The value of ^n P_r is equal to - Vidyadip

MCQ

The value of $^n{P_r}$ is equal to

✓
$^{n - 1}{P_r} + r{\,^{n - 1}}{P_{r - 1}}$
B
$n.{\;^{n - 1}}{P_r}{ + ^{n - 1}}{P_{r - 1}}$
C
$n{(^{n - 1}}{P_r}{ + ^{n - 1}}{P_{r - 1}})$
D
$^{n - 1}{P_{r - 1}}{ + ^{n - 1}}{P_r}$

✓

Answer

Correct option: A.

$^{n - 1}{P_r} + r{\,^{n - 1}}{P_{r - 1}}$

a
(a) $^{n - 1}{P_r} + r{.^{n - 1}}{P_{r - 1}}$

$ = \frac{{(n - 1)\,!}}{{(n - 1 - r)\,!}} + r\frac{{(n - 1)\,!}}{{(n - r)\,!}}$

$\left( {\because \,\,{\,^n}{P_r} = \frac{{n\,!}}{{(n - r)\,!}}} \right)$

= $\frac{{(n - 1)\,!}}{{(n - 1 - r)\,!}}\,\,\left\{ {1 + r.\frac{1}{{n - r}}} \right\}$

= $\frac{{(n - 1)\,!}}{{(n - 1 - r)\,!(n - r)\,!}}\left( {\frac{n}{{n - r}}} \right) = \frac{{n\,!}}{{(n - r)\,!}} = {\,^n}{P_r}$.

Aliter : We know that $^{n - 1}{C_r} + {\,^{n - 1}}{C_{r - 1}} = {\,^n}{C_r}$

==> $\frac{{^{n - 1}{P_r}}}{{r\,!}} + \frac{{^{n - 1}{P_{r - 1}}}}{{(r - 1)\,!}} = \frac{{^n{P_r}}}{{r\,!}}$

==> $^{n - 1}{P_r} + r\,.{\,^{n - 1}}{P_{r - 1}} = {\,^n}{P_r}$.

Need a full question paper?

Generate a complete, print-ready paper with questions like this in minutes — across 16+ boards, with answer keys.

Start Generating Free

Explore more

More "M.C.Q (1 Marks)" from STD 11 - 6. permutation and combination→STD 11 - 6. permutation and combination — all question types→Maths STD 11 Science question papers→CBSE Board STD 11 Science question papers→CBSE Board question paper generator→

Similar questions

Which of the following has only one subset?

The number of way to sit $3$ men and $2 $ women in a bus such that total number of sitted men and women on each side is $3$

The equation $\sqrt{(\text{x}-2)^{2}+\text{y}^{2}}+\sqrt{(\text{x}+2)^{2}+\text{y}^{2}}=5$ represents:

The vertex of the parabola $3x - 2{y^2} - 4y + 7 = 0$ is

In the expansion of ${\left( {x - \frac{3}{{{x^2}}}} \right)^9},$ the term independent of $x$ is

Let $L$ is distance between two parallel normals of , $\frac{{{x^2}}}{{{a^2}}} + \frac{{{y^2}}}{{{b^2}}} = 1,\,\,\,a > b$ then maximum value of $L$ is

$\tan A + \cot (180^\circ + A) + \cot (90^\circ + A) + \cot (360^\circ - A)$

If $p$ be the length of the perpendicular from the origin on the line $\frac{\text{x}}{\text{a}}+\frac{\text{y}}{\text{b}}=1,$ then:

The contrapositive of $(p ∨ q) \rightarrow r$ is.

$1 + \frac{3}{2} + \frac{5}{{{2^2}}} + \frac{7}{{{2^3}}} + ......\,\infty \,$ is equal to