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Permutations

Class 11th Mathematics RS Aggarwal Solution
Exercise 8a
  1. Compute:(i) {9!}/{ (5!) x (3!) } ! (ii) {32!}/{29!} (iii) { (12!)…
  2. Prove that LCM {6!, 7!, 8!} = 8!
  3. Prove that {1}/{10!} + frac {1}/{11!} + frac {1}/{12!} = frac {145!}/{12!} .…
  4. If {1}/{6!} + frac {1}/{7!} = frac {x}/{8!} , find the value of x.…
  5. Write the following products in factorial notation:(i) 6 × 7 × 8 × 9 × 10 × 11 ×…
  6. Which of the following are true of false?(i) (2 + 3) ! = 2 ! + 3!(ii) (2 × 3)! =…
  7. If (n + 1) ! = 12 × (n – 1) !, find the value of n.
  8. If (n + 2) ! = 2550 × n!, find the value of n.
  9. If (n + 3) ! = 56 × (n + 1) !, find the value of n.
  10. If {n!}/{ (2!) x (n-2) ! } : frac {n!}/{ (4!) times (n-4) ! } = 2 : 1,…
  11. If { (2n) ! }/{ (3!) x (2n-3) ! } : frac {n!}/{ (2!) times (n-2) ! } =…
  12. Evaluate {n!}/{ (r!) x (n-r) ! } , when n = 15 and r = 12.
  13. Prove that (n + 2) × (n!) + (n + 1) ! = (n!). (2n + 3)
  14. Prove that(i) {n!}/{r!} = n(n – 1) (n – 2) …. (r + 1)(ii) (n – r + 1).…
Exercise 8b
  1. There are 10 buses running between Delhi and Agra. In how many ways can a man go…
  2. A, B and C are three cities. There are 5 routes from A to B and 3 routes from B…
  3. There are 12 steamers plying between A and B. In how many ways could the round…
  4. In How many ways can 4 people be seated in a row containing 5 seats?…
  5. In How many ways can 5 ladies draw water from 5 taps, assuming the no tap…
  6. In a textbook on mathematics there are three exercises A, B and C consisting of…
  7. In a school, there are four sections of 40 students each in XI standard. In how…
  8. In how many ways can a vowel, a consonant and a digit be chosen out of the 26…
  9. How many 8-digit telephone numbers can be constructed using the digits 0 to 9 if…
  10. (ac and the outcomes are recorded. How many possible outcomes are there?(b) How…
  11. Find the number of different signals that can be generated by arranging at…
  12. How many 4-letter codes can be formed using the first 10 letters of the English…
  13. Given, A = {2, 3, 5} and B = {0, 1}. Find the number of different ordered pairs…
  14. How many arithmetic progressions with 10 terms are there whose first term in…
  15. There are 6 items in column A and 6 items in column B. A student is asked to…
  16. A mint prepares metallic calendars specifying months, dates and days in the…
  17. From among the 36 teachers in a school, one principal and one vice-principal…
  18. A sample of 3 bulbs is tested. A bulb is labeled as G if it is good and D if it…
  19. For a set of five true or false questions, no student has written the all…
  20. In how many ways can the following prizes be given away to a class of 20…
  21. Find the total number of ways of answering 5 objective-type question, each…
  22. A gentleman has 6 friends to invite. In how many ways can be send invitation…
  23. In how many ways 6 rings of different types can be worn in 4 fingers?…
  24. In how many ways can 5 letters be posted in 4 letter boxes?
  25. How many 3-letters words can be formed using a, b, c, d, e if(i) repetition of…
  26. How many 4-digit numbers are there, when a digit may be repeated any number of…
  27. How many numbers can be formed from the digits 1, 3, 5, 9 if repetition of…
  28. How many 3-digit numbers are there with no digit repeated?
  29. How many 3-digit numbers can be formed by using the digits 0, 1, 3, 5, 7 while…
  30. How many 6-digit numbers can be formed from the digits 0, 1, 3, 5, 7, 9 when no…
  31. How many natural numbers less than 1000 can be formed from the digits 0, 1, 2,…
  32. How many 6-digit telephone numbers can be constructed using the digits 0 to 9,…
  33. In how many ways can three jobs, I, II and III be assigned to three persons A,…
  34. A number lock on a suitcase has three wheels each labeled with ten digits 0 to…
  35. A customer forgets a four-digit code for an automated teller machine (ATM) in a…
  36. In how many ways can 3 prizes be distributed among 4 girls, when(i) no girl…
Exercise 8c
  1. 10P4 Evaluate:
  2. 62P3 Evaluate:
  3. 6P6 Evaluate:
  4. 9P0 Evaluate:
  5. Prove that 9P3 + 3 × 9P2 = 10P3.
  6. (i) If nP5 = 20 × nP3, find n.(ii) If 16 × nP3 = 13 × n+1P3, find n.(iii) If…
  7. (i) If If 5Pr = 2 × 6Pr–1, find r.(ii) If 20Pr = 13 × 20Pr–1, find r.(iii) If…
  8. (i) If nP4 : nP5, = 1 : 2, find n.(ii) If n–1P3 : n+1P3, = 5 : 12, find n.…
  9. If 15Pr–1 : 16Pr–2, = 3 : 4, find r.
  10. If 2n–1Pn : 2n+1Pn–1, = 22 : 7, find n.
  11. Find n, If n+5Pn+1 = {11}/{2} (n – 1). n+3Pn, find n.
  12. Prove that 1 + 1. 1P1 + 2. 2P2 + 3. 3P3 + …. n. nPn = n+1Pn+1.
  13. Find the number of permutations of 10 objects, taken 4 at a time.…
Exercise 8d
  1. In how many ways can 5 persons occupy 3 vacant seats?
  2. In how many ways can 7 people line up at a ticket window of a cinema hall?…
  3. In how many ways can 5 children stand in a queue?
  4. In how many ways can 6 women draw water from 6 wells if no well remains unused?…
  5. In how many ways can 4 different books, one each in chemistry, physics, biology…
  6. Six students are contesting the election for the presidentship of the students,…
  7. It is required to seat 5 men and 3 women in a row so that the women occupy the…
  8. There are 6 items in column A and 6 items in column B. A student is asked to…
  9. Five letters F, K, R, R and V one in each were purchased from a plastic…
  10. Ten students are participating in a race. In how many ways can the first three…
