Question 14 Marks
Republic day is a national holiday of India. It honours the date on which the constitution of India came into effect on 26 January 1950 replacing the Government of India Act (1935) as the governing document of India and thus, turning the nation into a newly formed republic.
Answer the following question, which are based on the word "REPUBLIC".
(i) Find the number of arrangements of the letters of the word 'REPUBLIC'.
(a) 40300 (b) 30420 (c) 40320 (d) 40400
(ii) How many arrangements start with a vowel?
(a) 12015 (b) 15120 (c) 12018 (d) 15100
(iii) Which concept is used for finding the arrangements start with a vowel?
(a) Permutation (b) FPM (c) Combination (d) FPA
(iv) If the number of arrangements of the letters of the word 'REPUBLIC' is abcde, the (a + b + $\mathbf{c}+\mathbf{d}+\mathbf{e})$ is
(a) 10 (b) 9 (c) 8 (d) 15
(v) If the number of arrangements start with a vowel is abcde, then $(\mathbf{a}+\mathbf{b})-(\mathbf{d}+\mathbf{e})$ is
(a) 2 (b) 3 (c) 4 (d) 5
Answer the following question, which are based on the word "REPUBLIC".
(i) Find the number of arrangements of the letters of the word 'REPUBLIC'.
(a) 40300 (b) 30420 (c) 40320 (d) 40400
(ii) How many arrangements start with a vowel?
(a) 12015 (b) 15120 (c) 12018 (d) 15100
(iii) Which concept is used for finding the arrangements start with a vowel?
(a) Permutation (b) FPM (c) Combination (d) FPA
(iv) If the number of arrangements of the letters of the word 'REPUBLIC' is abcde, the (a + b + $\mathbf{c}+\mathbf{d}+\mathbf{e})$ is
(a) 10 (b) 9 (c) 8 (d) 15
(v) If the number of arrangements start with a vowel is abcde, then $(\mathbf{a}+\mathbf{b})-(\mathbf{d}+\mathbf{e})$ is
(a) 2 (b) 3 (c) 4 (d) 5
Answer
View full question & answer→(i) (c) The letters in the word 'REPUBLIC' are all distinct. There are 8 letters in the given word. So, the number of arrangements are 8 ! i.e. 40320.
(ii) (b) The vowels in a given word are ' $\mathrm{E}, \mathrm{I}, \mathrm{U}$ '. If we start a word from vowel, we can choose 1 vowel from 3 vowels in ${ }^3 \mathbf{C}_1$ ways. Further, remaining 7 letters can be arranged in 7 ! ways.
$\therefore$ Total number of arrangements start with a vowel
$
={ }^3 \mathrm{C}_1 \times 7 !=3 \times 5040=15120
$
(iii) (c) Combination
(iv) (b) Since, number of arrangements are 40320 .
On comparing, we get
$
\begin{gathered}
a=4, b=0, c=3, d=2, e=0 \\
\text { So, } a+b+c+d+e=4+0+3+2+0=9
\end{gathered}
$
(v) (c) Since, number of arrangements are 15120
On comparing, we get
$
\begin{gathered}
a=1, b=5, c=1, d=2, e=0 \\
\therefore(a+b)-(d+e)=(1+5)-(2+0)=6-2=4
\end{gathered}
$
(ii) (b) The vowels in a given word are ' $\mathrm{E}, \mathrm{I}, \mathrm{U}$ '. If we start a word from vowel, we can choose 1 vowel from 3 vowels in ${ }^3 \mathbf{C}_1$ ways. Further, remaining 7 letters can be arranged in 7 ! ways.
$\therefore$ Total number of arrangements start with a vowel
$
={ }^3 \mathrm{C}_1 \times 7 !=3 \times 5040=15120
$
(iii) (c) Combination
(iv) (b) Since, number of arrangements are 40320 .
On comparing, we get
$
\begin{gathered}
a=4, b=0, c=3, d=2, e=0 \\
\text { So, } a+b+c+d+e=4+0+3+2+0=9
\end{gathered}
$
(v) (c) Since, number of arrangements are 15120
On comparing, we get
$
\begin{gathered}
a=1, b=5, c=1, d=2, e=0 \\
\therefore(a+b)-(d+e)=(1+5)-(2+0)=6-2=4
\end{gathered}
$
