Question 11. If P(n, 5) : P(n, 3) = 2 : 1, find n.
Solution:
Given:
P(n, 5) : P(n, 3) = 2 : 1
\frac{P(n, 5) }{ P(n, 3)} = \frac{2 }{ 1} After applying the formula,
P (n, r) =
\frac{ n!}{(n โ r)!} P (n, 5) =
\frac{n!}{ (n โ 5)!} P (n, 3) =
\frac{n!}{ (n โ 3)!} So, from the question,
\frac{P (n, 5) }{ P(n, 3)} = \frac{2 }{ 1} After substituting the values in above expression we will get,
\frac{\frac{n!}{(n-5)!}}{\frac{n!}{(n-3)!}}=\frac{2}{1}\\ \frac{n!}{(n-5)!}\times\frac{(n-3)!}{n!}=\frac{2}{1} \\\frac{(n โ 3)! }{ (n โ 5)!} = \frac{2}{1}\\ \frac{[(n โ 3) (n โ 3 โ 1) (n โ 3 โ 2)!] }{ (n โ 5)!} = \frac{2}{1}\\ \frac{[(n โ 3) (n โ 4) (n โ 5)!]} { (n โ 5)!} = \frac{2}{1} (n โ 3)(n โ 4) = 2
n2 โ 3n โ 4n + 12 = 2
n2 โ 7n + 12 โ 2 = 0
n2 โ 7n + 10 = 0
n2 โ 5n โ 2n + 10 = 0
n (n โ 5) โ 2(n โ 5) = 0
(n โ 5) (n โ 2) = 0
n = 5 or 2
For, P (n, r): n โฅ r
โด n = 5 [for, P (n, 5)]
Question 12. Prove that:
1. P (1, 1) + 2. P (2, 2) + 3 . P (3, 3) + โฆ + n . P(n, n) = P(n + 1, n + 1) โ 1.
Solution:
By using the formula,
P (n, r) =
\frac{n!}{(n โ r)!} P (n, n) =
\frac{n!}{(n โ n)!} =
\frac{ n!}{0!} = n! [Since, 0! = 1]
Consider LHS:
= 1. P(1, 1) + 2. P(2, 2) + 3. P(3, 3) + โฆ + n . P(n, n)
= 1.1! + 2.2! + 3.3! +โฆโฆโฆ+ n.n! [Since, P(n, n) = n!]
=\sum_{r=1}^nr.r! \\ =\sum_{r=1}^nr.r!+r!-r! \\ \sum_{r=1}^n(r+1)r!-r!\\ \sum_{r=1}^n(r+1)!-r! = (2! โ 1!) + (3! โ 2!) + (4! โ 3!) + โฆโฆโฆ + (n! โ (n โ 1)!) + ((n+1)! โ n!)
= 2! โ 1! + 3! โ 2! + 4! โ 3! + โฆโฆโฆ + n! โ (n โ 1)! + (n+1)! โ n!
= (n + 1)! โ 1!
= (n + 1)! โ 1 [Since, P (n, n) = n!]
= P(n+1, n+1) โ 1
= RHS
Hence Proved.
Question 13. If P(15, r โ 1) : P(16, r โ 2) = 3 : 4, find r.
