We have
$x = 1555555\cdots 526$ number of 5's >=0$
so $x + 29 = 1555555\cdots 5$
Let it be a n digit number
so $x + 29 = 10^{n-1} + 5 *111\cdots 1$ n-1 1's
or $x + 29 = 10^{n-1} + \frac{5}{9}(10^{n-1} -1 )$
as 7 is not a factor of 9
So we have $9(x+29) = 9 * 10^{n-1} + 5 * 10^{n-1} -5$
or $9x + 9 * 29 -5 = 14 * 10^{n-1}$
so $9x + 266$ is divisible by 7
as $266$ is divisible by $7$ so $9x$ is divisible by $7$ and $7$ is coprime to $9$ so $x$ is divisible by $7$
We know $\tan\,2A = \frac{2\tan\, A}{1+\tan ^2 A}\cdots(1)$
So if $\tan\, A $ is rational then $\tan 2A$ is rational
Further $\tan(A+B) = \frac{\tan \, A + \tan\, B}{1-\tan\,A \tan \,B}\cdots(2)$
So if $\tan\, A$ and $\tan \, B$ are rational then $\tan(A+B)$ is rational
So if $\tan\, A$ and $\tan \,nA$ are rational then $\tan(n+1)A$ is rational
using Above 2 we get if $\tan\, A $ is rational then $\tan nA$ is rational for all $n \in Z$
if $\tan \, 1^{\circ}$ is rational then $\tan \, 30^{\circ}$ or $\frac{1}{\sqrt{3}}$ is rational which is not
Hence $\tan \, 1^{\circ}$ is irrational
Proved
We have from the properties of AM
$\frac{1}{b + c} - \frac{1}{a + b} = \frac{1}{c + a} - \frac{1}{b + c}$
Or $\frac{a-c}{(b+c)(a+b)} = \frac{b-a}{((a+c)(b+c)}$
Or $\frac{a-c}{a+b }= \frac{b-a}{a+c}$
Or $(a-c)(a+c) = (a+b)(b-a)$
Or $a^2-c^2 = b^2-a^2$
Or $b^2+c^2= 2a^2$ hence $b^2, a^2$ and $c^2$ are in A.P.
Because $GCD(63,23) =1 $ so this has a solution.
Now let us find a particular solution a and b such that $63a + 23b= 1$
For this we shall use extended Euclidean algorithm.
We have
$63= 2 * 23 + 17\cdots(1)$
$23= 17 + 6\cdots(2)$
$17= 2 * 6 + 5\cdots(3)$
$6= 5 + 1\cdots(4)$
as we have got 1 as the last remainder we are done,.
Now let us work back wards to see
$1= 6- 5$
$=6- (17 - 2 *6)$ from (3)
$= 3 * 6 - 17$
$= 3 * (23-17) - 17$ from (2)
$= 3 * 23- 4 * 17$
$= 3 * 23 - 4 * (63-2 * 23)$ from (1)
$=11 * 23 - 4 * 63$
So we have $ 1= 11 * 23 - 4 * 63$
Hence $ -7 = - 77 * 23 + 28 * 63$
The above solution is correct however we can reduce the absolute value of coefficients of 23 and 63 by adding 63 to 1st one and subtracting 23 from 2nd one to get
$-7 = 5 * 63- 14 * 23$
so $(x,y) = (5,14)$ is a solution and general solution is $5 + 23t,14+63t)$ as $23 * 63 - 63 * 23 = 0$
We have $35 = 7 * 5$ so
$GCD(a,5) = 1$ and $GCD(a,7) = 1$
Because GCD(a,5) is 1 so as per Fermats Little Thorem $a^{4} \equiv 1 \pmod {5}$ or
$a^{12} \equiv 1 \pmod {5}\cdots(1) $
Because GCD(a,7) is 1 so as per Fermats Little Thorem $a^{6} \equiv 1 \pmod {7}$ or
$a^{12} \equiv 1 \pmod {7}\cdots(2)$
From (1) and 2
$a^{12} \equiv 1 \pmod {35}$
We have GCD = $6 = 2 * 3$
$1^{st} number = $12 = 2^2 *3$
$2^{nd}$ number = $18= 2 * 3^2$
LCM = $72 = 2^3 * 3^2$
So the $3^{rd}$ number has to of the form $2^a3^b$
Taking the lowest powers of 2 and 3 we get the HCF
So HCF = $2^{min(1,a)}3^{min(1,b)}= 2 * 3$ which gives $a >=1$ and $b >=1$
Taking the highest powers of 2 and 3 we get the LCM
LCM= $2^{max(2,a)}3^{max(2,b)}= 2^3 * 3^2$ so $a=3$ and $ b <=2$
Giving $a=3,b=1$ that is number = $2^3*3=24$ or $a=3,b=3$ that is number = $2^3*3^2=72$
so $3^{rd}$ number can be 24 or 72
It is 114 mod n so 2001–114 should be divisible by n and $n > 114$
Factors of 1887 are 1 3 17 37 51 111 629 1887. any number $<= 111$ shall give a smaller remainder and 2 numbers 629 and 1187 shall give a remainder 114 so the number is lower of the 2 that is 629.
