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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
J
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Gives typical russian combinatorics vibes
Sadigly   2
N 5 minutes ago by Edward_Tur
Source: Azerbaijan Senior MO 2025 P3
You are given a positive integer $n$. $n^2$ amount of people stand on coordinates $(x;y)$ where $x,y\in\{0;1;2;...;n-1\}$. Every person got a water cup and two people are considered to be neighbour if the distance between them is $1$. At the first minute, the person standing on coordinates $(0;0)$ got $1$ litres of water, and the other $n^2-1$ people's water cup is empty. Every minute, two neighbouring people are chosen that does not have the same amount of water in their water cups, and they equalize the amount of water in their water cups.

Prove that, no matter what, the person standing on the coordinates $(x;y)$ will not have more than $\frac1{x+y+1}$ litres of water.
2 replies
Sadigly
May 8, 2025
Edward_Tur
5 minutes ago
J
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symmedians and tangent
jokerjoestar   6
N 16 minutes ago by Ilikeminecraft
Let P be any point on the circumcircle (O) of triangle ABC. AP intersects the tangent lines of (O) passing through B,C respectively at M,N. K is the intersection of CM and BN and PK intersects BC at J. Prove that AJ is the symmedian of triangle ABC.
6 replies
jokerjoestar
Aug 23, 2022
Ilikeminecraft
16 minutes ago
J
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a tuff nut [cevians, intersections and angle bisectors]
vineet   8
N 24 minutes ago by Kyj9981
Source: Indian olympiad 2003
hey
here is the geometry problem from indian olympiad 2003.

consider traingle acute angled ABC . let BE and CF be cevians with E and F on
AC and AB resp intersecting in P. join EF and AP. denote the intersection of AP and EF by D. draw perpendicular on CB from D and denote the intersction of the perpendicular by K. Prove that KD bisects <EKF.

I will post the other problems as soon as i find them.
as for my performance in the olympiad, it was terrible. i got only two questions and one partial solution. well definitely i am heartbroken and was on an exile from mathematics until feb 25, the day i joined this group
say, when duz the romanian olympiad happen?

