarrow p-2-k \geq p-3 \Rightarrow k \leq 1 \Rightarrow k=0,1$$Now we have the following two cases to deal with:-
  • If $k=0$, then we have $$(x-a)^i(x-b)^j \equiv 1 \pmod{p} \Rightarrow (x-a)^i(x-b)^{p-1-i} \equiv 1 \pmod{p}$$Multiplying both sides of the congruence by $(x-b)^i$, and with the help of FLT, we get that $(x-a)^i \equiv (x-b)^i \pmod{p}$. Again consider the polynomial $H(x)=(x-a)^i-(x-b)^i$, which has $p-3$ roots in $\mathbb F_p[x]$. As $\text{deg}(H) \leq i-1$, so $i-1 \geq p-3$, which gives $i=p-2$ (since $0 \leq i \leq p-2$). But then, working in $\mathbb F_p,$ we have $$(x-a)^{p-2}=(x-b)^{p-2} \Rightarrow (x-a)^{p-1}(x-b)=(x-b)^{p-1}(x-a) \Rightarrow x-b=x-a \Rightarrow a=b \Rightarrow p \mid a-b \rightarrow \text{CONTRADICTION}$$$\text{ }$
  • Let $k=1$. Then we have $j=p-2-i$, which gives $$(x-a)^i(x-b)^{p-2-i}(x-c) \equiv 1 \pmod{p} \Rightarrow (x-a)^i(x-c) \equiv (x-b)^{i+1} \pmod{p}$$Let $T(x)=(x-a)^i(x-c)-(x-b)^{i+1}$ be a polynomial in $\mathbb F_p[x]$. Then, it has $p-3$ roots, and $\text{deg}(T) \leq i$. This gives $i \geq p-3$, which means that $i=p-3,p-2$ (since $0 \leq i \leq p-2$). If $i=p-2$, then $j=0$, in which case we can arrive at a contradiction in a similar manner as we did for the case $k=0$. So we must have $i=p-3,j=k=1$. This gives $$(x-a)^{p-3}(x-b)(x-c) \equiv 1 \pmod{p} \Rightarrow (x-b)(x-c) \equiv (x-a)^2 \pmod{p} \text{ } \forall x \in \mathbb{F}_p \setminus \{a,b,c\}$$where we multiply both sides by $(x-a)^2$ and use FLT. As this has $p-3$ roots, and $p-3>1$ (since $p>5$), so the identity $(x-a)^2=(x-b)(x-c)$ should be true in $\mathbb F_p$. Thus, we have (working in $\mathbb F_p$) $b+c=2a \text{ and } bc=a^2$. As this is the equality case of the AM-GM inequality, so we must have $b=c$, which contradicts the fact that $p \nmid b-c$.

Thus, we arrive at a contradiction in all cases, as desired. $\blacksquare$

EDIT: I forgot to mention that each of the polynomials $G,H,T$ are not identities (which we get on plugging in $a,b,c$ in them). We need this since otherwise we can not apply bounding on their degrees.
This post has been edited 2 times. Last edited by math_pi_rate, Apr 13, 2019, 7:43 AM
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Cindy.tw
54 posts
Cindy.tw
#12 Dec 13, 2020, 3:10 AM • 3 Y
Y by Adventure10, jhu08, cubres
pinetree1 wrote:
Here's a cleaner finish than using Lagrange.

First we may assume that $i, j, k < p-1$ by FLT, so $i+j+k\in \{0, p-1, 2(p-1)\}$.
  • If $i+j+k = 0$, we're done.
  • If $i+j+k = 2(p-1)$, send $i\to (p-1)-i$ (and similarly for $j$ and $k$) so that $i+j+k=p-1$. This does not affect the hypothesis by FLT.
Hence we can assume $i+j+k=p-1$. Let
$$f(x) = (x-a)^i(x-b)^j(x-c)^k - 1,$$so by hypothesis $f$ vanishes everywhere except at $a, b, c$. This implies $\sum_{x=0}^{p-1} f(x) \equiv -3\pmod p$.

However, $f$ is monic with degree $p-1$, and thus $\sum_{x=0}^{p-1} f(x) \equiv -1\pmod p$, contradiction.

Here are the details for the last step. If we let $g = f-x^{p-1}$ have degree less than $p-1$, we can write
$$\sum_{x=0}^{p-1} f(x) = \sum_{x=0}^{p-1} x^{p-1} + \sum_{x=0}^{p-1} g(x) \equiv -1\pmod p,$$where we are using the fact that if a polynomial $P$ has degree less than $p-1$, then $\sum_x P(x) \equiv 0\pmod p$. Of course this follows from the fact that
$$1^k+2^k+\dots +(p-1)^k\equiv 0\pmod p$$if $p-1\nmid k$.

