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k a May Highlights and 2025 AoPS Online Class Information
jlacosta   0
May 1, 2025
May is an exciting month! National MATHCOUNTS is the second week of May in Washington D.C. and our Founder, Richard Rusczyk will be presenting a seminar, Preparing Strong Math Students for College and Careers, on May 11th.

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0 replies
jlacosta
May 1, 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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find positive n so that exists prime p with p^n-(p-1)^n$ a power of 3
parmenides51   14
N 3 minutes ago by MathLuis
Source: JBMO Shortlist 2017 NT5
Find all positive integers $n$ such that there exists a prime number $p$, such that $p^n-(p-1)^n$ is a power of $3$.

Note. A power of $3$ is a number of the form $3^a$ where $a$ is a positive integer.
14 replies
parmenides51
Jul 25, 2018
MathLuis
3 minutes ago
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GCD of terms in a sequence
BBNoDollar   1
N 16 minutes ago by mashumaro
Determine the general term of the sequence of non-zero natural numbers (a_n)n≥1, with the property that gcd(a_m, a_n, a_p) = gcd(m^2 ,n^2 ,p^2), for any distinct non-zero natural numbers m, n, p.

⁡Note that gcd(a,b,c) denotes the greatest common divisor of the natural numbers a,b,c .
1 reply
BBNoDollar
4 hours ago
mashumaro
16 minutes ago
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Diodes and usamons
v_Enhance   46
N 37 minutes ago by HamstPan38825
Source: USA December TST for the 56th IMO, by Linus Hamilton
A physicist encounters $2015$ atoms called usamons. Each usamon either has one electron or zero electrons, and the physicist can't tell the difference. The physicist's only tool is a diode. The physicist may connect the diode from any usamon $A$ to any other usamon $B$. (This connection is directed.) When she does so, if usamon $A$ has an electron and usamon $B$ does not, then the electron jumps from $A$ to $B$. In any other case, nothing happens. In addition, the physicist cannot tell whether an electron jumps during any given step. The physicist's goal is to isolate two usamons that she is sure are currently in the same state. Is there any series of diode usage that makes this possible?

Proposed by Linus Hamilton
46 replies
1 viewing
v_Enhance
Dec 17, 2014
HamstPan38825
37 minutes ago
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China South East Mathematical Olympiad 2013 problem 2
s372102   3
N 37 minutes ago by AGCN
$\triangle ABC$, $AB>AC$. the incircle $I$ of $\triangle ABC$ meet $BC$ at point $D$, $AD$ meet $I$ again at $E$. $EP$ is a tangent of $I$, and $EP$ meet the extension line of $BC$ at $P$. $CF\parallel PE$, $CF\cap AD=F$. the line $BF$ meet $I$ at $M,N$, point $M$ is on the line segment $BF$, the line segment $PM$ meet $I$ again at $Q$. Show that $\angle ENP=\angle ENQ$
3 replies
s372102
Aug 10, 2013
AGCN
37 minutes ago
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f(x+y) = max(f(x), y) + min(f(y), x)
Zhero   50
N an hour ago by lpieleanu
Source: ELMO Shortlist 2010, A3
Find all functions $f: \mathbb{R} \to \mathbb{R}$ such that $f(x+y) = \max(f(x),y) + \min(f(y),x)$.

George Xing.
50 replies
Zhero
Jul 5, 2012
lpieleanu
an hour ago
J
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Similar to iran 1996
GreekIdiot   1
N an hour ago by Lufin
Let $f: \mathbb R \to \mathbb R$ be a function such that $f(f(x)+y)=f(f(x)-y)+4f(x)y \: \forall x,y \: \in \: \mathbb R$. Find all such $f$.
1 reply
GreekIdiot
Apr 26, 2025
Lufin
an hour ago
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Prove that 4p-3 is a square - Iran NMO 2005 - Problem1
sororak   24
N an hour ago by EmersonSoriano
Let $n,p>1$ be positive integers and $p$ be prime. We know that $n|p-1$ and $p|n^3-1$. Prove that $4p-3$ is a perfect square.
24 replies
sororak
Sep 21, 2010
EmersonSoriano
an hour ago
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IMO ShortList 1999, combinatorics problem 4
orl   27
N an hour ago by cursed_tangent1434
Source: IMO ShortList 1999, combinatorics problem 4
Let $A$ be a set of $N$ residues $\pmod{N^{2}}$. Prove that there exists a set $B$ of of $N$ residues $\pmod{N^{2}}$ such that $A + B = \{a+b|a \in A, b \in B\}$ contains at least half of all the residues $\pmod{N^{2}}$.
27 replies
orl
Nov 14, 2004
cursed_tangent1434
an hour ago
J
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Geometry
Lukariman   2
N an hour ago by Lukariman
Given circle (O) and point P outside (O). From P draw tangents PA and PB to (O) with contact points A, B. On the opposite ray of ray BP, take point M. The circle circumscribing triangle APM intersects (O) at the second point D. Let H be the projection of B on AM. Prove that <HDM = 2∠AMP.
2 replies
Lukariman
Yesterday at 12:43 PM
Lukariman
an hour ago
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IMO 2010 Problem 1
canada   119
N an hour ago by lpieleanu
Find all function $f:\mathbb{R}\rightarrow\mathbb{R}$ such that for all $x,y\in\mathbb{R}$ the following equality holds \[ f(\left\lfloor x\right\rfloor y)=f(x)\left\lfloor f(y)\right\rfloor \] where $\left\lfloor a\right\rfloor $ is greatest integer not greater than $a.$

Proposed by Pierre Bornsztein, France
119 replies
canada
Jul 7, 2010
lpieleanu
an hour ago
J
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f(n) <= f(a(G)) + f(b(G))
dangerousliri   5
N 2 hours ago by awesomeming327.
Source: FEOO, Problem 2, Shortlist C2
Given a group $G$ of people, we define $a(G)$ to be the least number of tables needed such that each person from the group sits in one of them with no two friends sitting on the same table, and $b(G)$ to be the least number of tables needed such that each person from the group sits in one of them with no two enemies sitting on the same table.
Consider all functions $f:\mathbb{N} \to \mathbb{N}$ such that for each group $G$ of $n$ people we have
\[ f(n) \leqslant f(a(G)) + f(b(G)) \quad \text{and} \quad f(2) = 1.\]Find all possible values of $f(2020)$.

Note: We assume that for every pair of people in a group, they are either both friends with each other or both enemies with each other. Also, $\mathbb{N}$ is the set of all positive integers.

Proposed by Demetres Christofides, Cyprus
5 replies
dangerousliri
May 30, 2020
awesomeming327.
2 hours ago
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f(w^2+x^2+y^2+z^2)=f(w^2+x^2)+f(y^2+z^2)
dangerousliri   23
N 2 hours ago by awesomeming327.
Source: FEOO, Problem 1, Shortlist N1
Find all functions $f:\mathbb{N}_0\rightarrow\mathbb{R}$ such that,
$$f(w^2+x^2+y^2+z^2)=f(w^2+x^2)+f(y^2+z^2)$$for all non-negative integers $w,x,y$ and $z$.

Note: $\mathbb{N}_0$ is the set of all non-negative integers and $\mathbb{R}$ is the set of all real numbers.

Proposed by Dorlir Ahmeti, Kosovo
23 replies
dangerousliri
May 30, 2020
awesomeming327.
2 hours ago
J
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Darboux cubic
srirampanchapakesan   0
2 hours ago
Source: Own
Let P be a point on the Darboux cubic (or the McCay Cubic ) of triangle ABC.