vineet
8 replies
vineet
Mar 2, 2003
Kyj9981
24 minutes ago
J
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An easy combinatorics
fananhminh   2
N 36 minutes ago by fananhminh
Source: Vietnam
Let S={1, 2, 3,..., 65}. A is a subset of S such that the sum of A's elements is not divided by any element in A. Find the maximum of |A|.
2 replies
fananhminh
an hour ago
fananhminh
36 minutes ago
J
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Trig Identity
gauss202   1
N 4 hours ago by Lankou
Simplify $\dfrac{1-\cos \theta + \sin \theta}{\sqrt{1 - \cos \theta + \sin \theta - \sin \theta \cos \theta}}$
1 reply
gauss202
5 hours ago
Lankou
4 hours ago
J
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Trunk of cone
soruz   1
N Today at 9:59 AM by Mathzeus1024
One hemisphere is putting a truncated cone, with the base circles hemisphere. How height should have truncated cone as its lateral area to be minimal side?
1 reply
soruz
May 6, 2015
Mathzeus1024
Today at 9:59 AM
J
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Inequalities
sqing   7
N Today at 8:29 AM by sqing
Let $a,b,c >1 $ and $ \frac{1}{a-1}+\frac{1}{b-1}+\frac{1}{c-1}=1.$ Show that$$ab+bc+ca \geq 48$$$$\frac{1}{a}+\frac{1}{b}+\frac{1}{c}\leq \frac{3}{4}$$Let $a,b,c >1 $ and $ \frac{1}{a-1}+\frac{1}{b-1}+\frac{1}{c-1}=2.$ Show that$$ab+bc+ca \geq \frac{75}{4}$$$$\frac{1}{a}+\frac{1}{b}+\frac{1}{c}\leq \frac{6}{5}$$Let $a,b,c >1 $ and $ \frac{1}{a-1}+\frac{1}{b-1}+\frac{1}{c-1}=3.$ Show that$$ab+bc+ca \geq 12$$$$\frac{1}{a}+\frac{1}{b}+\frac{1}{c}\leq \frac{3}{2}$$
7 replies
1 viewing
sqing
Yesterday at 9:04 AM
sqing
Today at 8:29 AM
J
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Assam Mathematics Olympiad 2022 Category III Q18
SomeonecoolLovesMaths   2
N Today at 8:12 AM by nyacide
Let $f : \mathbb{N} \longrightarrow \mathbb{N}$ be a function such that
(a) $ f(m) < f(n)$ whenever $m < n$.
(b) $f(2n) = f(n) + n$ for all $n \in \mathbb{N}$.
(c) $n$ is prime whenever $f(n)$ is prime.
Find $$\sum_{n=1}^{2022} f(n).$$
2 replies
SomeonecoolLovesMaths
Sep 12, 2024
nyacide
Today at 8:12 AM
J
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Assam Mathematics Olympiad 2022 Category III Q17
SomeonecoolLovesMaths   1
N Today at 7:24 AM by nyacide
Consider a rectangular grid of points consisting of $4$ rows and $84$ columns. Each point is coloured with one of the colours red, blue or green. Show that no matter whatever way the colouring is done, there always exist four points
of the same colour that form the vertices of a rectangle. An illustration is shown in the figure below.
1 reply
SomeonecoolLovesMaths
Sep 12, 2024
nyacide
Today at 7:24 AM
J
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Assam Mathematics Olympiad 2022 Category III Q14
SomeonecoolLovesMaths   1
N Today at 6:54 AM by nyacide
The following sum of three four digits numbers is divisible by $75$, $7a71 + 73b7 + c232$, where $a, b, c$ are decimal digits. Find the necessary conditions in $a, b, c$.
1 reply
SomeonecoolLovesMaths
Sep 12, 2024
nyacide
Today at 6:54 AM
J
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Assam Mathematics Olympiad 2022 Category III Q12
SomeonecoolLovesMaths   2
N Today at 6:20 AM by nyacide
A particle is in the origin of the Cartesian plane. In each step the particle can go $1$ unit in any of the directions, left, right, up or down. Find the number of ways to go from $(0, 0)$ to $(0, 2)$ in $6$ steps. (Note: Two paths where identical set of points is traversed are considered different if the order of traversal of each point is different in both paths.)
2 replies
SomeonecoolLovesMaths
Sep 12, 2024
nyacide
Today at 6:20 AM
J
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Assam Mathematics Olympiad 2022 Category III Q10
SomeonecoolLovesMaths   1
N Today at 5:53 AM by nyacide
Let the vertices of the square $ABCD$ are on a circle of radius $r$ and with center $O$. Let $P, Q, R$ and $S$ are the mid points of $AB, BC, CD$ and $DA$ respectively. Then;
(a) Show that the quadrilateral $P QRS$ is a square.
(b) Find the distance from the mid point of $P Q$ to $O$.
1 reply
SomeonecoolLovesMaths
Sep 12, 2024
nyacide
Today at 5:53 AM
J
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A problem of collinearity.
Raul_S_Baz   2
N Today at 4:11 AM by Raul_S_Baz
Î am the author.
IMAGE
P.S: How can I verify that it is an original problem? Thanks!
2 replies
Raul_S_Baz
Yesterday at 4:19 PM
Raul_S_Baz
Today at 4:11 AM
J
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Inequalities
sqing   0
Today at 3:46 AM
Let $ a,b,c>0 $ . Prove that
$$\frac{a+5b}{b+c}+\frac{b+5c}{c+a}+\frac{c+5a}{a+b}\geq 9$$$$ \frac{2a+11b}{b+c}+\frac{2b+11c}{c+a}+\frac{2c+11a}{a+b}\geq \frac{39}{2}$$$$ \frac{25a+147b}{b+c}+\frac{25b+147c}{c+a}+\frac{25c+147a}{a+b} \geq258$$
0 replies
sqing
Today at 3:46 AM
0 replies
J
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J
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RMM 2013 Problem 1
dr_Civot   31
N Apr 30, 2025 by cursed_tangent1434
For a positive integer $a$, define a sequence of integers $x_1,x_2,\ldots$ by letting $x_1=a$ and $x_{n+1}=2x_n+1$ for $n\geq 1$. Let $y_n=2^{x_n}-1$. Determine the largest possible $k$ such that, for some positive integer $a$, the numbers $y_1,\ldots,y_k$ are all prime.
31 replies
dr_Civot
Mar 2, 2013
cursed_tangent1434
Apr 30, 2025
J
RMM 2013 Problem 1
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Reveal topic tags
floor function
modular arithmetic
quadratics
number theory
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dr_Civot
354 posts
dr_Civot
#1 Mar 2, 2013, 10:36 AM • 5 Y
Y by Davi-8191, Mathuzb, ILOVEMYFAMILY, Adventure10, Rounak_iitr
For a positive integer $a$, define a sequence of integers $x_1,x_2,\ldots$ by letting $x_1=a$ and $x_{n+1}=2x_n+1$ for $n\geq 1$. Let $y_n=2^{x_n}-1$. Determine the largest possible $k$ such that, for some positive integer $a$, the numbers $y_1,\ldots,y_k$ are all prime.
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dr_Civot
354 posts
dr_Civot
#2 Mar 2, 2013, 11:10 AM • 3 Y
Y by ILOVEMYFAMILY, Adventure10, Mango247
Solution.
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siddigss
224 posts
siddigss
#3 Mar 2, 2013, 3:03 PM • 2 Y
Y by Adventure10, Mango247
Sorry just a stupid post :blush: !
This post has been edited 2 times. Last edited by siddigss, Mar 18, 2013, 6:55 PM
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dr_Civot
354 posts
dr_Civot
#4 Mar 2, 2013, 3:40 PM • 3 Y
Y by Adventure10, Mango247, Rounak_iitr
siddigss wrote:
Click to reveal hidden text

Your solution is obviously wrong because if $a\equiv 2 \mod 3$ then $4a+3\equiv 2\neq 0 \mod 3$.

By the way, if you try to find some prime $p$ such that $p\mid x_n$ for some $n$ you will never find such prime letting $a\equiv -1 \mod p$.
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ksun48
1514 posts
ksun48
#5 Mar 2, 2013, 10:03 PM • 4 Y
Y by Illuzion, CHLORG1, ILOVEMYFAMILY, Adventure10
I claim that the answer is two.
If $x_1 = 2$, then $x_2 = 5$, $x_3 = 11$. $2^2-1 = 3$ and $2^5-1=31$ are primes, but $2^11-1 = 23\cdot 89$ is not a prime. (this achieves $k = 2$)
Assume $x_1$ is odd from now on.