You miss the point that $i, j, k$ might be 0, then your claim failed.
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GeronimoStilton
1521 posts
GeronimoStilton
#13 Feb 21, 2021, 1:32 PM • 3 Y
Y by Adventure10, jhu08, cubres
Reduce $i,j,k$ modulo $p-1$. If $i+j+k=0$ we are done, and if $i+j+k=2(p-1)$ replace each with $p-1-i,p-1-j,p-1-k$ so we can WLOG assume $i+j+k=p-1$. WLOG $i+j\le 2(p-1)/3$. Clearly $i+j>0$ because otherwise $k$ wasn't reduced. The goal is to show we cannot have
\[(x-c)^{i+j}-(x-a)^i(x-b)^j\equiv 0\pmod{p}\]for all $x\not\equiv a,b,c\pmod{p}$. Suppose otherwise. The polynomial has degree at most $i+j-1$ but $p-3$ roots. Note it cannot be zero because then taking $x=c$ yields a contradiction. Otherwise, we get
\[p-3\le i+j-1\le 2(p-1)/3-1\iff p-2\le 2(p-1)/3\iff 3p-6\le 2p-2\iff p\le 4,\]which is absurd, thus we are done.
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srisainandan6
2811 posts
srisainandan6
#14 Aug 6, 2021, 4:16 PM • 2 Y
Y by jhu08, cubres
Interesting.

Notice by FLT, we can immediately restrict the values of $i,j,k$ to $\{0,1,...,p-2\}$. Hence we have that $i+j+k \le 3(p-2)$, so $i+j+k \in \{0,p-1,2(p-1)\}$.If $i+j+k = 0$, then it is easy to see that we are done. Now we will show that we can reduce the case where $i+j+k = 2(p-1)$ to $i+j+k= p-1$. We can consider two cases now, one where $\max{(i,j,k)} \ge p-1$ and one where $p-1 \ge \max{(i,j,k)} \ge \frac{2(p-1)}{3}$. In the former case, we are able to replace $\max{(i,j,k)}$ with $\max{(i,j,k)} - (p-1)$, and in the latter case replace $\max{(i,j,k)}$ with $(p-1) - \max{(i,j,k)}$. Now we can turn all our attention to the case where $i+j+k = p-1$.

Observe that we are essentially operating on $\mathbb{F}_p \setminus \{a,b,c\}$ and have that ${(x-a)}^i{(x-b)}^j{(x-c)}^k = 1$. We desire to show that this isn't possible unless $x=a,b,c$, and we will suppose the contrary. Assume that $\max{(i,j,k)}=i$. Applying FLT once more gives us ${(x-b)}^j{(x-c)}^k - {(x-a)}^{j+k} = 0$, and notice that the leading degree cancels out so the degree of this polynomial is given to be $j+k-1$. Since we have that $\max{(i,j,k)}=i$, we get that $j+k-1 \le \frac{2(p-1)}{3}$. By Lagrange, we have that $p-3 \le \frac{2(p-1)}{3}$, which only holds for $p \le 4$, ridiculous. $\blacksquare$
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Sprites
478 posts
Sprites
#15 Aug 25, 2021, 6:47 AM • 1 Y
Y by cubres
Reduce $i,j,k$ modulo $p-1$.
Since the equation is symmetric we can assume that $i>j>k$(if they were equal then $p-1|i+j+k=3i=3j=3k$ or $p-1|i,p-1|j,p-1|k$,which is what we wanted)
If $i+j+k=0$,we will be done so consider the case $i+j+k=2(p-1)$ where we can replace each of $i,j,k$ with $p-i-1,p-j-1,p-k-1$ so we just need to check the case when $i+j+k=p-1$
By FLT,${(x - a)(x - b)(x - c)[(x-b)}^j{(x-c)}^k - {(x-a)}^{j+k}] \equiv 0 \pmod p$,and since this works for all $x$,choose $x$ such that $(x - a)(x - b)(x - c) \equiv r>0 \pmod p$
By Lagrange's theorem and since $p$ is a prime,$f(X) \equiv 0 \pmod p$,has atmost $deg(f)>0$ solutions so $(X-b)^j(X-c)^k \equiv (X-a)^{j+k} \pmod p$ must have atleast $p$ solutions $\pmod p$ which covers all residues so it must work for all integers.
Now plugging in $X=b$ and $X=c$ gives $(b-a)^{j+k}$ and $(c-a)^{j+k}$ to be divisible by $p$
Since $p \nmid(b-a),(c-a)$,$j+k=(p-1)r$,a contradiction since $0<j+k<p-1$,or all of $i,j,k \equiv 0 \pmod p$,as required.
This post has been edited 4 times. Last edited by Sprites, Aug 25, 2021, 7:03 AM
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HamstPan38825
8857 posts
HamstPan38825
#16 Apr 13, 2023, 11:33 PM • 1 Y
Y by cubres
Assume that $i, j, k < p-1$. We will show that $i=j=k=0$.

Assume otherwise. Then $i+j+k = (p-1)$ or $2(p-1)$; in the former case, replace each $i$ with $p-1-i$, so it suffices to show the former case.