P1P2P3 is the circumcevian or pedal triangle of P wrt ABC.

Prove that P also lie on the Darboux cubic ( or the McCay Cubic) of P1P2P3 .
0 replies
srirampanchapakesan
2 hours ago
0 replies
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primitive polyominoes
N.T.TUAN   29
N 3 hours ago by Disjunction
Source: USAMO 2007
An animal with $n$ cells is a connected figure consisting of $n$ equal-sized cells[1].

A dinosaur is an animal with at least $2007$ cells. It is said to be primitive it its cells cannot be partitioned into two or more dinosaurs. Find with proof the maximum number of cells in a primitive dinosaur.

(1) Animals are also called polyominoes. They can be defined inductively. Two cells are adjacent if they share a complete edge. A single cell is an animal, and given an animal with $n$ cells, one with $n+1$ cells is obtained by adjoining a new cell by making it adjacent to one or more existing cells.
29 replies
N.T.TUAN
Apr 26, 2007
Disjunction
3 hours ago
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IMO ShortList 2008, Number Theory problem 3
April   24
N Apr 29, 2025 by sansgankrsngupta
Source: IMO ShortList 2008, Number Theory problem 3
Let $ a_0$, $ a_1$, $ a_2$, $ \ldots$ be a sequence of positive integers such that the greatest common divisor of any two consecutive terms is greater than the preceding term; in symbols, $ \gcd (a_i, a_{i + 1}) > a_{i - 1}$. Prove that $ a_n\ge 2^n$ for all $ n\ge 0$.

Proposed by Morteza Saghafian, Iran
24 replies
April
Jul 9, 2009
sansgankrsngupta
Apr 29, 2025
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IMO ShortList 2008, Number Theory problem 3
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Reveal topic tags
greatest common divisor
number theory
Sequence
IMO Shortlist
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Source: IMO ShortList 2008, Number Theory problem 3
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April
1270 posts
April
#1 Jul 9, 2009, 10:27 PM • 5 Y
Y by Davi-8191, anantmudgal09, Adventure10, Mango247, kiyoras_2001
Let $ a_0$, $ a_1$, $ a_2$, $ \ldots$ be a sequence of positive integers such that the greatest common divisor of any two consecutive terms is greater than the preceding term; in symbols, $ \gcd (a_i, a_{i + 1}) > a_{i - 1}$. Prove that $ a_n\ge 2^n$ for all $ n\ge 0$.

Proposed by Morteza Saghafian, Iran
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Allnames
925 posts
Allnames
#2 Jul 10, 2009, 6:12 AM • 2 Y
Y by Adventure10, Mango247
April wrote:
Let $ a_0$, $ a_1$, $ a_2$, $ \ldots$ be a sequence of positive integers such that the greatest common divisor of any two consecutive terms is greater than the preceding term; in symbols, $ \gcd (a_i, a_{i + 1}) > a_{i - 1}$. Prove that $ a_n\ge 2^n$ for all $ n\ge 0$.
I use $ (a;b)$ as $ gcd(a;b)$.
I prove this nice problem by induction.
It is obvious to see that $ a_n > a_{n - 1}\forall n\in N$
Firstly, $ a_0\ge 1$. Let $ (a_1;a_2) = d > a_0\ge 2$. Thus $ a_1\ge 2$, $ a_2 = kd \ge 4$ because $ k\ge 2$.
Suppose that this problem has been right until $ n - 1$. It means $ a_i\ge 2^i \forall i\le n - 1$.
Assume that $ 2^{n - 1}\le a_{n - 1} < a_n < 2^n$. Let $ (a_n;a_{n - 1}) = d > a_{n - 2}\ge 2^{n - 2}$ and $ a_n = kd < 2^n;k\ge 2$.
Because $ d\ge 2^{n - 2}$, if $ k\ge 4$ then $ a_n = kd\ge 2^n$ contr.It implies $ k = 2$ or $ k = 3$.
Case I: $ k = 2$ then $ a_{n - 1} = d\ge 2^{n - 1}$(induction hypothesis) and $ a_n = 2d\ge 2^n$ which is contradiction !.
Case II: $ k = 3$ then if $ a_{n - 1} = d$ by the same argument above, we have the contradiction .
It means $ a_n = 3d;a_{n - 1} = 2d$.Let $ (a_{n - 2};2d) = T > a_n - 3\ge 2^{n - 3}$. Hence $ 2d = aT,a\ge 2$
$ a\ge 2$ implies $ T < 2^{n - 1}$(since $ 2^{n - 1}\le 2d = aT < 2^n$). If $ a\ge 4$ then $ aT\ge 2^{n - 1}$.It is impossible.
Then $ a = 2$ or $ a = 3$.
Case1: $ a = 2$ then $ d = T$ then $ a_{n - 2} = T\ge 2^{n - 2}$ then $ d\ge 2^{n - 1}$. Impossible!.
Case 2: $ k = 3$. If $ a_{n - 2} = T$ then $ a_{n - 1} = 3T\ge 3.2^{n - 2}$ then $ a_n = 1,5 a_{n - 1}\ge 4,5.2^{n - 2} > 2^n$ contradiction.
It means $ 2d = 3T$ and $ a_{n - 2} = 2T$ . Thus $ d = 1,5T < a_{n - 2}$. But $ (a_n;a_{n - 1}) = d > a_{n - 2}$ since initial hypothesis.
So that assumption is wrong then $ a_n\ge 2^n$.
I hope I don't make any stupid mistakes.
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mr bui
13 posts
mr bui
#3 Jul 11, 2009, 4:52 PM • 1 Y
Y by Adventure10
Sorry sir!!!!
But we have a sequence isn't satisfy above condition:
$ a_0=1,a_1=2,a_2=6,a_3=6$, but $ a_3<2^3=8$.....
I thinks we have other condition in this problem.
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bboypa
469 posts
bboypa
#5 Jul 13, 2009, 2:17 AM • 4 Y
Y by liimr, rtsiamis, Adventure10, Mango247
April wrote:
Let $ a_0$, $ a_1$, $ a_2$, $ \ldots$ be a sequence of positive integers such that the greatest common divisor of any two consecutive terms is greater than the preceding term; in symbols, $ \gcd (a_i, a_{i + 1}) > a_{i - 1}$. Prove that $ a_n\ge 2^n$ for all $ n\ge 0$.

