rx10 wrote:
This is a very nice question.
\(x = 10^{10} - z\) & \(z\) - two digit integer
Now \(10^3 - \) any two digit no = \(9ab\)
\(10^4 - \)any two digit no = \(99ab\)
Similarly
\(10^{10} - \) any two digit no = \(99999999ab\)
It's given that the sum of digits of \(x\) = \(84\)
We already have \(8\)times \(9\) = \(72\)
So sum of \(ab = 12\)
So we need \(ab\) in which the sum of the digits = \(12\)
\(39 , 48 , 57 , 66 , 75 , 84 , 93\)
Now if we put ab = 93 , \(z\) will be \(7\) , but z is a two digit integer
So total 6 nos.
Answer D
Can you explain this part again: Now 103−
10
3
−
any two digit no = 9ab
9
a
b
104−
10
4
−
any two digit no = 99ab
99
a
b
Similarly
1010−
10
10
−
any two digit no = 99999999ab