WLOG $i>j>k$. We have the reduction $$(x-a)^{j+k}(x-b)(x-c) \equiv (x-b)^{j+1}(x-c)^{k+1}$$for all integers $x$ by Fermat's little theorem. But now, the relevant degree of the polynomial is $j+k+2 < p$, hence $f \equiv 0 \pmod p$ by Lagrange. Then $$(X-b)^j(X-c)^k \equiv (X-a)^{j+k} \pmod p.$$At $X=b$, this implies $a=b$, impossible. Thus $i=j=k=0$.
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dolphinday
1324 posts
dolphinday
#17 Jul 27, 2024, 10:59 PM • 1 Y
Y by cubres
WLOG $0 \leq i, j, k \leq p-2$ since we can remove $p-1$ from each of $i$, $j$, $k$ repeatedly since it does not affect the quantity in question. If $0 = i = j = k$ we are done so FTSOC assume this is not true.
Then $i + j + k < 3(p-1)$ so either $i + j + k = p-1$ or $2p - 1$. If $i + j + k = 2p - 1$ then replace each of $i, j, k$ with $(p-1) - i, (p-1) - j, (p-1) - k$ to get that $i + j + k = p-1$ which is the only case we will be dealing with. Note that $1^k + 2^k + \dots + (p-1)^k \equiv 0\pmod{p}$ unless $p - 1 \mid k$.
Then we can count $\sum_{i=1}^{p-1} (x-a)^i(x-b)^j(x-c)^k \pmod{p}$ from our previous claim as $-1 \pmod{p}$. However since $(x-a)^i(x-b)^j(x-c)^k - 1$ vanishes modulo $p$ for all $x \neq a, b, c$ we have that $\sum_{i=1}^{p-1} (x-a)^i(x-b)^j(x-c)^k \equiv p-3 \pmod{p}$. This is a contradiction as $p-1 \equiv p-3 \pmod{p}$ implies $p = 2$, contradiction. So then $i \equiv j \equiv k \equiv 0\pmod{p-1}$.
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Saucepan_man02
1328 posts
Saucepan_man02
#18 Jan 15, 2025, 5:59 AM • 1 Y
Y by cubres
Storage:

Removing the cover; we have: for all $x \in \mathbb F_p /\{a, b, c\}$: $(x-a)^i (x-b)^j (x-c)^k \equiv 1 \equiv (x-a)^{i+j+k} \pmod p$ Assume that: $ i, j, k \le p-1$. If $i+j+k=0$, we are done. If $i+j+k=2(p-1)$, replace $i$ with $p-1-i$, $j$ with $p-1-j$, $k$ with $p-1-k$. Thus assume $i+j+k=(p-1)$.

WLOG $i \ge j \ge k$. Thus: $j+k \le \frac{2(p-1)}{3}$. Note that: $(x-b)^j (x-c)^k \equiv (x-a)^{j+k} \pmod p$ has $p-3$ solutions. Thus, by Lagrange's Theorem we must have: $p-3 \le \frac{2(p-1)}{3}$ which leads to contradiction as $p>5$.
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OronSH
1729 posts
OronSH
#19 Jan 20, 2025, 2:23 AM • 2 Y
Y by dolphinday, cubres
Shift $i,j,k$ by $p-1$ to be $<p-1$, then if $i+j+k=2p-2$ consider $p-1-i,p-1-j,p-1-k$ instead. If $i+j+k=p-1$ then $(x-a)^i(x-b)^j(x-c)^k$ is zero on $a,b,c$ and one otherwise, but so is $(x-a)^{p-1}+(x-b)^{p-1}+(x-c)^{p-1}-2$. Now they have the same degree and different leading term, so their difference is a polynomial of degree $p-1$ with $p$ roots $0,1,\dots,p-1$, impossible. Thus $i+j+k=0$ so $i,j,k=0$ which implies $p-1\mid i,j,k$ as desired.
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cubres
117 posts
cubres
#20 Mar 2, 2025, 11:26 AM
Y by
Rough sketch of the solution
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Mathandski
754 posts
Mathandski
#21 Mar 6, 2025, 5:44 PM • 2 Y
Y by OronSH, cubres
Subjective Rating (MOHs)
Please contact westskigamer@gmail.com if there is an error with any of my solution for cash bounties by 3/18/2025.
Bounty claims likely here since I didn't use $p > 5$.
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Ilikeminecraft
609 posts
Ilikeminecraft
#22 Apr 14, 2025, 5:30 PM
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We may assume $i + j + k \leq 3(p - 1).$ If $i + j + k = 3(p - 1),$ at least one is geq than $p - 1.$ Then, FLT finishes.

If $i + j + k = 2(p - 1),$ then taking $i\mapsto p - 1 - i, j\mapsto p- 1 - j, k \mapsto p - 1 - k$ implies it suffices to show the case when $i + j + k = p - 1.$

Suppose $k \leq j \leq i.$ Then, $i = p - 1 - j - k,$ so $(x - b)^j(x - c)^k \equiv (x- a)^{j + k}\pmod{p}.$ The polynomial $(x - b)^j(x - c )^k - (x - a)^{j + k}$ has $p - 3$ distinct 0s in $\mathbb F_p.$ However, the degree is bounded above by $\frac{2(p - 1)}{3} - 1.$ Since $\frac{2(p - 1)}{3} - 1 < p - 3$ is true for all $p \geq7,$ we are done.
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