Our aim $ a_n \ge 2^n$(*) is true for $ n \in \{0,1\}$, in fact $ a_1=1$ would imply $ 1=(a_2,a_1)>a_0 \in \mathbb{N}_0$, absurd. It is also true that $ \{a_n\}_{n \in \mathbb{N}}$ is strictly incrasing since $ \min\{a_{n+1},a_{n+2}\}$ $ \ge (a_{n+1},a_{n+2})$ $ >a_n$. Now if (*) is true for $ n \in \{0,1,\ldots,n-1\}$ then it is true also for $ n$: in fact we have $ a_n-a_{n-1}$ $ \ge (a_n-a_{n-1},a_{n-1})$ $ =(a_n,a_{n-1}) >a_{n-2} \implies$ $ a_n > a_{n-1}+a_{n-2}$. Now if $ \frac{a_{n-1}}{3} \ge (a_{n-1},a_n)> a_{n-2}$ then we are done since $ a_n>a_{n-1}+a_{n-2} \ge 4a_{n-2} \ge 2^n$. Otherwise $ \frac{a_{n-1}}{2}=(a_n,a_{n-1})$. Now if $ a_n \ge 2a_{n-1}$ we are done, otherwise it means that $ 2 \mid a_{n-1}$, $ 3 \nmid a_{n-1}$ and $ a_n=\frac{3}{2}a_{n-1}$. Now if $ \frac{a_{n-1}}{4} \ge a_{n-2} \implies a_n>a_{n-1} \ge 2^n$, in the last last case (since $ 3 \nmid a_{n-1}$) we must have $ (a_{n-2},a_{n-1})=\frac{a_{n-1}}{2}$, but $ \frac{a_{n-1}}{2}=(a_n,a_{n-1})>a_{n-2}=\frac{a_{n-1}}{2}$, contradiction.
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liimr
34 posts
liimr
#6 Jul 6, 2013, 7:24 PM • 1 Y
Y by Adventure10
bboypa wrote:
in the last last case (since $ 3 \nmid a_{n-1}$) we must have $ (a_{n-2},a_{n-1})=\frac{a_{n-1}}{2}$, but $ \frac{a_{n-1}}{2}=(a_n,a_{n-1})>a_{n-2}=\frac{a_{n-1}}{2}$, contradiction.
this part i think has problem
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JuanOrtiz
366 posts
JuanOrtiz
#7 Apr 26, 2014, 3:18 AM • 4 Y
Y by mathocean97, HolyMath, Adventure10, Mango247
It is a pity that there are no correct solutions here.

Here is my solution. Basically I used $3^2 \textgreater 2^3$, and other similar inequalities.

We use induction. Trivially $a$ is increasing, and we can check by hand that $a_i \ge 2^i$ for $i \le 4$.

Now assume $a_m \ge 2^m$ for $i \le n$, and assume $a_{n+1} \textless 2^{n+1}$. If $a_n | a_{n+1}$ we achieve a contradiction since $a_{n+1} \ge 2a_n$. Therefore $a_n$ doesn't divide $a_{n+1}$. Let $d=(a_n, a_{n+1}) \textgreater a_{n-1}$. If $a_{n+1} \ge 4d$ we're done, and if $a_{n+1} \le 2d$ then $a_n | a_{n+1}$. Therefore $a_{n+1}=3d$ and so $a_n=2d$.

Let $e=(2d,a_{n-1}) \textgreater a_{n-2} \ge 2^{n-2}$. Recall $d \textgreater a_{n-1}$. If $a_{n-1} | 2d$ then $a_{n-1} \le \frac{2d}{3}$ we see $3d \ge 9(2^{n-2})$ so we're done. So we get $a_{n-1} \neq e$, so $a_{n-1} \ge 2e$. But if $a_{n-1} \ge 3e$ then $3d \textgreater 3a_{n-1} \ge 9e \textgreater 9a_{n-2} \ge 9(2^{n-2})$ so we're done. From this we get $a_{n-1}=2e$ and so $e \ge 2^{n-2}$. If $2d \ge 6e$ then $3d \ge 9e \ge 9(2^{n-2})$ so we're done. Therefore $3e \le 2d \le 5e$. Since $d=(a_{n+1},a_n) \textgreater a_{n-1}=2e$ we get $2d \ge 4e$. Therefore $2d=5e$. So we can write $a_{n+1}=15f$, $a_n=10f$, $a_{n-1}=4f$.

Let $X = a_{n-2} \textless (a_n, a_{n-1})=2f$. Redefine $d$ so that $d=(a_{n-1},a_{n-2}) \textgreater a_{n-3} \ge 2^{n-3}$. Let $T=4f/d$. If $T \ge 5$ then $4f \ge 5d \ge 5(2^{n-3})$ and so $2^{n+1} \textgreater 15f \ge 5d(15/4) \ge 2^{n-3}(75/4) \textgreater 2^{n+1}$, contradiction. Since $X \textless 2f$ then $d \textless 2f$ and so $T \ge 3$. So $d=f$ or $4f/3$ and $d | X\le 2f$ and so we see $X=d$. So $d \ge 2^{n-2}$ and from this, $4f = Td \ge 3d \ge 3(2^{n-2})$ and so $15f \ge 3(2^{n-2})(\frac{15}{4}) \textgreater 2^{n+1}$ so we're done.

Such an ugly problem :(
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xdiegolazarox
42 posts
xdiegolazarox
#9 Feb 12, 2016, 4:12 AM • 2 Y
Y by Adventure10, Mango247
My solution :) :
It is obvious to see that $ a_n > a_{n - 1}\forall n\in N$.It is easy to see that true for $n = 0$,$1$,$2$,$3$,$4$. Now suppose that is true for $n = 0$,$1$,$2$ ... $k$ , $ k\ge 4$ .We assume that $ a_{k+1}<2^{k + 1}$ ,then it is easy to see that $ a_{k+1}< {2a_{k},4a_{k-1}}$, also $a_{k-1} < (a_{k}; a_{k+1}) \mid a_{k+1} - a_{k}$, also $a_{k} = p(a_{k}; a_{k+1})$ , then $4a_{k-1} >a_{k+1} \ge (p+1) (a_{k}; a_{k+1})> (p+1) (a_{k-1})$, then $ p \le 2$, but $p=1$ implies that $a_{k+1} \ge 2 a_{k}$ (contradiction) , then $p=2$ and $2a_{k+1}=3a_{k}$, in particular $a_{k+1}=3R$ and $a_{k}=2R$ , $R= (a_{k}; a_{k+1})$, but $ a_{k+1}<4a_{k-1} \implies a_{k-1} >\frac{3}{4}R$ , also $a_{k-1}<R$ ,let $Q= (a_{k}; a_{k-1}) \implies 2^{k-2}<Q=\frac{a_{k}-a_{k-1}}{X} < \frac{5R}{4X} \implies 2^{k+1}>3R>\frac{2^{k}3X}{5} \implies X\le3$ ,but $ R > a_{k-1}\ge Q=\frac{a_{k}-a_{k-1}}{X} \implies R>\frac{a_{k}}{X+1} = \frac{2R}{X+1} \implies X\ge2$ , but $X=2 \implies Q=\frac{a_{k}-a_{k-1}}{2} < \frac{a_{k}}{2} $ and $ a_{k-1}<R=\frac{a_{k}}{2} \implies \frac{a_{k}-a_{k-1}}{2} > \frac{a_{k}}{4} \implies \frac{a_{k}}{3}=\frac{a_{k}-a_{k-1}}{2} \implies \frac{3}{4}R<a_{k-1}=\frac{a_{k}}{3}=\frac{2R}{3}$ (contradiction), then $X=3$ ,also $Q=\frac{2R-a_{k-1}}{3} > \frac{2R}{6}$ and $a_{k-1} >\frac{3}{4}R>\frac{R}{2} \implies Q=\frac{2R-a_{k-1}}{3}< \frac{2R}{4} \implies Q=\frac{2R}{5}\implies a_{k-1}=\frac{4R}{5}$ ,let $T=(a_{k-1}; a_{k-2})=\frac{a_{k-2}}{Y} \implies\frac{2(2^{k+1})}{15}>\frac{2R}{5}>a_{k-2}>Y(a_{k-3})>Y(2^{k-3}) \implies 32>15Y \implies Y\le2$ ,but $Y=1 \implies T=a_{k-2} \implies a_{k-2}\mid \frac{4R}{5}$ and $a_{k-2}<\frac{2R}{5} \implies 2^{k-2}< a_{k-2} \le \frac{4R}{15}< \frac{4(2^{k+1})}{45} $ (contradiction),then $Y=2 \implies \frac{a_{k-2}}{2} \mid \frac{4R}{5} \implies a_{k-2} \mid \frac{8R}{5}$,but $ a_{k-2}\textless \frac{2R}{5}=\frac{8R}{(4)5} \implies 2^{k-2}\textless a_{k-2}\le \frac{8R}{25}\textless \frac{8(2^{k+1})}{75}$ (contradiction) ,then $a_{k+1}\ge 2^{k + 1}$ ,with what would be complete induction . :D
This post has been edited 1 time. Last edited by xdiegolazarox, Feb 12, 2016, 4:14 AM
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Stranger8
238 posts
Stranger8
#10 Mar 29, 2016, 3:59 PM • 1 Y
Y by Adventure10
mr bui wrote:
Sorry sir!!!!
But we have a sequence isn't satisfy above condition:
$ a_0=1,a_1=2,a_2=6,a_3=6$, but $ a_3<2^3=8$.....
I thinks we have other condition in this problem.