  11. If there are 6 periods on each working day of a school, in how many ways can…
  12. In how many ways can 6 pictures be hung from 4 picture nails on a wall?…
  13. Find the number of words formed (may be meaningless) by using all the letters…
  14. Find the number of different 4-letter words (may be meaningless) that can be…
  15. How many words can be formed from the letters of the word ‘SUNDAY’? How many of…
  16. How many words beginning with C and ending with Y can be formed by using the…
  17. Find the number of permutations of the letters of the word ‘ENGLISH’. How many…
  18. In how many ways can the letters of the word ‘HEXAGON’ be permuted? In how many…
  19. How many words can be formed out of the letters of the word ‘ORIENTAL’ so that…
  20. In how many ways can the letters of the word ‘FAILURE’ be arranged so that the…
  21. In how many arrangements of the word ‘GOLDEN’ will the vowels never occur…
  22. Find the number of ways in which the letters of the word ‘MACHINE’ can be…
  23. How many permutations can be formed by the letters of the word ‘VOWELS’,…
  24. How many numbers divisible by 5 and lying between 3000 and 4000 can be formed…
  25. In an examination, there are 8 candidates out of which 3 candidates have to…
  26. In how many ways can 5 children be arranged in a line such that(i) two of them,…
  27. when a group photograph is taken, all the seven teachers should be in the first…
  28. Find the number of ways in which m boys and n girls may be arranged in a row so…
Exercise 8e
  1. Find the total number of permutations of the letters of each of the words given…
  2. In how many ways can the letters of the expression x2y2z4 be arranged when…
  3. There are 3 blue balls, 4 red balls and 5 green balls. In how many ways can they…
  4. A child has three plastic toys bearing the digits 3, 3, 5 respectively. How many…
  5. How many different signals can be transmitted by arranging 2 red, 3 yellow and 2…
  6. How many words can be formed by arranging the letters of the word ‘ARRANGEMENT’,…
  7. How many words can be formed by arranging the letters of the word ‘INDIA’, so…
  8. Find the number of arrangements of the letters of the word ‘ALGEBRA’ without…
  9. How many words can be formed from the letters of the word ‘SERIES’, which start…
  10. In how many ways can the letters of the word ‘PARALLEL’ be arranged so that all…
  11. How many different words can be formed with the letters of the word ‘CAPTAIN’?…
  12. In how many ways can the letters of the word ‘ASSASSINATION’ be arranged so…
  13. (i)How many arrangements can be made by using all the letters of the word…
  14. In how many ways can the letters of the word ‘INTERMEDIATE’ be arranged so…
  15. (i)Find the number of different words by using all the letters of the word,…
  16. How many five - digit numbers can be formed with the digits 5, 4, 3, 5, 3?…
  17. How many numbers can be formed with the digits 2, 3, 4, 5, 4, 3, 2 so that the…
  18. How many 7 - digit numbers can be formed by using the digits 1, 2, 0, 2, 4, 2,…
  19. How many 6 - digit numbers can be formed by using the digits 4, 5, 0, 3, 4, 5?…
  20. The letters of the word ‘INDIA’ are arranged as in a dictionary. What are the…
Exercise 8f
  1. A child has 6 pockets. In how many ways, he can put 5 marbles in his pocket?…
  2. In how many ways can 5 bananas be distributed among 3 boys, there being no…
  3. In how many ways can 3 letters can be posted in 2 letterboxes?
  4. How many 3-digit numbers are there when a digit may be repeated any numbers of…
  5. How many 4-digit numbers can be formed with the digits 0, 2, 3, 4, 5 when a…
  6. In how many ways can 4 prizes be given to 3 boys when a boy is eligible for all…
  7. There are 4 candidates for the post of a chairman, and one is to be elected by…
Exercise 8g
  1. In how many ways can 6 persons be arranged in(i) a line, (ii) a circle?…
  2. There are 5 men and 5 ladies to dine at a round table. In how many ways can they…
  3. In how many ways can 11 members of a committee sit at a round table so that the…
  4. In how many ways can 8 persons be seated at a round table so that all shall not…
  5. In how many differents ways can 20 different pearls be arranged to form a…
  6. In how many different ways can a garland of 16 different flowers be made?…
Exercise 8h
  1. If (n + 1)! = 12 × [(n – 1)!], find the value of n.
  2. If {1}/{4!} + frac {1}/{5!} = frac {x}/{6!} , find the value of x.…
  3. How many 3-digit numbers are there with no digit repeated?
  4. How many 3-digit numbers above 600 can be formed by using the digits 2, 3, 4, 5,…
  5. How many numbers divisible by 5 and lying between 4000 and 5000 can be formed…
  6. In how many ways can the letters of the word ‘CHEESE’ be arranged?…
  7. In how many ways can the letters of the word ‘PERMUTATIONS’ be arranged if each…
  8. How many different words can be formed by using all the letters of the word…
  9. How many permutations of the letters of the word ‘APPLE’ are there?…
  10. How many words can be formed by the letters of the word ‘SUNDAY’?…
  11. In how many ways can 4 letters be posted in 5 letter boxes?
  12. In how many ways can 4 women draw water from 4 taps if no tap remains unused?…
  13. How many 5-digit numbers can be formed by using the digits 0, 1 and 2?…
  14. In how many ways can 5 boys and 3 girls be seated in a row so that each girl is…
  15. A child has plastic toys bearing the digits 4, 4 and 5. How many 3-digit…
  16. In how many ways can the letters of the word ‘PENCIL’ be arranged so that N is…

