Answer:
[tex]\frac{n!}{r!(n-r)!}[/tex]
Step-by-step explanation:
Combinatorial explanation:
The n balls have to be arranged in n positions and the only distinction is where are the black and where white balls are.
We can choose the position of black balls in [tex]\binom{n}{r}[/tex] ways, therefore, white ones are on the remaining positions.
Using binomial we can have explanation written below:
The balls can be arranged in n! possible permutations.
To be precise one particular arrangement includes [tex]r!(n-r)![/tex] permutations. Since r black balls can be permuted in r! ways and white balls in (n-r)! different orders.
So basically it yields,
[tex]r! \times (n-r)![/tex] permutations.
So the actual amount is,
[tex]\frac{r!}{(n-r)!}= \binom{n}{r}=\binom{n}{n-r}[/tex]