All terms in this sequence satisfy this condition not part of them ,directly you won't find an integer $a_4$ that satisfies this condition following your sequence
This post has been edited 1 time. Last edited by Stranger8, Sep 26, 2016, 1:21 AM
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bobthesmartypants
4337 posts
bobthesmartypants
#11 Apr 11, 2017, 1:20 AM • 2 Y
Y by Anar24, Adventure10
solution
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cip999
3645 posts
cip999
#12 Jun 18, 2017, 9:24 PM • 32 Y
Y by Anar24, nmd27082001, rmtf1111, anantmudgal09, Naysh, Arc_archer, pavel kozlov, toto1234567890, Phie11, MathbugAOPS, JasperL, MNJ2357, HolyMath, Supercali, MarkBcc168, rashah76, XbenX, parola, Elyson, Mathematicsislovely, guptaamitu1, Wizard0001, tapir1729, VicKmath7, Infinityfun, Adventure10, Mango247, math_comb01, SerdarBozdag, IMUKAT, puffypundo, megarnie
I think this problem deserves more than it seems, so here's a proof not going through some dreadful induction and massive casework.

First, let $\frac{a_{n + 1}}{a_n} = \frac{x_n}{y_n}$, where $x_n$, $y_n$ are positive integers and $(x_n, \: y_n) = 1$. Then we get $$(a_{n + 1}, \: a_{n + 2}) = \frac{a_{n + 1}}{y_{n + 1}} > a_n \implies y_{n + 1} < \frac{a_{n + 1}}{a_n} = \frac{x_n}{y_n} \implies \frac{x_n}{y_n} \ge y_{n + 1} + \frac{1}{y_n}$$Now observe that $$a_n = a_0 \cdot \frac{a_1}{a_0} \cdots \frac{a_n}{a_{n - 1}} = a_0 \cdot \frac{x_0}{y_0} \cdots \frac{x_{n - 1}}{y_{n - 1}} \ge a_0\left(y_1 + \frac{1}{y_0}\right)\cdots\left(y_n + \frac{1}{y_{n - 1}}\right)$$By AM-GM $y_{i + 1} + \frac{1}{y_i} \ge 2\sqrt{\frac{y_{i + 1}}{y_i}}$; furthermore, since $a_1 = \frac{x_0}{y_0}a_0$, $y_0 \mid a_0 \implies a_0 \ge y_0$. Thus we have $$a_n \ge a_0\left(y_1 + \frac{1}{y_0}\right)\cdots\left(y_n + \frac{1}{y_{n - 1}}\right) \ge y_0\left(2\sqrt{\frac{y_1}{y_0}}\right)\cdots\left(2\sqrt{\frac{y_n}{y_{n - 1}}}\right) = 2^n\sqrt{y_0y_n} \ge 2^n$$which ends the proof.
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anantmudgal09
1980 posts
anantmudgal09
#13 May 30, 2018, 11:56 PM • 3 Y
Y by Saikat002, Adventure10, Mango247
I'm writing this late at night so please let me know if you spot any errors :)
April wrote:
Let $ a_0$, $ a_1$, $ a_2$, $ \ldots$ be a sequence of positive integers such that the greatest common divisor of any two consecutive terms is greater than the preceding term; in symbols, $ \gcd (a_i, a_{i + 1}) > a_{i - 1}$. Prove that $ a_n\ge 2^n$ for all $ n\ge 0$.

Proposed by Morteza Saghafian, Iran

Note that $a_k \ge (a_k,a_{k+1})>a_{k-1}$ for all $k>0$. Note $a_0 \ge 1$ and $a_1>a_0\ge 1$ hence $a_1 \ge 2$. Now if $a_2=3$ then $(a_2,a_1)=1$; false! So $a_2 \ge 4$. Now pick the minimal $k>1$ with $a_{k+1}<2^{k+1}$. Then $2^k \le a_k<a_{k+1}<2^{k+1}$ and $k>1$ and $(a_{k+1}, a_k)>a_{k-1} \ge 2^{k-1}$.

Notice that $a_k \nmid a_{k+1}$ hence $(a_{k+1}, a_k) \le \frac{a_k}{2}$ so $a_k> 2a_{k-1}$. Also $a_{k+1}-a_k \ge (a_{k+1}, a_k)>2^{k-1}$ hence $a_k<3 \cdot 2^{k-1}$. Now if $(a_{k-1}, a_k) \ne a_k-2a_{k-1}$ then $(a_{k-1}, a_k)\le \frac{a_k-2a_{k-1}}{2} \le \frac{2^{k-1}}{2}<a_{k-2}$ a contradiction! Hence $a_k=n_1(a_k-2a_{k-1})$ for some integer $n_1>1$. Then $a_k=\frac{2n_1}{n_1-1}a_{k-1}$ and $a_k<3a_{k-1} \implies n_1>3$.

Now $(a_{k-1}, a_k)=\frac{a_{k-1}}{n_1-1}$ if $n_1-1$ is odd else $(a_{k-1}, a_k)=\frac{2a_{k-1}}{n_1-1}$ if $n_1-1$ is even. Either way, $a_{k-1}>2a_{k-2}$. Now $a_k<3 \cdot 2^{k-1} \implies a_{k-1}<3 \cdot 2^{k-2}$ and $2a_{k-2}<a_{k-1}<3a_{k-2}$. Thus, applying the previous argument again, we can find $n_2$ with $a_{k-1}=\frac{2n_2}{n_2-1}a_{k-2}$. Note that this procedure can be continued to obtain integers $n_3, \dots, n_{k-1}>3$ with similar relations; so $$3 \cdot 2^{j-1}>a_j=2^{j-1}\cdot \left(\frac{n_1 \cdot \dots \cdot n_{j-1}}{(n_1-1)\cdot \dots \cdot (n_{j-1}-1)}\right) \cdot a_1$$and $a_j$ is an integer for all $j \le k$. Thus, $a_1=2$ and $a_2=\frac{2n_{k-1}}{n_{k-1}-1}a_1$ is an integer so $a_2=5$ and so $5 \mid a_3$ but $a_3=\frac{2n_{k-2}}{n_{k-2}-1}a_2$ hence $a_3=11$ or $a_3=12$; contradiction!
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Rik786
36 posts
Rik786
#15 May 31, 2018, 8:27 AM • 3 Y
Y by cip999, Adventure10, Mango247
cip999 wrote:
I think this problem deserves more than it seems, so here's a proof not going through some dreadful induction and massive casework.