Exercise 8a
Question 1.

Compute:

(i)

(ii)

(iii)


Answer:

(i) To Find : Value of


Formulae :




Let,



By using above formula, we can write,



Cancelling (5!) from numerator and denominator we get,



∴x = 504


Conclusion : Hence, value of the expression is 504.


(ii) To Find : Value of


Formula :


Let,



By using the above formula we can write,



Cancelling (29!) from numerator and denominator,


∴x = 32 × 31 × 30


∴x = 29760


Conclusion : Hence, the value of the expression is 29760.


(iii) To Find : Value of


Formula :


Let,



By using the above formula we can write,



Taking (9!) common from numerator,



Cancelling (9!) from numerator and denominator,


∴x = (12 × 11 × 10) - 10


∴x = 1310


Conclusion : Hence, the value of the expression is 1310.



Question 2.

Prove that LCM {6!, 7!, 8!} = 8!


Answer:

To Prove : LCM {6!, 7!, 8!} = 8!


Formula :


LCM is the smallest possible number that is a multiple of two or more numbers.


Here, we observe that (8!) is the first number which is a multiple of all three given numbers i.e. 6!, 7! and 8!.





Therefore, 8! is the LCM of {6!, 7!, 8!}


Conclusion : Hence proved



Question 3.

Prove that .


Answer:

To Prove :



Formula : n! = n × (n - 1)!



=



=


= R.H.S.


∴L.H.S. = R.H.S.


Conclusion :



Question 4.

If , find the value of x.


Answer:

Given Equation :



To Find : Value of x.


Formula :


By given equation,




By using the above formula we can write,




Cancelling (8!) from both the sides,


∴x = 64


Conclusion : Value of x is 64.



Question 5.

Write the following products in factorial notation:

(i) 6 × 7 × 8 × 9 × 10 × 11 × 12

(ii) 3 × 6 × 9 × 12 × 15


Answer:

(i) Formula :


Let ,



Multiplying and dividing by



From the above formula,



Conclusion :



(ii) Formula :


Let ,



Above equation can be written as




By using above formula,



Conclusion :




Question 6.

Which of the following are true of false?

(i) (2 + 3) ! = 2 ! + 3!

(ii) (2 × 3)! = (2!) × (3!)


Answer:

Option (i) and (ii) both are false


Proofs :


For option (i),


L.H.S. = (2 + 3)! = (5!) = 120


R.H.S. = (2!) + (3!) = 2 + 6 = 8


∴L.H.S. ≠R.H.S.


For option (ii),


L.H.S. = (2 × 3)! = (6!) = 720


R.H.S = (2!) × (3!) = 4 × 6 = 24


∴L.H.S. ≠R.H.S.


Important Notes : for any two whole numbers a and b,





Question 7.

If (n + 1) ! = 12 × (n – 1) !, find the value of n.


Answer:

Given Equation :


(n + 1)! = 12 × (n - 1)!


To Find : Value of n


Formula :


By given equation,


(n + 1)! = 12 × (n - 1)!


By using above formula we can write,


∴(n + 1) × (n) × (n - 1)! = 12 × (n - 1)!


Cancelling the term (n - 1)! from both the sides,


∴(n + 1) × (n) = 12 …….. eq(1)


∴(n + 1) × (n) = (4) × (3)


Comparing both the sides, we get,


∴n = 3


Conclusion : Value of n is 3.


Note : Instead of taking product of two brackets in eq(1), it is easy to convert the constant term that is 12 into product of two consecutive numbers and then by observing two sides of equation we can get value of n.



Question 8.

If (n + 2) ! = 2550 × n!, find the value of n.


Answer:

Given Equation :



To Find : Value of n


Formula :


By given equation,


(n + 2)! = 2550 × n!


By using above formula we can write,


∴ (n + 2) × (n + 1) × (n!) = 2550 × n!


Cancelling the term (n)! from both the sides,


∴ (n + 2) × (n + 1) = 2550


∴ (n + 2) × (n + 1) = (51) × (50)


Comparing both the sides, we get,


∴n = 49


Conclusion : Value of n is 49.


Note : Instead of taking product of two brackets in eq(1), it is easy to convert the constant term that is 2550 into product of two consecutive numbers and then by observing two sides of equation we can get value of n.



Question 9.

If (n + 3) ! = 56 × (n + 1) !, find the value of n.


Answer:

Given Equation :



To Find : Value of n


Formula :


By given equation,


(n + 3)! = 56 × (n + 1)!


By using above formula we can write,


∴(n + 3) × (n + 2) × (n + 1)! = 56 × (n + 1)!


Cancelling the term (n + 1)! from both the sides,


∴ (n + 3) × (n + 2) = 56


∴ (n + 3) × (n + 2) = (8) × (7)


Comparing both the sides, we get,


∴n = 5


Conclusion : Value of n is 5.


Note : Instead of taking product of two brackets in eq(1), it is easy to convert the constant term that is 56 into product of two consecutive numbers and then by observing two sides of equation we can get value of n.



Question 10.

If = 2 : 1, find the value of n.


Answer:

Given Equation :



To Find : Value of n


Formula :


By given equation,





By using above formula,



Cancelling terms (n - 4)! And (2!),



∴ (n - 2) × (n - 3) = 6


∴ (n - 2) × (n - 3) = (3) × (2)


By comparing both the sides,



Conclusion : Value of n is 5.


Note : Instead of taking product of two brackets in eq(1), it is easy to convert the constant term that is 6 into product of two consecutive numbers and then by observing two sides of equation we can get value of n.



Question 11.

If = 44 : 3, find the value of n.


Answer:

Given Equation :



To Find : Value of n


Formula :


By given equation,





By using above formula,



Cancelling terms (n - 2)! , (2!), (2n - 3)! & n, we get,



….. taking 2 common from the term (2n - 2)



∴ (2n - 1) = 11


∴n = 6


Conclusion : Value of n is 6.



Question 12.

Evaluate , when n = 15 and r = 12.


Answer:

Given : n = 15 and r = 12


To Find : Value of at given n and r


Formula :




Let ,



Substituting n = 15 and r = 12 in above equation,




By using above formula,



Cancelling (12!) from numerator & denominator,



∴x = 455


Conclusion : Value of at n = 15 and r = 12 is 6.



Question 13.

