Any number from $k^2$ to $k(k +2)$ shall have square root between $k$ and $k+1$ as $k(k+2) +1$ shall have square root $k + 1$
So the floor function of any number $k^2$ to $k(k+2)$ shall be $k$. For $k$ to divide the number with in the range it has to be of the form $k^2$ or$ k(k+1)$ or $k(k+2)$
So for any $k $ $k^2 , k(k+1),k(k+2)$ satisfy the criteria
We know working in modulo 20 as 3 is co-prime to 20
$3^0 \equiv 1 \pmod {20}$
$3^1 \equiv 3 \pmod {20}$
$3^2 \equiv 9 \pmod {20}$
$3^3 \equiv 7 \pmod {20}$
$3^4 \equiv 1 \pmod {20}$
It repeats from this point,
As $3^n \pmod {20}$ is single digit so tens digit is even.
Let $GCD(m,n) = k$ then we have
$m = ka$
$n = kb$
For some integers a and b where GCD(a,b) = 1
LCM = kab and GCD = k
So $ab = 120$
And $m +n = k(a+b)$
$m +n = 667 = 29 * 23$
So k can be $1,23,29, 667$
If $k =$1$ $a +b = 667$ and $ab = 120$ this is not possible
If $k = 667$ $a + b = 1$ so this is not possible
If $k = 23$ $a +b = 29, ab = 120$ so $a = 24,b =5$ or vice versa giving $(552,115)$ or $(115,552)$
if $k = 29$ $a +b = 23, ab = 120$ so $a = 15, b =8$ or vice versa giving$ (345,232)$ or $(232,345)$
So solution set is $\{(552,115), (115,552), (345,232), (232,325)\}$
To complete square add 2 on both sides to get
$x^2+4x +4 \equiv 2 \pmod 7$
or $(x+2)^2 \equiv 2 \pmod 7\cdots(1)$
now working mod 7
$(0^2 \equiv 0 \pmod 7\cdots(2)$
$(1^2 \equiv 1 \pmod 7\cdots(3)$
$(2^2 \equiv 4 \pmod 7\cdots(4)$
$(3^2 \equiv 2 \pmod 7\cdots(5)$
from (1) and (5) we have
$(x+2) \equiv 3 \pmod 7\cdots(6)$ or $(x+2) \equiv 3 \pmod 7\cdots(7)$
or $x\equiv 1 \pmod 7$ or $x\equiv 2 \pmod 7$
As a = 0 gives b= 0 so a = 7k and b= 7m satisfy the given equation but they ate not co-prime
Because of symmetry let is assume $a=mb \pmod 7$
Putting in the given equation we get $m^2+m+1 \equiv 0\pmod 7$
As $m=1$ is not a solution to it multiplying by (m-1) on both sides we get
$m^3 \equiv 1 \pmod 7$
So $ m \equiv 1 \pmod 7$ or $ m \equiv 2 \pmod 7$ or $ m \equiv 4 \pmod 7$ but as $ m \equiv 1 \pmod 7$ is not a root of original eqution so solution is $ m \equiv 2 \pmod 7$ or $ m \equiv 4 \pmod 7$
So we can chose $(7p+m, 7q+2m)$ or $(7p+m, 7q+2m)$ p and q to be chosen such that the pairs form a co-prime
One set the infinite co-primes $(7p+1,7p+2)$ for any p
We have $abc=1\cdots(1)$
So $\frac{1}{a} = \frac{abc}{a} = bc$
Similarly
$\frac{1}{b} = ca$
And
$\frac{1}{c} = ab$
Hence
$\frac{1}{a}+\frac{1}{b}+\frac{1}{c} = bc+ca+ab\cdots(2)$
From above and
$a+b+c= \frac{1}{a}+\frac{1}{b}+\frac{1}{c}$
We have
Hence $a+b+c = ab+bc+ca\cdots(3)$
a,b c are roots of equation
$P(x) = x^3-(a+b+c)x^2 + (ab+bc+ca)x - abc=0\cdots(4)$
Let $a + b+c = m\cdots(5)$
So we get from (4), (3), (5)
$P(x) = x^3-mx^2+mx -1=0$
1 is a root of above equation as P(1) is zero
As a , b,c are roots one of $a,b,c$ is 1
Proved
Let the odd number be k. now let us take the number sequence $2^2–1, 2^3–1, 2^4–1$ so on k values that is upto $2^k-1$
Let us calculate all k remainder values when the above expressions are divided by k (as the remainder can be from zero to k-1) then we have on difference is zero and we are done.
If all k values are not different then we have say for 2 values of m and n the remainder must be same. without loss of generality let us assume $m > n$
So $(2^m-1) - (2^n-1) = 2^(m-n) -1 * 2^n$ is divisible by k. As k is odd $gcd(2^n,k) = 1$ so k must divide $2^(m-n) -1$
Note: The above is for the persons who are not familiar with number theory or want to know from $1^{st}$ principle.
n divides $2^{\phi(n)} -1$ as n is co-prime to 2 as per Eulers theorem in number theory.