Lemma: if $2^k-1$ is prime, then $k$ is prime.
Proof: If $p\mid k$, then $2^p-1 \mid 2^k-1$.

Now, assume to the contrary that $k > 2$, so that $2^{x_1}-1$, $2^{x_2}-1$, and $2^{x_3}-1$ are all prime. Then $x_3 = 4x_1+3$, and since $x_1$ is odd, $x_3 \equiv 7 \pmod{8}$. By the lemma, $x_3$ is prime. Thus $2$ is a quadratic residue mod $x_3$. Let $2 = k^2 \pmod{x_3}$. Then $2^{x_2}-1 \equiv k^{2x_2}-1 = k^{x_3-1}-1 \equiv 0 \pmod{x_3}$ by Fermat's Little Theorem. Thus $y_3 \mid 2^{x_2}-1$, and $2^{x_2}-1 > x_3$ (unless $x_3 = 5$ or $x_3 = 7$, which don't work), a contradiction to the fact that $2^{x_2}-1$ is prime.

Thus the minimum $k$ is two.
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MathTwo
541 posts
MathTwo
#6 Mar 3, 2013, 1:05 AM • 2 Y
Y by Adventure10, Mango247
I do not quite like the fact that quadratic reciprocity is really the only nice way to solve this problem.. there should be a nicer method that does not invoke such mechanics. Does anyone else have a nice more elementary solution to this problem?
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dinoboy
2903 posts
dinoboy
#7 Mar 3, 2013, 3:36 AM • 4 Y
Y by Adventure10, Mango247, ehuseyinyigit, and 1 other user
Computing $\left ( \frac{2}{p} \right )$ is rather simple and extremely elementary... the full strength of reciprocity laws is not needed.
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Saint123
183 posts
Saint123
#8 Apr 2, 2013, 3:32 PM • 2 Y
Y by Adventure10, Mango247
I will use $M_n$ to denote the $n-th$ Mersenne Number which is $2^n-1$

Now observe that a necessary condition for $M_n$ to be prime is that $n$ should be prime.
Now also observe that for primes $p$ and $q=2p+1$ we have $q|M_p$ if $p\equiv 3(mod4)$
So assume $a\equiv 1(mod4)$.
Now $x_2=2a+1\equiv 3(mod4)$ and it is a prime for $y_2$ to be a prime.
So if $x_3=2(2a+1)+1$ is a prime, $x_3|y_2$, thus the maximum such $k$ is 2 - added that $x_3$, and thus $y_3$ is composite.
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dibyo_99
487 posts
dibyo_99
#9 Apr 3, 2013, 6:14 AM • 1 Y
Y by Adventure10
Firstly, $x_n = 2^{n-1}(a+1) -1$
Using basic properties of Mersenne primes, if $y_i$s are primes, $x_i$s must also be primes.
Assuming $k>2$, $x_1, x_2, x_3$ are all primes.
So, $a$ is a prime, $2a+1$ is a prime and also $4a+3$ is a prime.

Then by using Euler's criterion,
$2^{2a+1}-1 \cong 2^{\frac{(4a+3)-1}{2}}\cong \left( \frac{2}{4a+3} \right)(mod$ $4a+3)$
Suppose now that $a=2$. Then, we see that $y_3= 2^{11} -1= 2047=23.89$, contradiction.
So, $a$ must be odd. Therefore $4a+3 \cong 7(mod$ $8)$.
So we have $2^{2a+1} \cong \left( \frac{2}{4a+3} \right) \cong 1(mod$ $4a+3)$, since $2$ is a quadratic residue modulo any prime of the form $8m+7$.
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Garfield
243 posts
Garfield
#10 Oct 19, 2016, 8:12 AM • 2 Y
Y by Adventure10, Mango247
Solution
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yayups
1614 posts
yayups
#11 Dec 13, 2018, 1:41 PM • 1 Y
Y by Adventure10
Hmm, I feel this is a bit too hard for a #1, though not sure. The key lemma took me a while to find.

The answer is $k=2$. Suppose we had a chain of length $3$. Clearly, if $y_n$ is prime, then so is $x_n$ (because $2^a-1\mid 2^b-1$ if $a\mid b$). We have the following miraculous lemma:

Lemma: All the $x_i$ for $i\le k$ except potentially $x_1$ are not $1$ or $7$ mod $8$.