First, let $\frac{a_{n + 1}}{a_n} = \frac{x_n}{y_n}$, where $x_n$, $y_n$ are positive integers and $(x_n, \: y_n) = 1$. Then we get $$(a_{n + 1}, \: a_{n + 2}) = \frac{a_{n + 1}}{y_{n + 1}} > a_n \implies y_{n + 1} < \frac{a_{n + 1}}{a_n} = \frac{x_n}{y_n} \implies \frac{x_n}{y_n} \ge y_{n + 1} + \frac{1}{y_n}$$Now observe that $$a_n = a_0 \cdot \frac{a_1}{a_0} \cdots \frac{a_n}{a_{n - 1}} = a_0 \cdot \frac{x_0}{y_0} \cdots \frac{x_{n - 1}}{y_{n - 1}} \ge a_0\left(y_1 + \frac{1}{y_0}\right)\cdots\left(y_n + \frac{1}{y_{n - 1}}\right)$$By AM-GM $y_{i + 1} + \frac{1}{y_i} \ge 2\sqrt{\frac{y_{i + 1}}{y_i}}$; furthermore, since $a_1 = \frac{x_0}{y_0}a_0$, $y_0 \mid a_0 \implies a_0 \ge y_0$. Thus we have $$a_n \ge a_0\left(y_1 + \frac{1}{y_0}\right)\cdots\left(y_n + \frac{1}{y_{n - 1}}\right) \ge y_0\left(2\sqrt{\frac{y_1}{y_0}}\right)\cdots\left(2\sqrt{\frac{y_n}{y_{n - 1}}}\right) = 2^n\sqrt{y_0y_n} \ge 2^n$$which ends the proof.

Done a very good job and innovative
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mastermind.hk16
143 posts
mastermind.hk16
#17 Aug 4, 2019, 3:45 AM • 2 Y
Y by Adventure10, Mango247
First, note that $ a_i \geq (a_i, a_{i+1}) > a_{i-1}$.

Let us prove the result by strong induction on $n$.
Base case: $n=0,1,2,3$
Clearly, $a_0 \geq 1$ and $a_1 \geq 2$ because $a_1>a_0$.
$(a_2,a_1) \geq 2 \longrightarrow a_2 \geq a_1 +2 \geq 4$.
$(a_3,a_2) \geq 3 \longrightarrow a_3 \geq a_2 +3 \geq 7$. But if $a_3 =7$, then $(a_3,a_2)=1$. Contradiction. So $a_3 \geq 8$.

Assume for all $i \leq n, \ a_i \geq 2_i$.
Consider $a_{n+1}$. We have $a_{n+1} \geq (a_{n+2},a_{n+1})> a_n$.
Also, $d=(a_{n+1},a_{n}) > 2^{n-1}$ by the induction hypothesis.

Let $d = \frac{a_n}{m}$ and assume $m \geq 3$. Since $d \mid a_{n+1},$
Then $a_{n+1} \geq d(m+1) \geq \frac{a_n}{m} (m+1) > (m+1) \cdot 2^{n-1} \geq 4 \cdot 2^{n-1}=2^{n+1}$

So now $m=1$. Then $a_{n+1} > a_n =d \Longrightarrow a_{n+1} \geq 2a_n \geq 2^{n+1}$.

Lastly, $m=2$. Then $a_{n+1} \geq \frac{3}{2} a_n$. Write $a_i = 2^i + b_i \ \ \forall i \leq n, \ (b_i \geq 0)$
Since $d = \frac{a_n}{2} > a_{n-1} \longrightarrow b_n > 2b_{n-1}$.
If $b_n \geq 2^{n-1}$, then $a_{n+1} \geq 3(2^{n-1} +2^{n-2}) > 2^{n+1}$. The last inequality simplifies to $9>8$. So now assume $b_n < 2^{n-1} \dots (*)$

Consider $e=(a_n, a_{n-1})$ and $f=(a_{n-1}, a_{n-2})$.
If $e=a_{n-1}$, then $a_{n-1} \mid a_n \Longleftrightarrow a_{n-1} \mid b_n -2b_{n-1}$. But $0 < b_n -2b_{n-1} < 2^{n-1} \leq a_{n-1} \leq b_n -2b_{n-1}$. Contradiction.
So $ a_{n-2}<e \leq \frac{a_{n-1}}{2} \longrightarrow b_{n-1}-2b_{n-2}>0$.
Also $$2^{n-2}<e = (b_n -2b_{n-1}, a_{n-1}) \leq b_n -2b_{n-1}$$Hence $a_n =2^n +b_n > 2^n +2^{n-2} + 2b_{n-1}$.
If $b_{n-1} \geq 2^{n-3}$, we are done from $(*)$. So assume $b_{n-1} < 2^{n-3}$. Repeating the same argument as before we get that $f \leq \frac{a_{n-2}}{2}$. But $$2^{n-3}<f = (b_{n-1}-2b_{n-2}, a_{n-2}) \leq b_{n-1} -2b_{n-2} \leq b_{n-1}$$This is a contradiction. And our induction is complete.
This post has been edited 3 times. Last edited by mastermind.hk16, Aug 4, 2019, 4:29 AM
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ubermensch
820 posts
ubermensch
#18 Sep 13, 2019, 3:55 PM • 1 Y
Y by Adventure10
Yay, we're back yet again with another keep-bashing-mindlessly-until-you-get-something problem!

Looking at the problem, there's nothing which immediately strikes as obviously helping to solve the problem, and the condition really calls for an inductive argument, so here we have it-

First let's observe, quite obviously, that the sequence is a strictly increasing one, as $a_i \geq gcd(a_i,a_{i+1})>a_{i-1}$.

Now, assume for all $i \in [1,2,3,...,i-1]$, $a_i \geq 2^i$ (strong inductive argument).
For the sake of contradiction, also assume that $a_i<2^i =>$ write $a_i=2^{i-1}+k, k<2^{i-1}$.

As $gcd(a_i,a_{i-1})>a_2$, and by assumption, write $a_{i-1}=2^{i-1}+l, l<2^{i-1} =>gcd(2^{i-1}+k,2^{i-1}+l)>2^{i-2}$
$=>gcd(k,2^{i-1}+l-k)>2^{i-2}=>k \mid 2^{i-1}+l-k$ (using $k<2^{i-1}$) and $k>2^{i-2}$

Hence $k \mid 2^{i-1}+l$. Writing $k=2^{i-2}+m$, we get $2^{i-2}+m \mid 2^{i-1}+l => 2^{i-2}+m \mid l-2m$.
As $l<2^{i-1},m<2^{i-2}=>|l-2m| <2^{i-1}=> 2m-l =2^{i-2}+m (\neq$ possible as $=>m>2^{i-2}=>k>2^{i-1}$) or $l=3m+2^{i-2}$.

When $l=3m+2^{i-2}$, we get $a_i=2^{i-1}+2^{i-2}+m$ and $a_{i-1}=2^{i-1}+2^{i-2}+3m$ - I was actually feeling a little despondent after getting this, thinking that I had done all of the above for nothing, until I realised it's a direct violation of monotonicity! $=>$ our assumption $a_i<2^i$ was indeed false.

