All 4 digits are same
Let it be 1111x . Add 1 in both sides to get
$12n^2 + 12n + 12 = 1111x + 1$
Work mod 12 to get
$7x \equiv = 0 \pmod {12}$
So x is odd and
Trying x 1 3 5 9 11 we get x is 5 .
So $12n^2 + 12n + 12 = 5556$
Or $n^2 + n + 1 = 463$
Or $n = 21$
We have 501 = 495 (multiple of 15) + 6
6 = 3 * 2
So 501 = 2 * 3 + 99 * 5
As 3 * 5 = 5 * 3
We have 501 = 3 (2 + 5t) + 5 ( 99 - 3t)
If t is zero or positive coefficient of 3 is positive and t -ve coefficient of 3 is -ve . We need to ensure 99 - 3t positive so t is less than 33 so 33 values 0 to 32
Hence answer (A) 33
We have sum of 1st n cubes ($\frac{(n(n+1)}{2})^2$
Hence $\sum_{k=1}^{k=n} k^3$ = $(\frac{(n(n+1)}{2})^2$
Also sun of 1st n+p cubes is
$\sum_{k=1}^{k=n+p} k^3 $ = $(\frac{((n+p)(n+p+1)}{2})^2$
Hence sum of p cubes from $(n+1)^3$ to $(n+p)^3$ is
$\sum_{k=n+1}^{k=n+p} k^3 $ = $(\frac{((n+p)(n+p+1)}{2})^2$ - $(\frac{(n(n+1)}{2})^2$
p = 3 is a special case of the problem
We are having numbers in the form $\frac{n!(n+1)!}{2}$ .
This is $\frac{(n!)^2 * (n+1)}{2}$
It is a perfect square if $\frac{(n+1)}{2}$ is a perfect square $\frac{18}{2}$ is a perfect square so (D) is the answer
Because this is 3 consecutive odd numbers one of them is divisible by 3. None may be divisible by 5 as in case of 17,19,21. If the form are 5n + 2, 5n+ 4, 5n+ 4 where n is odd. None is divisible by 2 as numbers are odd . So answer is 3 that is (D)
Let n be divisible by 17 . So n is of the form 17k . 17k +1 is divisible by 13 so 4k +1 is divisible by 13 . So k is 3 is a solution or any multiple of 13 plus 3. Say $k=13 t +3$ or $n =221t +51$
We have putting $ab +bc +ca$ for 1 in $1+a^2$
$1+a^2 = ab + bc +ca + a^2 = (a+b)(a+c)$
Similarly $1+b^2 = (b+c)(b+a)$
And $1+ c^2 = (c+b)(c+a)$
So $(1+a^2)(1+b^2)(1+c^2) = ((a+b)(b+c)(c+a))^2$ a perfect square