Prove that (n + 2) × (n!) + (n + 1) ! = (n!). (2n + 3)


Answer:

To Prove :


Formula :


L.H.S. = (n + 2) × (n!) + (n + 1)!


= (n + 2) × (n!) + (n + 1) × (n!)


= (n!) × [(n + 2) + (n + 1)]


= (n!) × (2n + 3)


= R.H.S.


∴L.H.S. = R.H.S.


Conclusion : (n + 2) × (n!) + (n + 1)! = (n!) × (2n + 3)



Question 14.

Prove that

(i) = n(n – 1) (n – 2) …. (r + 1)

(ii) (n – r + 1).

(iii)


Answer:

(i) To Prove :


Formula :



Writing (n!) in terms of (r!) by using above formula,


=


Cancelling (r!),


= n(n - 1)(n - 2)…. (r + 1)


= R.H.S.


∴LHS = RHS


Note : In permutation and combination r is always less than n, so we can write n! in terms of r! by using given formula.


(ii) To Prove :


Formula :



by using above formula,



Cancelling (n - r + 1),



= R.H.S.


∴LHS = RHS


(iii) To Prove :


Formula :



by using above formula,




Taking common,





= R.H.S.


∴LHS = RHS




Exercise 8b
Question 1.

There are 10 buses running between Delhi and Agra. In how many ways can a man go from Delhi to Agra and return by a different bus?


Answer:

Given: 10 buses running between Delhi and Agra.


To Find: Number of ways a man can go from Delhi to Agra and return by a different bus.


There are 10 buses running between Delhi and Agra so there are 10 different ways to go from Delhi to Agra. The man cannot return from the same bus he went so number of ways are reduced to 9.


These second event occur in completion of first event so there are:10 × 9=90 ways in which a man can go from Delhi to Agra and return by a different bus.



Question 2.

A, B and C are three cities. There are 5 routes from A to B and 3 routes from B to C. How many different routes are there from A to C via B?


Answer:

Given: 5 routes from A to B and 3 routes from B to C.


To find: number of different routes from A to C via B.


Let E1 be the event : 5 routes from A to B


Let E2 be the event : 3 routes from B to C


Since going from A to C via B is only possible if both the events E1 and E2 occur simultaneously.


So there are 5 × 3=15 different routes from A to C via B.



Question 3.

There are 12 steamers plying between A and B. In how many ways could the round trip from A be made if the return was made on (i) the same steamer? (ii) a different steamer?


Answer:

Given: 12 steamers plying between A and B.


To find: number of ways the round trip from A can be made.


i) The steamer which will go from A to B will be returning back,since the given condition is that same steamer should return.


There are 12 steamers available so there are 12 different ways to make around trip between A & B if done on same steamer.


ii)If the return trip is done on different steamer than the once used in trip on going from A to B then the possible number of ways are:12 × 11=132.


(11 because the once used in going from A to B cannot be used in returning hence, reduced by 1.)



Question 4.

In How many ways can 4 people be seated in a row containing 5 seats?


Answer:

To find :number of ways in which 4 people can be seated in a row containing 5 seats.


The possible number of ways in which 4 people be seated in a row containing 5 seats =7P4 (There are 5 places to be filled with 4 persons where arrangement doesn’t matter.)


7P4(nPr )



=7 × 6 × 5 × 4


=840



Question 5.

In How many ways can 5 ladies draw water from 5 taps, assuming the no tap remains unused?


Answer:

To find: number of ways in which 5 ladies draw water from 5 taps.


Condition: no tap remains unused


The condition given is that no well shold remain unused.


So possible number of ways are:5 × 4 × 3 × 2 × 1=120.



Question 6.

In a textbook on mathematics there are three exercises A, B and C consisting of 12, 18 and 10 questions respectively. In how many ways can three questions be selected choosing one from each exercise?


Answer:

Given: three exercises A, B and C consisting of 12, 18 and 10 questions respectively.


To find: number of ways in which three questions be selected choosing one from each exercise.


Ways of selecting one question from exercise A:12C1 (way of selecting one element from n number of elements.)


Ways of selecting one question from exercise B:18C1


Ways of selecting one question from exercise C:10C1


So number of ways of choosing one question from each exercise A ,B,C =12C1 × 18C1 × 10C1


=12 × 18 × 10


=2160



Question 7.

In a school, there are four sections of 40 students each in XI standard. In how many ways can a set of 4 student representatives be chosen, one from each section?


Answer:

Given: there are four sections of 40 students each in XI standard.


To find : number of ways in which a set of 4 student representatives be chosen, one from each section.


Ways of selecting one student from section 1:40C1


Ways of selecting one student from section 2:40C1


Ways of selecting one student from section 3:40C1


Ways of selecting one student from section 4:40C1



So number of ways of choosing a set of 4 student representatives one from each section=40C1 × 40C1 × 40C1 × 40C1


=40 × 40 × 40 × 40


=2560000



Question 8.

In how many ways can a vowel, a consonant and a digit be chosen out of the 26 letters of the English alphabet and the 10 digits?


Answer:

To find: number of ways in which a vowel, a consonant and a digit be chosen out of the 26 letters of the English alphabet and the 10 digits.


e.g.



Way of selecting a vowel from 5 vowels=5C1


Way of selecting a consonant from 26 consonants=21C1


Way of selecting a digit from 10 digits=10C1


So ways of choosing a vowel, a consonant, a digit=5C1 × 21C1 × 10C1


=5 × 21 × 10


=1050



Question 9.

How many 8-digit telephone numbers can be constructed using the digits 0 to 9 if each number starts with 270 and n digit appears more than once?


Answer:

Given:8 digit telephone number starts with 270 .


To find: How many 8-digit telephone numbers can be constructed?



There are 10 digits between 0 to 9,and three of them are utilized in filling up the first three digits i.e.270 of the 8 digit phone number,so remaining number of digits=10-3=7,and this need to be used in filling up the remaining 8-3=5 places of the telephone number.


i.e.the remaining 5 places need to filled up with any one of:1,3,4,5,6,8,9


So, number of ways=7 × 6 × 5 × 4 × 3=2520.



Question 10.

(ac and the outcomes are recorded. How many possible outcomes are there?

