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
We are deleting one digit and adding to the number. So value mod 9 shall not change . Given number mod 9 is not zero . So when we get a 10 digit number it shall not be divisible by 9. If all 10 digits are different then the number is divisible by 9. So all ten digits cannot be different. So upto 9 digits shall be different so at least one digit must repeat or two same digits will be there.