Solution:
Given:
P(15, r โ 1) : P(16, r โ 2) = 3 : 4
\frac{P(15, r โ 1) }{ P(16, r โ 2)} = \frac{3}{4} After applying the formula,
P (n, r) =
\frac{n!}{(n โ r)!} P (15, r โ 1) =
\frac{15! }{ (15 โ r + 1)!} =
\frac{15! }{ (16 โ r)!} P (16, r โ 2) =
\frac{16!}{(16 โ r + 2)!} =
\frac{16!}{(18 โ r)!} So, from the question,
\frac{P(15, r โ 1) }{ P(16, r โ 2)} = \frac{3}{4} After substituting the values in above expression we will get,
\frac{\frac{15!}{(16-r)!}}{\frac{16!}{(18-r)!}}=\frac{3}{4}\\ \frac{15! }{ (16 โ r)!} ร \frac{(18 โ r)! }{ 16!} = \frac{3}{4}\\ \frac{15! }{ (16 โ r)!} ร \frac{[(18 โ r) (18 โ r โ 1) (18 โ r โ 2)!]}{(16ร15!)} = \frac{3}{4}\\ \frac{1}{(16 โ r)!} ร \frac{[(18 โ r) (17 โ r) (16 โ r)!]}{16} = \frac{3}{4}\\ (18 โ r) (17 โ r) = \frac{3}{4} ร 16\\ (18 โ r) (17 โ r) = 12
306 โ 18r โ 17r + r2 = 12
306 โ 12 โ 35r + r2 = 0
r2 โ 35r + 294 = 0
r2 โ 21r โ 14r + 294 = 0
r(r โ 21) โ 14(r โ 21) = 0
(r โ 14) (r โ 21) = 0
r = 14 or 21
For, P(n, r): r โค n
โด r = 14 [for, P(15, r โ 1)]
Question 14. n+5Pn+1 = 11(n โ 1)/2 n+3Pn, find n.
Solution:
Given:
n+5Pn+1 = 11(n โ 1)/2 n+3Pn
P (n +5, n + 1) = 11(n โ 1)/2 P(n + 3, n)
By using the formula,
P (n, r) =
\frac{n!}{(n โ r)!} P(n + 5, n=1) =
\frac{(n+5)!}{(n+5-n-1)!}=\frac{(n+5)!}{4!}\\ P(n + 3, n) =
\frac{(n+3)!}{(n+3-n)!}=\frac{(n+3)!}{3!} So, from the question
P(n + 5, n + 1) = 11(n -1)/2P(n + 3, n)
After substituting the values in above expression we get,
\frac{(n+5)!}{4!}=\frac{11(n-1)}{2}\times\frac{(n+3)!}{3!}\\ \frac{(n+5)!}{(n-1)(n+3)!}=\frac{11}{2}\times\frac{4!}{3!}\\ \frac{(n+5)(n+5-1)(n+5-2)!}{(n-1)(n+3)!}=\frac{11}{2}\times\frac{4\times3!}{3!}\\ \frac{(n+5)(n+4)(n+3)!}{(n-1)(n+3)!}=\frac{44}{2}\\ \frac{(n+5)(n+4)}{n-1}=22 (n + 5) (n + 4) = 22 (n โ 1)
n2 + 4n + 5n + 20 = 22n โ 22
n2 + 9n + 20 โ 22n + 22 = 0
n2 โ 13n + 42 = 0
n2 โ 6n โ 7n + 42 = 0
n(n โ 6) โ 7(n โ 6) = 0
(n โ 7) (n โ 6) = 0
n = 7 or 6
โด The value of n can either be 6 or 7.
Question 15. In how many ways can five children stand in a queue?
Solution:
Number of arrangements of โnโ things taken all at a time = P (n, n)
Hence,
After applying the formula,
P (n, r) =
\frac{n!}{(n โ r)!} The total number of ways in which five children can stand in a queue = the number of arrangements of 5 things taken all at a time = P (5, 5)
Thus,
P (5, 5) =
\frac{5!}{(5 โ 5)!} =
\frac{5!}{0!} = 5! [Since, 0! = 1]
= 5 ร 4 ร 3 ร 2 ร 1
= 120
Therefore, Number of ways in which five children can stand in a queue are 120.
Question 16. From among the 36 teachers in a school, one principal and one vice-principal are to be appointed. In how many ways can this be done?
Solution:
Given:
The total number of teachers in a school = 36
As we know that, number of arrangements of n things taken r at a time = P(n, r)
After applying the formula,
P (n, r) =
\frac{n!}{(n โ r)!} โด The total number of ways in which this can be done = the number of arrangements of 36 things taken 2 at a time = P(36, 2)
P (36, 2) =
\frac{36!}{(36 โ 2)!} =
\frac{36!}{34!} =
\frac{(36 ร 35 ร 34!)}{34!} = 36 ร 35
= 1260
Hence, Number of ways in which one principal and one vice-principal are to be appointed out of total 36 teachers in school are 1260.