And thus, we've finally wrapped up all the possible cases, and all that's left to establish is the base case(s). Notice that $a_0$ is automatically $ \geq 1$, and if $a_1<2=>a_1=1$, then $gcd(a_1,a_2)=1>a_3$ couldn't possibly hold true. Finally, as $gcd(a_2,a_3)>2$, if $a_2<4=>a_2=3$, and this is only possible if $a_1=2$. But as this would imply $gcd(a_1,a_2)=1$, $gcd(a_1,a_2)>a_0$ couldn't possibly be true. As we only used $i,i-1,i-2$ in our argument, we're done!
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v_Enhance
6877 posts
v_Enhance
#19 Nov 14, 2019, 8:52 PM • 5 Y
Y by WindTheorist, v4913, Adventure10, Mango247, MS_asdfgzxcvb
Note $a_i \ge \gcd(a_i, a_{i+1}) > a_{i-1}$ so that the sequence is strictly increasing. Thus let $r_i = \frac{a_{i+1}}{a_i} > 1$ for each $i$.

Let's rephrase the condition in terms of the $r_i$. Let $d_i$ denote the denominator of $r_i$ in lowest terms.

Claim: We always have $r_i > d_{i+1}$.

Proof. Extend $\gcd \colon {\mathbb Q}_{>0} \times {\mathbb Q}_{>0} \to {\mathbb Q}_{>0}$ by $\gcd(a,b) = \prod_p p^{\min(\nu_p(a), \nu_p(b))}$. Then the condition is $ \gcd(r_i a_i, r_i r_{i+1} a_i) > a_i \iff \frac{1}{d_{i+1}} = \gcd(1, r_{i+1}) > \frac{1}{r_i}$ as needed. $\blacksquare$

Let's say an index is critical if $r_i < 2$ and hence $d_i \ge 2$.

Claim: If $i \ge 3$ is a critical index, there exists $e \le 3$ such that $r_{i-1}$, \dots, $r_{i-e}$ are not critical and $r_{i-e} \dots r_i > 2^{e+1}$.

Proof. Choose a critical index $i$. We consider several cases.
  • If $d_i \ge 3$ then $r_{i-1} > d_i$ and we have $r_{i-1} r_i > d_i \cdot \frac{d_i+1}{d_i} \ge 4 = 2^2. $
  • Suppose $d_i = 2$ and $d_{i-1} = 1$. Then $r_{i-1} r_i > 3 \cdot \frac 32 = \frac 92 > 2^2$.
  • Suppose $d_i = 2$ and $d_{i-1} = 2$. There are two sub-cases. If $d_{i-2} = 1$ then $ r_{i-2} r_{i-1} r_i > 3 \cdot \frac 52 \cdot \frac 32 > 2^3. $
    On the other hand if $d_{i-2} \ge 2$ then $ r_{i-3} r_{i-2} r_{i-1} r_i > d_{i-2} \cdot \frac{2d_{i-2}+1}{d_{i-2}} \cdot \frac 52 \cdot \frac 32 = \frac{15}{4}(2d_{i-2}+1) \ge \frac{75}{4} > 2^4. $
  • Suppose $d_i = 2$ but $d_{i-1} \ge 3$. Then $r_{i-2} > d_{i-1}$ and we have $ r_{i-2} r_{i-1} r_i > d_{i-1} \cdot \frac{2d_{i-1}+1}{d_{i-1}} \cdot \frac 32 = 7 \cdot \frac 32 > 2^3.$
This completes the proof. $\blacksquare$

Thus by induction it suffices to show $a_i \ge 2^i$ only for $i=0,1,2,3$, which is routine.
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yayups
1614 posts
yayups
#20 Jan 21, 2020, 7:16 AM • 1 Y
Y by Adventure10
Note that \[a_i\ge \gcd(a_i,a_{i+1})>a_{i-1},\]so the sequence is strictly increasing. We'll be implicitly using this fact over and over in the proof.

We prove the result by induction on $i$. We begin with the base case.

Claim: [Induction Base Case] We have $a_i\ge 2^i$ for $i\in\{0,1,2\}$.

Proof: We have $a_0\ge 1$, and $a_1>a_0\ge 1$, so $a_1\ge 2$. It suffices to show that $a_2\ge 4$. Note that $a_2\ge a_1+1$ and $a_1\ge 2$, so the only case in which $a_2\le 3$ is if $a_2=2$ and $a_3=3$. This doesn't work as $\gcd(a_2,a_3)=1\not>a_1$. $\blacksquare$

Before proving the inductive step, we have the following useful lemma.

Lemma: If $a_i\le 2a_{i-1}$, then $a_i\mid a_{i+1}$.

Proof: Note that $\gcd(a_i,a_{i+1})=a_i$ or $\gcd(a_i,a_{i+1})\le a_i/2\le a_{i-1}$. The latter case can't happen by the problem condition, so we have $\gcd(a_i,a_{i+1})=a_i$, or $a_i\mid a_{i+1}$. $\blacksquare$

Claim: [Inductive Step] Suppose $i\ge 2$. Then, if $a_j\ge 2^j$ for all $0\le j\le i$, then $a_{i+1}\ge 2^i$.

Proof: Let $a_{i-2}=b$, $a_{i-1}=d\alpha$, $a_i=d\beta$, and $a_{i+1}=a$, where $\gcd(\alpha,\beta)=1$. The problem condition gives us $d>b$ and $\gcd(a,d\beta)>d\alpha$. Furthermore, we know that $b\ge 2^{i-2}$, $d\alpha\ge 2^{i-1}$, and $d\beta\ge 2^i$. Our goal is to show that $a\ge 2^{i+1}$. We have the following cases.

Case 1: Suppose $\beta\ge 8$. Then, \[a>d\beta\ge 8d>8b\ge 8\cdot 2^{i-2}= 2^{i+1},\]as desired.

Case 2: Suppose $\beta\le 7$ and $\beta\le 2\alpha$. Then, we have $d\beta\le 2(d\alpha)$, so by the lemma, we have $d\beta\mid a$. We also know that $a>d\beta$, so we have \[a\ge 2d\beta\ge 2\cdot 2^i=2^{i+1},\]as desired.

Case 3: Suppose $\beta\le 7$ and $\beta\ge 4\alpha$. Then, we have \[a>d\beta\ge 4d\alpha\ge 4\cdot 2^{i-1}=2^{i+1},\]as desired.