Proof of Lemma: Note that if $x_{n+1}\equiv 1,7\pmod{8}$, then $2$ is a QR mod $x_{n+1}$. Therefore, $2^{(x_{n+1}-1)/2}\equiv 1\pmod{x_{n+1}}$, so $x_{n+1}\mid 2^{x_n}-1=y_n$. But $y_n$ is prime, so we must have $x_{n+1}=y_n$, so $2x+1=2^x-1$ for $x=x_n$. It is easy to see that $2x+1=2^x-1$ has no solutions for positive integers $x$. Therefore, we have the desired contradiction. $\blacksquare$

Now, note that the action of $2x+1$ mod $8$ is given by
\begin{align*} 0&\mapsto 1\\ 1&\mapsto 3\\ 2&\mapsto 5\\ 3&\mapsto 7\\ 4&\mapsto 1\\ 5&\mapsto 3\\ 6&\mapsto 5\\ 7&\mapsto 7.\\ \end{align*}Since our chain of length $3$ can't have anything that's $1$ or $7$ except the start, the last element can only be $1,2,5,6$, so only $5$. Therefore, the chain is $2,5,3$. Now, if $x_1\equiv 2\pmod{8}$ then $x_1=2$ (because its has to be prime), which we can verify doesn't work. $\blacksquare$
This post has been edited 1 time. Last edited by yayups, Dec 13, 2018, 4:31 PM
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math_pi_rate
1218 posts
math_pi_rate
#12 Dec 14, 2018, 7:52 AM • 2 Y
Y by Adventure10, Mango247
Nice problem. Although it's easily doable if one knows what are Mersenne Primes. Anyway, here's my solution: Let $M_s=2^s-1$ denote the $s^{th}$ Mersenne Number. It is well known that if $M_s$ is a prime then $s$ must also be a prime. We claim that $k=2$ is the largest possible value of $k$. To see this, take $x_1=a=3$. Then $x_2=7$ and $x_3=15$, which works as $y_1=M_3=7$ and $y_2=M_7=127$ are primes, while $y_3=M_{15}=32767=7 \times 4681$ is not. Now, we'll show that $k=3$ doesn't work. To see this, assume to the contrary that for some value of $a$, $k=3$ works. Then $x_1=a,x_2=2a+1,x_3=4a+3$ must all be primes. We use the following well-known lemma to supplement our proof-

LEMMA If $p \equiv 3 \pmod{4}$ and $q=2p+1$ are both primes, then $q \mid M_p$.

PROOF: By FLT, we get that \begin{align*} 2^{q-1} \equiv 1 \pmod{q} \Rightarrow 2^{2p} \equiv 1 \pmod{q} &\Rightarrow 2^p \equiv +1 \pmod{q} \\ &\text{OR } 2^p \equiv -1 \pmod{q} \end{align*}Suppose the latter holds true. Then, using the fact that $p=\frac{q-1}{2}$, and from Euler's Criterion, we get that $2$ is a quadratic non-residue modulo $q$. But, as $q=2p+1 \equiv 7 \pmod{8}$ , using the Second Supplement to the Quadratic Reciprocity Theorem, we get that $2$ is in fact a quadratic residue modulo $q$, which is a contradiction! Thus, the former result must be true, i.e. $2^p-1 \equiv 0 \pmod{q} \Rightarrow q \mid M_p$ $\Box$

Return to the problem at hand. It's easy to see that $a=2$ doesn't work (as $M_{4a+3}=M_{11}=2047=23 \times 89$ is not a prime). So from now on we assume that $a>2$. As $a$ is a prime number, it must be of the form $2t+1$. This gives $x_2=4t+3$. By our Lemma, we get that $x_3=2x_2+1$ (which is a prime) divides $M_{x_2}$, as $x_2 \equiv 3 \pmod{4}$ is a prime, which contradicts the fact that $y_2$ is a prime number. Hence, done. $\blacksquare$
This post has been edited 2 times. Last edited by math_pi_rate, Dec 14, 2018, 7:53 AM
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niyu
830 posts
niyu
#13 Feb 18, 2019, 9:04 PM • 1 Y
Y by Adventure10
We claim the answer is $k = 2$, which is achieved by $a = 3$.

Lemma 1: If $2^m - 1$ is prime for some positive integer $m$, $m$ must itself be prime.

Proof of Lemma 1: Suppose not, and write $m = ab$ for some $a, b > 1$. But $2^a - 1 \mid 2^m - 1$, contradicting the fact that $2^m - 1$ is prime. $\blacksquare$

Lemma 2: Suppose $p, 2p + 1$ are both odd primes. If $2^p - 1$ and $2^{2p + 1} - 1$ are both also prime, $p \equiv 1 \pmod{4}$.

Proof of Lemma 2: Consider
\begin{align*} 2^p \pmod{2p + 1}. \end{align*}This is the Jacobi symbol $\left(\frac 2{2p + 1}\right)$. If $\left(\frac 2{2p + 1}\right) = 1$, we have
\begin{align*} 2p + 1 &\mid 2^p - 1, \end{align*}contradicting the fact that $2^p - 1$ is prime. Hence, we must have $\left(\frac 2{2p + 1}\right) = -1$. This is equivalent to
\begin{align*} (-1)^{\frac{(2p + 1)^2 - 1}{8}} &= -1 \\ \iff (-1)^{\frac{2p(2p + 2)}{8}} &= -1 \\ \iff (-1)^{\frac{p + 1}{2}} &= -1. \end{align*}Thus, we must have $p \equiv 1 \pmod{4}$, proving the lemma. $\blacksquare$

We now return to the original problem. Suppose $y_1, y_2, y_3$ are all prime. By Lemma 1, $x_1, x_2, x_3$ are also all prime, so by definition $a, 2a + 1, 4a + 3$ are all prime. Now, by Lemma 2, $a \equiv 1 \pmod{4}$, and also $2a + 1 \equiv 1 \pmod{4}$, which is clearly impossible. Therefore, $k \leq 2$, with equality demonstrated by $a = 3$. This completes the proof. $\Box$
This post has been edited 3 times. Last edited by niyu, Mar 1, 2019, 4:05 AM
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mastermind.hk16
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mastermind.hk16
#14 Feb 28, 2019, 11:04 PM • 2 Y
Y by Adventure10, Mango247
I claim $k=2$. Construction: $x_1=2$.
Lemma 1: If $2^t -1$ is prime, then $t$ must be prime.
Proof: Clearly, it $t=uv$, then both $2^u -1$ and $2^v -1$ divide $t$.