(b) How many possible outcomes if the coin is tossed.

(i) four times? (ii) five times? (iii) n times?


Answer:

a) A coin is tossed three times


So possible number of outcomes=23=8


(HHH,HHT,HTH,HTT,THH,THT,TTH,TTT)


b)


i) A coin is tossed four times


So possible number of outcomes=24=16


(HHHH,HHHT,HHTH,HHTT,HTHH,HTHT,HTTH,HTTT,THHH,THHT,THTH,THTT,TTHH,TTHT,TTTH,TTTT)


ii) A coin is tossed n times


So possible number of outcomes=2n



Question 11.

Find the number of different signals that can be generated by arranging at least 2 flags in order (one below the other) on a vertical staff, if five different flags are available.


Answer:

Given:5 Flags




Way of generating signal using 2 different flags =5P2 (way of selecting 2 things out of 5 things with considering arrangement.)


Way of generating signal using 3 different flags =5P3


Way of generating signal using 4 different flags =5P4


Way of generating signal using 5 different flags =5P5


So total number of ways =5P2 + 5P3 + 5P4 + 5P5


=20 + 60 + 120 + 120


=320



Question 12.

How many 4-letter codes can be formed using the first 10 letters of the English alphabet, if no letter can be repeated?


Answer:

Given: first 10 letters of the English alphabet.


In 4 letter code for first position there are 10 possibilties for second position there are 9 possibilities ,for third position there are 8 possibilities and for fourth position there are 7 posiibilities since repetition is not allowed.


So total numbers of combination=10 × 9 × 8 × 7=5040



Question 13.

Given, A = {2, 3, 5} and B = {0, 1}. Find the number of different ordered pairs in which the first entry is an element of A and the second is an element of B.


Answer:

This is the example of Cartesian product of two sets.


The pairs in which the first entry is an element of A and the second is an element of B are :


(2,0),(2,1),(3,0),(3,1),(5,0),(5,1)


⇒3 × 2=6



Question 14.

How many arithmetic progressions with 10 terms are there whose first term in the set {1, 2, 3} and whose common difference is in the set {2, 3, 4}?


Answer:

Given: Two sets: {1, 2, 3} & {2, 3, 4}


To find: number of A.P. with 10n terms whose first term is in the set {1, 2, 3} and whose common difference is in the set {2, 3, 4}


Number of arithmetic progressions with 10 terms whose first term are in the set {1, 2, 3} and whose common difference is in the set {2, 3, 4} are:3 × 3=9


(3 because there are three elements in the set {1, 2, 3} and another 3 because there are three elements in the set {2, 3, 4})



Question 15.

There are 6 items in column A and 6 items in column B. A student is asked to match each item in column A with an item in column B. How many possible (correct or incorrect) answers are there to this question?


Answer:


As we can see that For Item2 there can be any of the match


So, For each item in column A there are 6 different options in column B since we don’t have to think about correct or incorrect matching.


So possible number of combinations possible to answer:


6 × 5 × 4 × 3 × 2 × 1=720



Question 16.

A mint prepares metallic calendars specifying months, dates and days in the form of monthly sheets (one plate for each month). How many types of February calendars should it prepare to serve for all the possibilities in the future years?


Answer:

To find: types of February calendars that can be prepared.


There are two factors to develop FEBRUARY metallic calendars


1)The day on the start of the year of which possibility=7


2)whether the year is leap year or not of which possibility is =2


So, number of FEBRUARY calendars possibilities to serve in future years=7 × 2=14



Question 17.

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?


Answer:

Given: 36 teachers are there in a school.


To find: Number of ways in which one principal and one vice-principal can be appointed.


There are 36 options of appointing principal and 35 option of appointing vice-principal since same teacher cannot be appointed as principal and vice-principal.


Total number of ways=36 × 35=1260



Question 18.

A sample of 3 bulbs is tested. A bulb is labeled as G if it is good and D if it is defective. Find the number of all possible outcomes.


Answer:

A bulb can be good or defective ,so there are 2 different possibilities of a bulb.


So number of all possibile outcomes(of all bulbs)=2 × 2 × 2=8



Question 19.

For a set of five true or false questions, no student has written the all correct answer and no two students have given the same sequence of answers. What is the maximum number of students in the class for this to be possible?


Answer:

Given: a set of five true – false questions.


To find: the maximum number of students in the class.


Condition: no student has written the all correct answer and no two students have given the same sequence of answers.


The total number of answering a set of 5 true or false question=25=32


Since, no two students have given the same sequence of answers and no student has written the all correct answer.


Therefore total possibilities reduces by 1(of no student has written the all correct answer)


⇒25-1=32-1=31



Question 20.

In how many ways can the following prizes be given away to a class of 20 students :first and second in mathematics; first and second in chemistry; first in physics and first in English?


Answer:

Given: 20 students.


The number of ways of giving first and second prizes in mathematics to a class of 20 students=20 × 19.


(First prize can be given to any one of the 20 students but the second prize cannot be given to the student that received the first prize so the number of candidates for the second prize is 19.)


The number of ways of giving first and second prizes in chemistry


to a class of 20 students=20 × 19.


The number of ways of giving first prize in physics to a class of 20 students=20


The number of ways of giving first prize in english to a class of 20 students=20


So total numbe of ways=20 × 19 × 20 × 19 × 20 × 20=57760000



Question 21.

Find the total number of ways of answering 5 objective-type question, each question having 4 choices.


Answer:

Given: 5 objective-type question, each question having 4 choices.


To find: the number of ways of answering them.


Each objective-type question has 4 choices.


So the total number of ways of answering 5 objective-type question, each question having 4 choices=4 × 4 × 4 × 4 × 4=45



Question 22.

A gentleman has 6 friends to invite. In how many ways can be send invitation cards to them, if he has 3 servants to carry the cards?


Answer:

Given: A gentleman has 6 friends to invite. He has 3 servants to carry the cards.


Each friend can be invited by 3 possible number of servants.


So the number of ways of inviting 6 friends using 3 servants=3 × 3 × 3 × 3 × 3 × 3=36



Question 23.

