Tag: statistics

For a particular class, the total number of different tickets from first intermediate station is $5.$ 
Similarly, number of different tickets from second intermediate station is $4.$ 
So the total number of different tickets is $5+4+3+2+1=15$.
And same number of tickets for another class is equal to total number of different tickets, 

Matches played between 8 teams =$ 7+6+5+4+3+2+1 = 21$

Total number of wrong answers $= 2^{n-1}+2^{n-2}+...+2^{2}+2+1$
$=2^{n-1}+2^{n-2}+...+2^{4}+2^{3}+2^{2}+2+1$
$\Rightarrow 2^{n}-1=2043$  [Using formula for sum of G.P]
$ \Rightarrow 2^{n}=2048$
$ \Rightarrow 2^{n}=2^{11}$
$\Rightarrow n = 11$
Hence, option 'B' is correct.

In order to solve this question, we must observe the number of ways in which we can select the first term of the required A.P. for different values of the common difference($r$) starting from $r=1$ given that there are only $3$ terms before $n$.
For $r=1$, the number of ways in which we can select the first term of the A.P. $=n-2$
For $r=2$, the number of ways to select the first term $=n-4$
For $r=3$, the number of ways to select the first term $=n-6$
Now we see a pattern emerging, we also realize from this that $r<=\dfrac{n-1}{2}$ for an A.P. with 3 terms to exist in the given interval.
$\therefore$ The final answer $=n-2+n-4+n-6+...+5+3+1$
Now we use the formula to find the sum of an A.P. which is $S _n=\dfrac{n}{2}[a _1+a _n]$ 
$\therefore$ Answer $=\dfrac{n-1}{4}[1+n-2]=\dfrac{(n-1)^2}{4}$

$7$ Courses in morning 

We know that $ { { n } _{ C } } _{ r }=  { { n } _{ C } } _{n- r }$

Given, $ { { n } _{ C } } _{3}= { { n } _{ C } } _{13} $
$ => r = 3 $ and $ n -r = 13 $
$ => n - 3 = 13 $
$ => n = 16 $

Also, $ { { n } _{ C } } _{ r }=\dfrac { n! }{ r!(n-r)! }  $
So, $ { { 20 } _{ C } } _{ 16 }=\dfrac { 20! }{ 16!(20-16)! } = \dfrac { 20! }{ 16! \times 4! }  = \dfrac { 20 \times 19 \times 18 \times 17 \times 16! }{ 16! \times 4 \times 3 \times 2 } = 4845   $

If two zeros are the entries in the diagonal, then
$^{3}\mathrm{C} _{2}\times^{3}\mathrm{C} _{1}$
If all the entries in the principle diagonal is 1, then
$^{3}\mathrm{C} _{1}$
$\Rightarrow$  Total matrix $= 12.$