Case 4: Suppose $\beta\le 7$ and $2\alpha<\beta<4\alpha$. Since $\gcd(\alpha,\beta)=1$, we have the following subcases.
  • Case 4.1: Suppose $\alpha=1$ and $\beta=3$. Then, $\gcd(a,3d)>d$, so we have $\gcd(a,3d)\in\{3d,3d/2\}$. Thus, $\tfrac{3d}{2}\mid a$ and $a>3d$, so \[a\ge\frac{9d}{2}>4d=4d\alpha\ge 4\cdot 2^{i-1}=2^{i+1},\]as desired.
  • Case 4.2: Suppose $\alpha=2$ and $\beta=5$. Then, $\gcd(a,5d)>2d$, so $\gcd(a,5d)\in\{5d,5d/2\}$. Thus, $\tfrac{5d}{2}\mid a$ and $a>5d$ so either \[a\ge 10d=2\cdot(d\beta)\ge 2\cdot 2^i=2^{i+1},\]or $a=\tfrac{15d}{2}$. So it suffices to look at the case where $a_{i-2}=b$, $a_{i-1}=2d$, $a_i=5d$, $a_{i+1}=\tfrac{15d}{2}$. In this case, we have $d$ even, so $a_{i+1}\ge 15$. So we're already done if $i=2$, so we may assume $i\ge 3$. Because of this, we may define $c=a_{i-3}$, noting that $c\ge 2^{i-3}$. Recall that in this case, our sequence contains \[c,b,2d,5d,\frac{15d}{2}\]as a subsequence. We have the following two subcases.
    • Case 4.2.1: Suppose $b>2c$. Then, $\gcd(2d,b)>c$ so $\gcd(b,2(d-b))>c$. Since $d>b$, this implies that $2(d-b)>c$, so $2d>2b+c>5c$. Thus, \[a=\frac{15d}{2}>\frac{15}{4}\cdot 5c\ge \frac{75}{4}\cdot 2^{i-3}>2^{i+1},\]as desired.
    • Case 4.2.3: Suppose $b\le 2c$. By the lemma, we have that $b\mid 2d$ and $d>b$, so $2d\ge 3b$. Thus, \[a=\frac{15d}{2}\ge\frac{15}{4}\cdot 3b\ge\frac{45}{4}\cdot 2^{i-2}\ge 2^{i+1},\]as desired.
  • Case 4.4: Suppose $\alpha=2$ and $\beta=7$. Then, $\gcd(a,7d)\ge 2d$, so $\gcd(a,7d)\in\{7d,7d/2,7d/3\}$. Thus $a$ is a multiple of $7d/2$ or $7d/3$, and since $a>7d$, we have that \[a\ge \frac{4}{3}\cdot 7d\ge \frac{28}{3}\cdot 2^{i-2}\ge 2^{i+1},\]as desired.
  • Case 4.4: Suppose $\alpha=3$ and $\beta=7$. Then, $\gcd(a,7d)\ge 2d$, so $\gcd(a,7d)\in\{7d,7d/2\}$. The proof then proceeds exactly as in the previous case.
Thus, we've shown that $a\ge 2^{i+1}$ in all cases, proving the claim. $\blacksquare$

Combining the base case and the inductive step completes the proof.
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aops29
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aops29
#21 Jan 31, 2020, 2:40 PM • 2 Y
Y by AlastorMoody, Adventure10
Solution to 2008 N3
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awesomeming327.
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awesomeming327.
#22 Apr 11, 2023, 1:31 AM
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We proceed with induction. It is easy to verify that $a_0\ge 1$ and $a_1\ge 2$. Suppose $a_n\ge 2^n$ and $a_{n+1}\ge 2^{n+1}$, then
\begin{align*} \text{gcd}(a_{n+2}, a_{n+1}) &> a_n \\ \text{gcd}(a_{n+3}, a_{n+2}) &> a_{n+1} \end{align*}Let $a_{n+2}=k\text{gcd}(a_{n+2}, a_{n+1}) = l\text{gcd}(a_{n+3}, a_{n+2})$. If $k=1$ then $a_{n+2}\mid a_{n+1}$, impossible by the second one. If $k=2$ then $a_{n+2}=2a_{n+1}\ge 2^{n+2}$ as desired. If $k=3$ then either $a_{n+2}=3a_{n+1}$ which implies the result or
\[a_{n+2}=\frac32 a_{n+1}\]but that'll imply $a_{n+3}=a_{n+2}$ which similarly to $a_{n+2}\mid a_{n+1}$ will not work. If $k=4$ then $a_{n+2}>4a_n\ge 2^{n+2}$ as desired.
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megarnie
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#23 Feb 3, 2024, 7:16 PM
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Suppose this was false.

Clearly this is true for $0$ (since $a_0 \ge 1 = 2^0$). Now let $n$ be the smallest nonnegative integer for which $a_{n+1} < 2^{n+1}$. This implies $a_i \ge 2^i$ for all $0\le i\le n$.

First notice that the sequence must be strictly increasing.

Let $d = \gcd(a_n, a_{n+1})$. We have $d > a_{n-1} \ge 2^{n-1}$, therefore $\frac{a_{n+1}}{d} < 4$.

Now, this implies that both $\frac{a_n}{d}$ and $\frac{a_{n+1}}{d}$ are positive integers under $4$. If $a_n = d$, then $a_n \mid a_{n+1}$, but since $a_{n+1} > a_n$, we have $a_{n+1} \ge 2a_n \ge 2^{n+1}$, contradiction. Thus, $a_n = 2d$ and $a_{n+1} = 3d$ must hold and $d > a_{n-1}$. If $n = 1$, then $a_2 = 3d < 4$, so $d = 1$, absurd since $d > a_0$. Thus, $n > 1$.

Therefore, we have $3d < 2^{n+1} \implies d < \frac{2^{n+1}}{3}$. Looking at $\gcd(a_{n-1}, a_n)$, we see $\gcd(a_{n-1}, 2d) > a_{n-2} \ge 2^{n-2}$.

We have \[ \frac{a_{n-1}}{\gcd(a_{n-1}, 2d)} < \frac{a_{n-1}}{2^{n-2}} \le \frac{d}{2^{n-2}} \le \frac 83, \]so the fraction must be either $1$ or $2$. If it is $1$, then $a_{n-1} \mid 2d$. Now note that $2d < \frac{2^{n+2}}{3} \le a_{n-1} \cdot \frac{8}{3}$, meaning that either $a_{n-1} = 2d$ or $2a_{n-1} = 2d$, both contradict $a_{n-1} < d$. Hence we must have $\frac{a_{n-1}}{\gcd(a_{n-1}, 2d) } = 2$, so $\gcd(a_{n-1}, 2d) = \frac{a_{n-1}}{2}$.

Now, let $2d = k \cdot \frac{a_{n-1}}{2}$. Since $a_{n-1} < d$, $k > 4$. We have $k \cdot 2^{n-2} \le k \cdot \frac{a_{n-1}}{2} < \frac{2^{n+2}}{3}$, so $k < \frac{16}{3}$. Thus, $k = 5$ must hold. Therefore $d$ is a multiple of $5$, so let $d = 5x$.

We see that $a_{n-1} = 4x, a_n = 10x, a_{n+1} = 15x$. If $n = 2$ held, then $a_3 = 15x < 8$, which is impossible. Now we look at $\gcd(a_{n-2}, 4x)$. Call it $m$. It must be greater than $a_{n-3} \ge 2^{n-3}$.

We have $\frac{2^{n-1}}{5} < x < \frac{2^{n+1}}{15}$. Notice that $\gcd(a_{n-1}, a_n) > a_{n -2}$, so $\gcd(4x, 10x) > a_{n-2}$ implying that $a_{n-2} < 2x$. We see that $ \frac{a_{n-2}}{m} < \frac{2x}{m} < \frac{2^{n+2}}{15 \cdot 2^{n-3}} < 3$, so $\frac{a_{n-2}}{m}$ must be either $1$ or $2$. Since $a_{n-2} > a_{n-3}$, we cannot have $a_{n-2} = m$, so we must have $a_{n-2} = 2m$. Thus, we must have $m < x$.

Now, we have $\frac{4x}{m} > 4$, but \[ \frac{4x}{m} < \frac{4x}{2^{n-3}} < \frac{64}{15} < 5 ,\]so $\frac{4x}{m}$ is not an integer.

Hence we have a contradiction, so $a_n \ge 2^n$ for all nonnegative integers $n$.
This post has been edited 1 time. Last edited by megarnie, Feb 3, 2024, 7:17 PM
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vsamc
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#24 May 23, 2024, 7:25 PM
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Solution
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i3435
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#25 Jul 8, 2024, 1:15 PM
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Note that $a_n> a_{n-1}$ since $\text{gcd} (a_n,a_{n+1})\le a_n$.