In how many ways 6 rings of different types can be worn in 4 fingers?


Answer:

Given:6 rings and 4 fingers.


Each ring has 4 different fingers that they can be worn.


So total number of ways in which 6 rings of different types can be worn in 4 fingers =4 × 4 × 4 × 4 × 4 × 4=46



Question 24.

In how many ways can 5 letters be posted in 4 letter boxes?


Answer:

Each letter has 4 possible letter boxes option.


So the number of ways in which 5 letters can be posted in 4 letter boxes =4 × 4 × 4 × 4 × 4=45 (Each 4 for each letter.)



Question 25.

How many 3-letters words can be formed using a, b, c, d, e if

(i) repetition of letters is not allowed?

(ii) repetition of letters is allowed


Answer:



i)if repetition of letters is not allowed then number of many 3-letters words that can be formed using a, b, c, d, e are


5 × 4 × 3=60



ii) if repetition of letters is allowed then number of many 3-letters words that can be formed using a, b, c, d, e are


5 × 5 × 5=125



Question 26.

How many 4-digit numbers are there, when a digit may be repeated any number of times?


Answer:

To find: Number of 4 digit numbers when a digit may be repeated any number of times


The first place has possibilities of any of 9 digits.


(0 not included because 0 in starting would make the number a 3 digit number.)


The second place has possibilities of any of 10 digits.


The third place has possibilities of any of 10 digits.


The fourth place has possibilities of any of 10 digits.


Since repetition is allowed.


So there are 9 × 10 × 10 × 10=9000 4-digit numbers when a digit may be repeated any number of times.



Question 27.

How many numbers can be formed from the digits 1, 3, 5, 9 if repetition of digits is not allowed?


Answer:

To find: number of numbers that can be formed from the digits 1, 3, 5, 9 if repetition of digits is not allowed


Forming a 4 digit number:4!


Forming a 3 digit number:4C3 × 3!


Forming a 2 digit number:4C2 × 2!


Forming a 1 digit number:4


So total number of ways=4! + ( 4C3 × 3!) + ( 4C2 × 2!) + 4


=24 + 24 + 12 + 4


=64



Question 28.

How many 3-digit numbers are there with no digit repeated?


Answer:


In forming a 3 digit number the 100’s place can be occupied by any 9 out of 10 digits(0 not included because it will lead to formation of 2 digit number.)


The 10’s place can be occupied by any of the remaining 9 digits(here 0 can or cannot be used.)


In one’s place any of the remaing 8 digits can be used.


So total 3-digit numbers with no digit repeated are:9 × 9 × 8=648.



Question 29.

How many 3-digit numbers can be formed by using the digits 0, 1, 3, 5, 7 while each digit may be repeated any number of times?


Answer:

100’s place 10’s place Unit’s place


There are total 5 digits available ,for forming a 3 digit number,in 100’s place only 1,3,5,7 can be used(0 not included because it will lead to formation of 2 digit number.)


In 10’s place any of the 5 can be used and same is the case with one’s place.


So total number of 3 digit numbers formed=4 × 5 × 5=100



Question 30.

How many 6-digit numbers can be formed from the digits 0, 1, 3, 5, 7, 9 when no digit is repeated? How many of them are divisible by 10?


Answer:


There are total 6 digits available ,for forming a 6 digit number,in 100000’s place only 1,3,5,7,9 can be used(0 not included because it will lead to formation of 2 digit number.)


In 10000’s place any of the remaining 5 digits can be used(even 0 can be used.)


In 1000’s place any of the remaining 4 digits can be used.


In 100’s place any of the remaining 3 digits can be used.


In 10’s place any of the remaining 2 digits can be used.


In one’s place the remaining digit can be used.


So total number of 6 digit numbers possible=5 × 5 × 4 × 3 × 2 × 1=600


For finding the number of 6 digit numbers divisible by 10 the one’s place should contain 0 so possibilities=5 × 4 × 3 × 2 × 1=120



Question 31.

How many natural numbers less than 1000 can be formed from the digits 0, 1, 2, 3, 4, 5 when a digit may be repeated any number of times?


Answer:

To find: number of natural numbers less than 1000 that can be formed from the digits 0, 1, 2, 3, 4, 5 when a digit may be repeated any number of times


For forming a 3 digit number less than 1000 possible ways are:


5 × 6 × 6…(in 100’s place 5 digits are only possible 0 not included.)


=180


For forming a 2 digit number less than 1000 possible ways are:


5 × 6……(in 10’s place 5 digits are only possible 0 not included.)


=30


For forming a 1 digit number less than 1000 possible ways are:


5…(0 not included because it is a whole number and natural number is asked in question.)


So total number of numbers less than 1000 that can be formed from the digits 0, 1, 2, 3, 4, 5 when a digit may be repeated any number of times=180 + 30 + 5=215



Question 32.

How many 6-digit telephone numbers can be constructed using the digits 0 to 9, if each number starts with 67 and no digit appears more than once?


Answer:

To find: 6-digit telephone numbers that can be constructed using the digits 0 to 9.


Condition: each number starts with 67 and no digit appears more than once



There are 10 digits between 0 to 9,and two of them are utilized in filling up the first two digits i.e.67 of the 6 digit phone number, so remaining number of digits=10-2=8,and this need to be used in filling up the remaining 6-2=4 places of the telephone number.


So, number of ways=8 × 7 × 6 × 5=1680.



Question 33.

In how many ways can three jobs, I, II and III be assigned to three persons A, B and C if one person is assigned only one job and all are capable of doing each job?


Answer:

Given: three jobs, I, II and III to be assigned to three persons A, B and C.


To find: In how many ways this can be done.


Condition: one person is assigned only one job and all are capable of doing each job.


It is given that one person is assigned only one job and all are capable of doing each job.


So if for person one 3 options are available ,for peson two 2 options and for person three only one option is available.


So total number of ways in which three jobs, I, II and III be assigned to three persons A, B and C if one person is assigned only one job and all are capable of doing each job=3 × 2 × 1=6



Question 34.

