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### Re: Secondary and Higher Secondary Marathon

Posted: Tue Feb 05, 2013 11:16 pm
FahimFerdous wrote:Problem 38:

$3^x+7^y=n^2$
how many integer solutions for $(x,y)$ are there?
I have a confusion here. Can $x,y$ be negative?

### Re: Secondary and Higher Secondary Marathon

Posted: Tue Feb 05, 2013 11:54 pm
Firstly if $x,y$ are both non-negative,then we can do the following:
$n^2\equiv 0(mod 4)$ here.And also $3\equiv -1(mod 4)$ and $7\equiv -1(mod 4)$. So one of $x,y$ is odd and the other is even. Let $x=2a,y=2b+1$. Then $7^{2b+1}=n^2-3^{2a}=(n+3^{a})(n-3^{a})$. Now we can assume that $n+3^{a}=7^{p},n-3^{a}=7^{q},p+q=2b+1$. Subtraction implies that $2\times 3^{a}=7^{p}-7^{q}$. If $q>0$ then $7|2\times 3^{a}$ which is not possible. So $q=0,p=2b+1$. Thus we get $2\times 3^{a}+1=7^{2b+1}=(2\times 3+1)^{2b+1}$. Expanding the RHS shows that $a=1$ and consequently $b=0$. Thus $(2,1)$ is the only solution. Similarly we can assume that $x=2a+1,y=2b$ and a similar argument implies that $(1,0)$ is another solution.

However,It is not clear to me whether $x,y$ can be negative or not. So I can't post anything for negative $x,y$. Can anyone help me please?

### Re: Secondary and Higher Secondary Marathon

Posted: Wed Feb 06, 2013 7:09 am
Tahmid Hasan wrote:
Tahmid Hasan wrote:Probelm $37$: $\mathbb{N}$ is the set of positive integers and $a\in\mathbb{N}$. We know that for every $n\in\mathbb{N}$, $4(a^n+1)$ is a perfect cube. Prove that $a=1$.
Source: Iran NMO-2012-4.
Note: In BdMO Summer Camp-2012, a similar problem was given in the Number Theory problem set.
Zubaer vai gave a 'cruxy' solution, but unfortunately I don't remember it. So I solved it with brute force.
Does anybody remember?
There's a typo, it's from Iran NMO-2008
Phelembac Adib Hasan wrote:@Tahmid vai, please post your proof and if you can still remember Zubayer vai's nice proof, please post it, too.
Sorry, I don't but I remember Mahi and Nadim vai solved it using ring.
My solution: Note that if $a=1,4(a^n+1)=8=2^3$.
Now assume $a>1$.
$4(a^9+1),4(a^3+1)$ are both perfect cubes, so their quotient $a^6-a^3+1$ is a perfect cube too.
$\forall a>1,a^3-1>0 \Rightarrow a^6-a^3+1<(a^2)^3$
So $a^6-a^3+1 \le (a^2-1)^3 \Rightarrow a^2(3a^2-a-3)+2 \le 0$.
But $\forall a>1, 3a^2>a+3$, so we have a contradiction.
I didn't understand how did you get that the $2$ perfect cube numbers.

### Re: Secondary and Higher Secondary Marathon

Posted: Wed Feb 06, 2013 9:45 am
sakib.creza wrote: I didn't understand how did you get that the $2$ perfect cube numbers.
See the statement at first:
Tahmid Hasan wrote:Probelm $37$: $\mathbb{N}$ is the set of positive integers and $a\in\mathbb{N}$. We know that for every $n\in\mathbb{N}$, $4(a^n+1)$ is a perfect cube. Prove that $a=1$.
Source: Iran NMO-2012-4.
Substitute $n=3,9$.

### Re: Secondary and Higher Secondary Marathon

Posted: Wed Feb 06, 2013 10:00 am
SANZEED wrote:However,It is not clear to me whether $x,y$ can be negative or not. So I can't post anything for negative $x,y$. Can anyone help me please?
$n$-এর সংজ্ঞা কি একই রাখা হবে না পাল্টানো হবে? মানে পূর্ণসংখ্যার বদলে মূলদ বলা হইলে কষ্ট বেশি হবে।
Consider these cases:
$1.\; x=0, z=-y>0\, \, \Longleftrightarrow 7^{z}+1=n^27^z$
আরও তিন চারটা কেস আসবে। সমাধানের বিস্তৃতি হবে ইনশাল্লাহ আমার জুনিয়র বলকানের সমান। আমার এখন করার কোন ইচ্ছা নাই। আর কেউ চাইলে করতে পারেন।

### Re: Secondary and Higher Secondary Marathon

Posted: Mon Dec 21, 2015 4:27 pm
Prove that 1+1/1+1/2+1/3+1/4+1/5+..........1/n not equal any integer i have proved that but not sure about the way of proving

### Re: Secondary and Higher Secondary Marathon

Posted: Fri Feb 23, 2018 9:01 am
samiul karim wrote:
Mon Dec 21, 2015 4:27 pm
Prove that 1+1/1+1/2+1/3+1/4+1/5+..........1/n not equal any integer i have proved that but not sure about the way of proving
Rewriting the problem:

$H_n=\dfrac 11 +\dfrac 12+\dfrac 13 +...+\dfrac 1n$

Prove that,if $n>1$,then $H_n$ is not equal to any integer.

Problem source
Solution

### Re: Secondary and Higher Secondary Marathon

Posted: Fri Dec 11, 2020 10:05 am
Find all the function such that
$f:R\Rightarrow R$ and
$f(f(x)+xf(y))=3f(x)+4xy$