Lemma 2: For any prime $p \equiv 7 \mod 8$, $ \ \ 2^{\frac{p-1}{2}} \equiv 1 \mod p$
Proof: We have $\left( \frac{2}{p} \right) = (-1)^{\frac{p^2-1}{2}} = 1$. Hence $1\equiv \left( \frac{2}{p} \right) \equiv 2^{\frac{p-1}{2}} \mod p$.

Now back to the problem. By Lemma 1, $x_i$'s must be prime for $y_i$'s to be prime.
AFSOC, we have $y_1, y_2, y_3$ are all prime. Let $x_1 =a$, where $a$ is an odd prime.
Then clearly $x_3 \equiv 7 \mod 8$. Applying Lemma 2, $2^{x_2}-1 \equiv 0 \mod x_3$.
But $a \geq 3 \longrightarrow 2^{2a +1}-1 > 4a+3 $ because $2^{2a-1} > 2^a +1 > a+1 $. So $y_2 =2^{x_2}-1$ is composite. Contradiction.

Lastly, if $x_1=2$ then $x_2 =5, x_3 =11, x_4 =23$. Again by Lemma 2, $23 \mid 2^{11}-1$ and $2^{11}-1>23$, so it's composite. Therefore, $k=2$.
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Idio-logy
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Idio-logy
#15 Apr 10, 2020, 1:42 AM • 2 Y
Y by Nathanisme, Mango247
The key observation is the following lemma:

Incredible

We can finish by considering the possible chain of $x_n$ modulo 8, and the answer is 2, which could be achieved by $a=3$.
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GeronimoStilton
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GeronimoStilton
#16 Jun 5, 2020, 9:22 PM
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The maximum value of $k$ is $k=2$. Construction is easy; take $a=2$, for example.

The following proof of maximality is due to awang11.

Suppose that $k=3$ was attainable. Note that $a,2a+1,4a+3$ must all be primes. If $a=2$, we get a contradiction because $2^{4a+3}-1=2^{11}-1=2047=23\cdot 89$. Thus, we can assume $a\equiv 1\pmod{2}$. Then, note that
\[2^{(4a+3-1)/2} \equiv 1\pmod{4a+3}\]because $2$ is a quadratic residue modulo $4a+3\equiv -1\pmod{8}$. This implies
\[4a+3\mid 2^{2a+1}-1=y_2.\]It remains to deal with the case
\[4a+3=2^{2a+1}-1.\]Then, we can rewrite as
\[a+1=2^{2a-1}.\]Note that equality holds at $a=1$, then note that increasing $a$ by $1$ increases the RHS by $1$ and the LHS by more than $1$, so equality can never hold for prime $a$.
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algebra_star1234
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algebra_star1234
#17 Jun 13, 2020, 11:39 PM
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We claim that that the maximum is $k=2$. We can achieve this with $a=2$.

For the sake of contradiction, assume there is a sequence of length at least $3$. First, note that $2^x - 1$ is prime only if $x$ is also prime. Therefore, we have $a$, $2a+1$, and $4a+3$ are prime. Note that when $a$ is even, $y_1$ is prime if and only if $a=2$. We already know the $a=2$ case yields $k=2$, so we can assume $a$ is odd or $a = 2k+1$. Therefore, we have $2k+1$, $4k+3$, and $8k+7$ are prime. Note that for a prime of the form $8k+7$, the number $2$ is a quadratic residue because
\[ \left(\frac{2}{p}\right) = (-1)^{\frac18 (p^2-1)} = 1 .\]Let $m^2 = 2 \pmod{8k+7}$. We assumed $y_2$ is prime, but
\[ 2^{4k+3} -1 \equiv m^{8k+6} - 1 \equiv 0 \pmod{8k+7} \]by FLT. Therefore, we must have $2^{4k+3}-1 = 8k+7$, which does not provide any solutions. Therefore, we have a contradiction, and we are done.
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VulcanForge
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VulcanForge
#18 Dec 30, 2020, 9:25 PM
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The answer is $k=2$; this can be achieved, for instance, when $a=3$. Now we show this is the best possible.

Assume otherwise that we could achieve three consecutive primes $y_1, y_2, y_3$; for obvious reasons, $x_1=a, x_2=2a+1, x_3=4a+3$ must also be prime. However, by quadratic reciprocity we have $$\left( \frac{2}{4a+3} \right) = (-1)^{(4a+4)(4a+2)/8} = (-1)^{(a+1)(2a+1)} = 1$$and so by Fermat's little theorem we have $2^{2a+1} \equiv 1 \pmod{4a+3}$. This contradicts the assumption that $y_2=2^{2a+1}-1$ is prime, because $2^{2a+1}-1>4a+3$ when $a \ge 2$.
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EulersTurban
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EulersTurban
#19 Dec 31, 2020, 12:11 AM
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Ultra nice problem and a great exercise for quadratic residues :D
$\color{black}\rule{25cm}{1pt}$
The maximal possible $k$ is $k=2$.