I show that for $n\ge 3$, if $a_n<2a_{n-1},4a_{n-2},8a_{n-3}$ then $15\mid a_n$ and if $n\ge 4$ then $16a_{n-4}<a_n$. This will solve the problem because
  • for $n=0$ $a_n\ge 1$,
  • for $n=1$ $a_1>a_0$ so $a_1\ge 2$,
  • for $n=2$ $a_2>a_1>a_0$ so either $a_2\ge 4$ or $a_2=3,a_2=2,a_2=1$ which is impossible
  • for $n=3$ $a_3\ge 8$ or $15\mid a_3$
  • for $n\ge 4$ strong induction works.

    Suppose for $n\ge 3$ that $a_n<2a_{n-1},4a_{n-2},8a_{n-3}$. In what follows, we use the property that $\text{gcd}(a_i,a_{i+1})$ is less than the absolute value of any nonzero linear combination of $a_i$ and $a_{i+1}$. $a_n-a_{n-1}>a_{n-2}$, so $a_{n-1}\le \frac{3}{4} a_n$ since $a_{n-2}>\frac{1}{4}a_n$. $2a_{n-1}-a_n>a_{n-2}>\frac{a_n}{4}$ so $a_{n-1}>\frac{5}{8}a_n$. $\left|3a_{n-1}-2{a_n}\right|$ is either $0$ or greater than $\frac{a_n}{4}$, which is impossible unless $a_{n-1}=\frac{2}{3}a_n$.

    $a_{n-2}<a_n-a_{n-1}$ so $a_{n-2}<\frac{a_n}{3}$. $\frac{a_n}{8}<a_{n-3}<a_{n-1}-2a_{n-2}$ so $a_{n-2}<\frac{13}{48}a_n$. $\left|2a_{n-1}-5a_{n-2}\right|$ is either $0$ or greater than $\frac{a_n}{8}$, so it equals $0$ and $a_{n-2}=\frac{4}{15}a_n$. Thus $15\mid a_n$.

    If $n\ge 4$, then $a_{n-3}<a_{n-1}-2a_{n-2}$ so $a_{n-3}<\frac{2}{15}a_n$. $a_{n-4}<a_{n-2}-2a_{n-3}<\frac{a_n}{60}$, as desired.
This post has been edited 1 time. Last edited by i3435, Jul 8, 2024, 1:16 PM
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lnzhonglp
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#26 Jul 24, 2024, 9:46 PM
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We use strong induction on $n$. The base cases up to $n=2$ are easy to verify. It is easy to check that the sequence must be strictly increasing. Now suppose $a_n \geq 2^n$ for up to $n$, and let $\gcd(a_n, a_{n+1}) = m$ and $a_{n+1} = km > ka_{n-1}$. If $k \geq 4$, then $a_{n+1} \geq 4a_{n-1} \geq 2^{n+1}$ and we are done.

If $k=3$, then we get $\gcd(a_n, 3m) = m > a_{n-1}$ and $a_n$ must be either $m$ or $2m$. Let $a_{n-1} = m-b$. If $a_n = m$, then $a_{n+1} = 3m \geq 3 \cdot 2^{n} > 2^{n+1}$. If $a_n = 2m$, then $$\frac 12 \gcd(2m, 2m-2b) = \gcd(m, m-b) = \gcd(m, b) \leq \gcd(2m, m-b) = \gcd(a_n, a_{n-1}) \leq a_{n-2} = 2^{n-2},$$so $b \geq 2^{n-2}$ and $m \geq 2^{n-2} + 2^{n-1}$, so $a_{n+1} = 3m \geq 2^{n+1} + 2^{n-2} > 2^{n+1}$, as desired.

If $k = 2$, then $a_{n+1} \geq 2a_n \geq 2^{n+1}$ and we are done. We have checked all cases so the induction is complete.
This post has been edited 2 times. Last edited by lnzhonglp, Jul 24, 2024, 9:48 PM
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Assassino9931
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#27 Feb 2, 2025, 5:23 PM
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awesomeming327. wrote:
which implies the result or
\[a_{n+2}=\frac32 a_{n+1}\]but that'll imply $a_{n+3}=a_{n+2}$ which similarly to $a_{n+2}\mid a_{n+1}$ will not work. If $k=4$ then $a_{n+2}>4a_n\ge 2^{n+2}$ as desired.
How does $a_{n+3} = a_{n+2}$ follow? I think this very direct induction approach (similarly to some other posts) does not work.
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L13832
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#29 Apr 6, 2025, 4:37 PM
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got deleted by mistake ig

solution
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sansgankrsngupta
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#30 Apr 29, 2025, 7:33 AM
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OG! $a_i \geq gcd(a_{i+1}, a_i) > a_{i-1} \implies$ the sequence is strictly increasing, denote $g_i = gcd(a_{i+1}, a_i)$. Now we proceed by strong induction on $n$
Base Cases: $n=0,1,2,3$
Will write ;ater
Inductive step: Assume the problem statement is true for all $n \in \{0,1,2 \cdots k\}$
Now for $n =k+1$, assume FTSOC that $a_{k+1}< 2^{k+1}$;
$2^{k-2} < g_{k}|a_{k+1}$ also, $a_{k+1}>a_k \geq g_{k}$. Hence $a_{k+1}= 2g_k$ or $3g_k$.

$\blacksquare$ If $a_{k+1} = 2g_k$, then since $g_k| a_k $ and $a_k <a_{k+1}= 2g_k$, we have that $a_k=g_k$. But then, $$a_{k+1}=2g_k= 2a_{k} \geq 2(2^{k}) =2^{k+1}$$produces a contradiction!
$\blacksquare$ If, $a_{k+1}= 3g_{k}$, then since $g_k| a_k $ and $a_k <a_{k+1}= 3g_k$, , we have that $a_k=g_k$ or $2g_k$.
$\hspace{1cm}$ $\bullet$ If $a_k=g_k$, then $$a_{k+1}=3g_k= 3a_{k} \geq 3(2^{k}) >2^{k+1}$$
$\hspace{1cm}$ $\bullet$ If $a_k=2g_k$, then $a_k= 3g_k< 2^{k+1} \implies $$$ 2^{k-1}\leq a_{k-1}< g_k< \frac23 2^k < \frac43 2^{k-1} \leq \frac43 a_{k-1} \implies a_{k-1}> \frac34 g_k $$.
$\hspace{1cm}$ We have that $g_{k-1} \mid a_{k-1}$. $\hspace{1.5cm}$ If $g_{k-1} \leq \frac{a_{k-1}}{3} \implies a_{k-2}<g_{k-1} \leq \frac{a_{k-1}}{3} < \frac29 2^k \leq 2^{k-2}$ which is a contradiction.

$\hspace{1cm}$ Hence, $\hspace{1cm} $ $g_{k-1}= a_{k-1}$ or $\frac{a_{k-1}}2$. If $a_{k-1}= g_{k-1}$, then $a_{k-1}| a_k = 2g_k$ since, $$\frac{2g_k}{3}< \frac{3}{4} g_k <a_{k-1} < \frac{2g_k}{2}$$$\hspace{1cm}$,this is a contradiction! Hence, $g_{k-1}= \frac{a_{k-1}}{2} \mid a_k = 2g_k \implies a_{k-1}|4g_k$. Since $ \frac46 g_k< \frac34g_k< a_{k-1}<\frac44 g_k$. Hence, $a_{k-1} = \frac45 g_k$. Will write the remaining later
This post has been edited 1 time. Last edited by sansgankrsngupta, Apr 29, 2025, 8:15 AM
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