A number lock on a suitcase has three wheels each labeled with ten digits 0 to 9. if opening of the lock is a particular sequence of three digits with no repeats, how many such sequences will be possible? Also, find the number of unsuccessful attempts to open the lock.


Answer:


The number of sequences possible =10 × 9 × 8=720(since no repeated digits is the given condition.)


There will be only one successful attempt so the number of unsuccessful attempts to open the lock=720-1=719.



Question 35.

A customer forgets a four-digit code for an automated teller machine (ATM) in a bank. However, he remembers that this code consists of digits 3, 5, 6, 9. Find the largest possible number of trials necessary to obtain the correct code.


Answer:

Given: code consists of digits 3, 5, 6, 9.


To find: the largest possible number of trials necessary to obtain the correct code.


The customer remembers that this 4 digit code consists of digits 3, 5, 6, 9.


So the largest possible number of trials necessary to obtain the correct code=4!=4 × 3 × 2 × 1=24



Question 36.

In how many ways can 3 prizes be distributed among 4 girls, when

(i) no girl gets more than one prize?

(ii) a girl may get any number of prizes?

(iii) no girl gets all the prizes?


Answer:

i)To distribute 3 prizes among 4 girls where no girl gets more than one prize the possible number of permutation possible are:4P3=24


ii) To distribute 3 prizes among 4 girls where a girl may get any number of prizes the number of possibilities are:4 × 4 × 4=64.


(since a prize can be given to any of the 4 girls.)


iii) To distribute 3 prizes among 4 girls where no girl gets all the prizes the number of possibilities are:(4 × 4 × 4)-(4)=64-4=60


(the situation where a single girl gets all the prizes has to reduced from the situation where a girl may get any number of prizes.)




Exercise 8c
Question 1.

Evaluate:

10P4


Answer:

To find: the value of 10P4


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


Therefore,


10P4


10P410 × 9 × 8 × 7


10P45040


Thus, the value of 10P4 is 5040.



Question 2.

Evaluate:

62P3


Answer:

To find: the value of 62P3


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


Therefore,


62P3


62P3 = 62 × 61 × 60 × 59 = 226920


Thus, the value of 62P3 is 226920.



Question 3.

Evaluate:

6P6


Answer:

To find: the value of 6P6


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


Therefore,


6P6


62P3 = 6 × 5 × 4 × 3 × 2× 1= 720


Thus, the value of 6P6 is 720.



Question 4.

Evaluate:

9P0


Answer:

To find: the value of 9P0


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


Therefore,


9P0


9P0 = 1


Thus, the value of 9P0 is 1.



Question 5.

Prove that 9P3 + 3 × 9P2 = 10P3.


Answer:

To Prove: 9P3 + 3 × 9P2 = 10P3


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


The equation given below needs to be proved i.e


9P3 + 3 × 9P2 = 10P3.


+


(9 × 8 × 7) + (3 × 9 × 8) = 10 × 9 × 8


10 × 9 × 8 = 10 × 9 × 8


Hence, proved.


9P3 + 3 × 9P2 = 10P3.



Question 6.

(i) If nP5 = 20 × nP3, find n.

(ii) If 16 × nP3 = 13 × n+1P3, find n.

(iii) If 2nP3 = 100 × nP2, find n.


Answer:

(i) To find: the value of n


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


nP5 = 20 × nP3.





20 = (n - 3)(n - 4)




(n - 8)(n + 1) = 0


n = 8, -1


We know, that n cannot be a negative number.


Hence, value of n is 8


(ii) To find: the value of n


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


16 ×nP3 = 13 × n+1P3.





16n – 32 = 13n + 13


3n = 45


n = 15


Hence, value of n is 15.


(iii) To find: the value of n


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


2nP3 = 100nP2





2n(2n - 1)(2n - 2) = 100 × n(n - 1)


4n(2n - 1)(n - 1) = 100 × n(n-1)




8n(n - 13) = 0


n = 0, 13


We know that n should be greater than zero.


Hence, value of n is 13



Question 7.

(i) If If 5Pr = 2 × 6Pr–1, find r.

(ii) If 20Pr = 13 × 20Pr–1, find r.

(iii) If 11Pr = 12Pr–1, find r.


Answer:

(i) To find: the value of r


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


5Pr = 26Pr-1






r = 10, 3


Hence, value of r is 3, 10


(ii) To find: the value of r


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


20Pr = 1320Pr-1




21 – r = 13


r = 8


Hence, value of r is 8.


(iii) To find: the value of r


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


11Pr = 12Pr-1






(r - 16)(r - 9) = 0


r = 16, 9


Since r cannot be 16 as it creates a negative factorial in denominator. Therefore,
r = 16 is not possible.


Hence, value of r is 9.



Question 8.

(i) If nP4 : nP5, = 1 : 2, find n.

(ii) If n–1P3 : n+1P3, = 5 : 12, find n.


Answer:

To find: the value of n


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


nP4 : nP5 = 1:2






n – 4 = 2


n = 6


Hence, value of n is 6.


(ii) To find: the value of n


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


n–1P3 : n+1P3, = 5 : 12







12



n = 8, 2.25


Since n cannot be 2.25 as it creates a negative factorial in denominator. Therefore,
n = 2.25 is not possible.


Hence, value of n is 8.



Question 9.

If 15Pr–1 : 16Pr–2, = 3 : 4, find r.


Answer:

To find: the value of r


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


15Pr–1 : 16Pr–2, = 3 : 4











Since r cannot be 21 as it creates a negative factorial in denominator. Therefore,
is not possible.


Hence, value of r is 14



Question 10.

If 2n–1Pn : 2n+1Pn–1, = 22 : 7, find n.


Answer:

To find: the value of n


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


2n–1Pn : 2n+1Pn–1, = 22 : 7









n = 10, -0.42


Since n cannot be -0.42


Hence, value of n is 10.



Question 11.

Find n, If n+5Pn+1 = (n – 1). n+3Pn, find n.


Answer:

To find: the value of n


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


n+5Pn+1 = (n – 1). n+3Pn







(n - 7)(n - 6) = 0


n = 7, 6


Hence, values of n are 7 & 6



Question 12.