Because of the primality condition on $y$ we must have that all of the $x$'s must be prime as well.

Now we easily find a formula for $x$, by subtracting the $(n+1)^{th}$ equation from the $(n+2)^{nd}$ equation we have that the characteristic polynomial is $t^2-3t+2=0$, this implies that $x_n = A+B.2^n$.
Plugging in the what we got for $x$ we get that $A=-1$, and setting $n=1$ we have that $B=\frac{a+1}{2}$, thus we have that $x_n=2^{n-1}(a+1)-1$.
Thus we must have that the numbers $a,2a+1,4a+3,8a+7$ are all prime numbers.

But notice the following, we have that $2^{2a+1}=2^{\frac{4a+3-1}{2}}$, since $4a+3$ is prime from Euler's criterion we must have that $2^{2a+1} \equiv \left(\frac{2}{4a+3}\right)\pmod{4a+3}$.
We have that $\left(\frac{2}{4a+3}\right) \equiv (-1)^{\left\lfloor \frac{4a+3+1}{4} \right\rfloor} \equiv (-1)^{a+1} \pmod{4a+3}$.
Now if $a > 2$ we have that $y_3$ isn't prime, so we have that $a=2$.
But now we have that $y_3=2^{11}-1=23.89$, thus we have that $k=2$.
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jj_ca888
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jj_ca888
#21 Dec 31, 2020, 3:31 AM • 2 Y
Y by VulcanForge, itslumi
why are we all doing heavynt
Our answer is $k = 2$, which can be achieved when $a = 2$. Note that in general, $y_n$ prime implies that $x_n$ is prime; if $y_n$ is prime but $x_n$ is not, then $y_n = 2^{x_n} - 1$ is divisible by $2^m - 1$ for some $m \neq 1, x_n$ satisfying $m \mid x_n$, which is impossible.

We will prove that the maximum $k$ for which $x_1, \ldots , x_k$ are all prime is $2$, which finishes the problem. Suppose $(x_1, x_2, x_3) = (a, 2a+1, 4a+3)$ are all prime. We know $a = 2$ yields $k = 2$ so assume $a$ is an odd prime. Write\[2^{2a+1} \equiv 2^{\tfrac12(4a + 3 - 1)} = \left(\tfrac{2}{4a+3}\right) = (-1)^{\tfrac{1}{8}((4a + 3)^2 - 1)} \pmod{4a + 3}\]Since $a$ is odd write $a = 2b+1$, so\[\tfrac18((4a + 3)^2 - 1) = \tfrac18((8b + 7)^2 - 1) = (8b+6)(b+1)\]hence it follows that $2^{2a+1} \equiv 1 \pmod{4a+3}$. Clearly $4a + 3 < 2^{2a+1} - 1$ so $4a+3 \mid 2^{2a+1} - 1$ thus it follows that $2^{x_2} - 1$ has a prime factor, a contradiction.

Hence, we can have $k = 2$ at maximum, as desired. $\blacksquare$
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pad
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pad
#22 Feb 24, 2021, 8:40 AM
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We claim $k=2$ is the maximum. Firstly, $k=2$ works since taking $a=2$ gives $2^2-1=3$ and $2^5-1=31$, both primes. Now we show $k=3$ fails.

Let $S=\{a,2a+1,4a+3\}$ and suppose $2^s-1$ is prime for all $s\in S$. If $s$ is composite, then so is $2^s-1$ due to the well-known fact that $x\mid y \iff 2^x-1\mid 2^y-1$. Hence all elements of $S$ are prime.

Claim: We have $4a+3\mid 2^{2a+1}-1$.

Proof: Since $a$ is prime, $a\equiv 1\pmod2$, so $4a+3\equiv 7\pmod8$. Also, $4a+3$ is prime, so \[ \left(\frac{2}{4a+3}\right)=1 \implies 2^{2a+1}\equiv 1 \pmod{4a+3},\]as claimed. $\blacksquare$

However, the claim is a contradiction since $2^{2a+1}-1$ is prime.

Remarks
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ILOVEMYFAMILY
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ILOVEMYFAMILY
#23 Jun 24, 2021, 2:13 AM
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dr_Civot wrote:
Solution.
dr_Civot wrote:
Solution.

Why a>2 then a is odd?
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bora_olmez
277 posts
bora_olmez
#24 Aug 27, 2021, 11:33 AM
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Cool problem.

We claim that the largest $k$ is $2$ which is possible if $x_1 = 2, x_2 = 5$.
$\textbf{Claim:}$ $k < 2$
$\textbf{Proof)}$
Assume that $2^{x_1}-1, 2^{x_2}-1, 2^{x_3}-1$ are all primes from which we get that $x_1, x_2, x_3$ are all primes as well because if we let $x_i = a \cdot b$ for some $i \in \{1,2,3\}$, then $$2^{a}-1 \mid 2^{ab}-1$$We therefore have that $p = x_1, 2p+1, 4p+3$ are all primes such that $2^p-1, 2^{2p+1}-1, 2^{4p+3}-1$ are all primes, as well with $p \neq 2$ as $2^11-1$ is not prime.
Notice that $$2^p-1 \equiv 2^{\frac{(2p+1)-1}{2}} - 1 \equiv 0 \pmod{2p+1}$$if $2$ is a quadratic residue $\pmod{2p+1}$ which is not possible, consequently, $2$ has to be a quadratic non-residue $\pmod{2p+1}$ and $\pmod{4p+3}$.
Then $2p+1 \equiv 3,5 \pmod{8}$, yet if $2p+1 \equiv 5 \pmod{8}$, then $p$ has to be even meaning that $2p+1 \equiv 3 \pmod{8}$.
Then $$4p+3 \equiv 2(2p+1)+1 \equiv 2\cdot 3 +1 \equiv 7 \pmod{8} $$meaning that $2$ is a quadratic residue $\pmod{4p+3}$ which is a contradiction. $\blacksquare$
This post has been edited 1 time. Last edited by bora_olmez, Aug 27, 2021, 11:33 AM
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sriraamster
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sriraamster
#25 Oct 2, 2021, 3:03 AM
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The answer is $k = 2.$

Remark that since $2^{m}-1 \mid 2^{n}-1$ when $m \mid n,$ it follows that all of $\{x_1, \dots, x_k \}$ must be prime. Now, assume we had three primes $a, 2a+1, 4a+3$ such that $2^{a}-1, 2^{2a+1}-1$, and $2^{4a+3}-1$ are all prime.

Claim: $4a+3 \mid 2^{2a+1}-1.$

We have \[ \left( \frac{2}{4a+3} \right) = (-1)^{1/8 ((4a+3)^2-1)} = (-1)^{(2a+1)(a+1)} = 1 \]if $a$ is an odd prime. If $a = 2,$ then $y_1 = 2^2-1 = 3, y_2 = 2^5-1 = 31$ and $y_3 = 2^11-1 = 2047,$ which is not prime. Hence, as we also have \[ \left( \frac{2}{4a+3} \right) = 2^{2a+1} \equiv 1 \pmod{4a+3} \]under the assumption that $4a+3$ is prime, we thus have $4a+3 \mid 2^{2a+1}-1.$

Hence, it is impossible to have three primes $a, 2a+1,$ and $4a+3$ such that all of $2^{a}-1, 2^{2a+1}-1,$ and $2^{4a+3}-1$ are prime, meaning we can have at most $k=2,$ which holds by taking $a=2.$
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HamstPan38825
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HamstPan38825
#26 Apr 23, 2023, 2:54 AM
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The answer is $k=2$. For construction, take $a=2$.

Now suppose $k \geq 3$. I will show one of the first three terms is composite. Assume for the sake of contradiction that $a, 2a+1, 4a+3$ are all primes.

Assume that $a$ is odd; $a=2$ can be quickly checked. Now note that $4a+3 \equiv -1 \pmod 8$, thus $\left(\frac 2{4a+3}\right) = 1$ and thus $4a+3 \mid 2^{x_2} - 1 = 4a+3$ as by assumption $2^{x_2} - 1$ is prime. But this obviously impossible for size reasons.
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egxa
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egxa
#27 Aug 7, 2023, 10:42 AM
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Easy to see if $a=1,2$ $k=2$.
Let $a\ge3$
Obvious that all of $x_i$ are prime.
Let $x_1=p$. From quadratic residue we get $(\frac{-2}{4p+3})=1=(\frac{-1}{4p+3}).(\frac{2}{4p+3})$ so
$(\frac{2}{4p+3})=-1$ and $p$ must be even. Contradiction. $\blacksquare$
This post has been edited 1 time. Last edited by egxa, Aug 7, 2023, 2:49 PM
Reason: typo
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Pyramix
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Pyramix
#28 Apr 7, 2024, 7:07 AM
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We know that if $2^t-1$ is a prime, then $t$ itself must be a prime, because if $t'\mid t$ then $2^{t'}-1\mid 2^t-1$. Hence, $x_1, x_2, \ldots, x_k$ must be prime. Note that if $2^{\text{odd}}-1$ is a prime $p$, then $2$ is Quadratic Residue $\pmod{p}$ and hence $p\equiv \pm1\pmod{8}$. Note that $x_3=4x_1+3$ and $x_3\equiv 7\pmod{8}$. Note that $2^{\frac{x_3-1}2}\equiv1\pmod{x_3}$ as $x_3\equiv-1\pmod{8}$. This means that $x_3\mid y_2$ and hence $x_3=y_2$ which is possible only if $x_3=7$ but then $7\mid y_4=2^{15}-1$. So, largest possible $k$ is $2$ because $2^1-1,2^3-1,2^7-1$ are not all prime because first term is 1. $\blacksquare$
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shendrew7
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shendrew7
#29 Apr 20, 2024, 7:43 PM
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Notice we must have $x_1, x_2, \ldots$ prime. Our main claim states that if $x_i \equiv 3 \pmod 4$ and $x_{i+1} = 2x_i+1 \equiv 3 \pmod 4$ are prime, we have $x_{i+1} \mid 2^{x_i}-1 = y_i$. This holds, as
\[2^{x_i} \equiv 2^{\frac{x_{i+1}-1}{2}} \equiv \left(\frac{2}{x_{i+1}}\right) \equiv 1 \pmod{x_{i+1}}.\]
Thus we can consider cases using this claim, and denote $K$ as the maximum possible value of $k$ in that case.
  • $a=2$: $K=2$.
  • $a \equiv 3 \pmod 4$: Then $x_1 \equiv x_2 \equiv 3 \pmod 4$. If $x_2$ is prime, then $x_1$ is composite, so $K=0$. If $x_2$ is composite, then $K=1$.
  • $a \equiv 1 \pmod 4$: Then $x_2 \equiv x_3 \equiv 3 \pmod 4$, so we can find $K \leq 2$ in a similar fashion.

Thus our answer is $k = \boxed{2}$, which can be achieved using $a=2$. $\blacksquare$
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Markas
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Markas
#30 Jul 13, 2024, 3:03 PM
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Let a = 2, $x_1 = 2$, $y_1 = 3$, $y_2 = 31$, $y_3 = 2047 = 23.89$ $\Rightarrow$ this is an example for k = 2. We will prove that $k < 3$. For this, assume that $y_1$, $y_2$ and $y_3$ are prime. If $b \mid a$ then $2^b - 1 \mid 2^a - 1$ - impossible $\Rightarrow$ a is prime $\Rightarrow$ all $x_i$ are prime. Now let $x_1$ be an odd prime since we checked the case for a = 2. Since $x_1$ is odd we get that $x_3 \equiv 7 \pmod 8$. We will show that for any prime $p \equiv 7 \pmod 8$, $2^{\frac{p-1}{2}} \equiv 1 \pmod p$. Thats true because $\left( \frac{2}{p} \right) = (-1)^{\frac{p^2-1}{2}} = 1$ and $1 \equiv \left( \frac{2}{p} \right) \equiv 2^{\frac{p-1}{2}} \pmod p$. Using this we get $2^{x_2}-1 \equiv 0 \pmod {x_3}$ $\Rightarrow$ $x_3 \mid y_2$ $\Rightarrow$ $x_3 = y_2$, but for $a \geq 3$ we have that $2^{2a +1}-1 > 4a+3$ since $2^{2a-1} > 2^a +1 > a+1$. So $y_2 = 2^{x_2}-1$ is composite, which is impossible and we get our contradiction $\Rightarrow$ k = 2.
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OronSH
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OronSH
#31 Sep 30, 2024, 3:45 AM • 2 Y
Y by megarnie, Funcshun840
The answer is $k=2$.

Check $a=1,2$. Next suppose $k=3$ is possible. We may assume $a=p$ is an odd prime and so are $2p+1,4p+3$. If $p\equiv 1\pmod 2$ then $4p+3\equiv 7\pmod 8$ so $2$ is a quadratic residue $\pmod{4p+3}$. Now consider the order of $2 \pmod{4p+3}$. It divides $4p+2$ but must be odd, so it is $2p+1$ and $4p+3\mid 2^{2p+1}-1$ so it is not prime, contradiction.
This post has been edited 1 time. Last edited by OronSH, Oct 1, 2024, 1:33 PM
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L13832
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L13832
#32 Jan 20, 2025, 7:36 AM • 2 Y
Y by alexanderhamilton124, Nobitasolvesproblems1979
solution
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cursed_tangent1434
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cursed_tangent1434
#33 Apr 30, 2025, 10:16 AM
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We claim that the answer is $k=2$ which is easily achieved when $a=2$ since $2^2-1=3$ and $2^5-1=31$ are both prime. We now show that it is impossible to have $k>2$. If there exists some positive integer $a$ for which $k>2$ note that $a>2$ as well, since $a=1$ and $a=2$ yield $k=0$ (since apparently one is not a prime) and $k=2$ respectively.

By assumption $y_1,y_2$ and $y_3$ are all prime and hence $x_1,x_2$ and $x_3$ are also all prime since if $t <x_i \mid x_i$ then,
\[2^t-1 \mid 2^{x_i}-1=y_i\]making it non-prime. However we may write $x_i = 2^{i-1}a+(2^{i-1}-1)$ for all positive integers $i$. Since $a>2$ and prime, $a$ must be odd. Hence,
\[x_3=2^{2}a+(2^2-1) = 4a+3 =4(2a'+1)+3 = 8a'+7 \equiv -1 \pmod{8}\]But now, if $x_3 \equiv -1 \pmod{8}$ is a prime, the Law of Quadratic Reciprocity states that $2$ is a quadratic residue $\pmod{x_3}$. Thus,
\[y_2 = 2^{x_2}-1 \equiv (r^2)^{x_2}-1 = r^{2x_2}-1 \equiv 0 \pmod{2x_2+1}\]since $2x_2+1=x_3$ is prime. But this means $2x_2+1 \mid 2^{x_2}-1$. Also, for all $x_2 \ge 4$,
\[2x_2+1 < 2^{x_2}-1\]which implies that we must have $x_2 <4$. However since $x_2=4a+3 \ge 4(1)+3=7 >3$ this is a clear contradiction so it is indeed impossible for $y_1,y_2$ and $y_3$ to all be prime for any choice of $a$.
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