Prove that 1 + 1. 1P1 + 2. 2P2 + 3. 3P3 + …. n. nPn = n+1Pn+1.


Answer:

To Prove: 1 + 1. 1P1 + 2. 2P2 + 3. 3P3 + …. n. nPn = n+1Pn+1.


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


1 + 1. 1P1 + 2. 2P2 + 3. 3P3 + …. n. nPn = n+1Pn+1.


1 + (2! - 1!) + (3! - 2!) + (4! - 3!) + …….((n + 1)! - n!) = (n + 1)!


1 + ((n + 1)! - 1!) = (n + 1)!


(n + 1)! = (n + 1)!


Hence proved.



Question 13.

Find the number of permutations of 10 objects, taken 4 at a time.


Answer:

To find: the number of permutations of 10 objects, taken 4 at a time.


Formula Used:


Total number of ways in which n objects can be arranged in r places (Such that no object is replaced) is given by,


nPr


10P4


10P410


10P45040


Hence, the number of permutations of 10 objects, taken 4 at a time is 5040.




Exercise 8d
Question 1.

In how many ways can 5 persons occupy 3 vacant seats?


Answer:

To find: number of arrangements of 5 people in 3 seats.


Consider three seats ABC


Now, place A can be occupied by any 1 person out of 5.


Then place B can be occupied by any 1 person from remaining 4 and for C there are 3 people to occupy the seat.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of 5 different objects in 3 places is


P(5,3) =


= = = 60.


Therefore, the number of possible solutions is 60.



Question 2.

In how many ways can 7 people line up at a ticket window of a cinema hall?


Answer:

To find: number of arrangements of 7 people in a queue.


Here there are 7 spaces to be occupied by 7 people.


Therefore 7 people can occupy first place.


Similarly, 6 people can occupy second place and so on.


Lastly, there will be a single person to occupy the 7 positions.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of 7 different objects in 7 places is


P(7,7) =


= = = 5040.


Therefore, the number of possible ways is 5040



Question 3.

In how many ways can 5 children stand in a queue?


Answer:

To find: number of arrangements of 5 children in a queue.


Here, 5 places are needed to be occupied by 5 children.


Therefore any one of the 5 children can occupy first place.


Similarly, any 4 children can occupy second place and so on.


Lastly, there will be a single person to occupy the 5 position


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of 5 different objects in 5 places is


P(5,5) =


= = = 120.


Hence, this can be done in 120 ways.



Question 4.

In how many ways can 6 women draw water from 6 wells if no well remains unused?


Answer:

To find: number of arrangements of 6 women drawing water from 6 wells


Here, 6 wells are needed to be used by 6 women.


Therefore any one of the 6 women can draw water from the 1 well.


Similarly, any 5 women can draw water from the 2nd well and so on.


Lastly, there will be single women left to draw water from the 6th well.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of 6 different objects in 6 places is


P(6,6) =


= = = 720.


Hence, this can be done in 720 ways.



Question 5.

In how many ways can 4 different books, one each in chemistry, physics, biology and mathematics, be arranged on a shelf?


Answer:

To find: number of arrangements of 4 different books in a shelf.


There are 4 different books.


Any one of the four different books can be placed on the shelf first.


Similarly, in the next position, 1 book out of 3 can be placed.


Finally, the last book will have a single place to fit.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of 4 different objects in 4 places is


P(4,4) =


= = = 24.


Hence they can be arranged in 24 ways.



Question 6.

Six students are contesting the election for the presidentship of the students, union. In how many ways can their names be listed on the ballot papers?


Answer:

To find: number of arrangements of names on a ballot paper.


There are six contestants contesting in the elections.


Name of any 1 student out of six can appear first on the ballot paper.


2 position on the ballot paper can be filled by rest of the five names and so on.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of 6 different objects in 6 places is


P(6,6) =


= = = 720.


Hence, their name can be arranged in 720 ways.



Question 7.

It is required to seat 5 men and 3 women in a row so that the women occupy the even places. How many such arrangements are possible?


Answer:

To find: number of arrangements in which women sit in even places


Condition: women occupy even places


Here the total number of people is 8.



In this question first, the arrangement of women is required.


The positions where women can be made to sit is 2nd, 4th, 6th, 8th. There are 4 even places in which 3 women are to be arranged.


Women can be placed in P (4,3) ways. The rest 5 men can be arranged in 5! ways.


Therefore, the total number of arrangements is P (4,3) ×5!


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 4 different objects in 3 places and the arrangement of 5 men are


P (4,3) ×5! =


=


= 2880.


Hence number of ways in which they can be seated is 2880.



Question 8.

There are 6 items in column A and 6 items in column B. A student is asked to match each item in column A with an item in column B. How many possible, correct or incorrect answers are there to this question?


Answer:

To find: number of possibilities of a selection of answers.


Each item in column A can select another item in column B.


Therefore the question involves selecting each item from column A to each item in column B. this can be done in P(6,6)


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 6 different objects in 6 places is


P(6,6) =


= = = 720.


Therefore, the possible number of selecting an incorrect or correct answer is 720.



Question 9.

Five letters F, K, R, R and V one in each were purchased from a plastic warehouse. How many ordered pairs of letters, to be used as initials, can be formed from them?


Answer:

(i) the number of initials is 1


In this case, all letters have one chance (i.e. letters F, K, R, V ).


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 4 different objects in 1 place is


P(4,1) =


= = = 4.


So no of ways is 4 .


(ii) the number of initials is 2


There are two cases here


(a) When two R do not occur in initials


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 4 different objects in 2 places is


P(4,2) =


= = = 12.


A number of arrangements here are 12.


(b) When two R occurs in initials


When two R are chosen then 1 pair is included twice.


Selection of 0 letters remaining from 3 letters can be done in P(3,0) ways.


Formula:


A number of permutations of n objects in which p objects are alike of one kind are =n!/p!


Selections = P(3,0) ×


= × = 1


Therefore, the total number of pairs 13.


(iii) the number of initial is 3


(a) two R do not occur in initials


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 4 different objects in 3 places is


P(4,3) =


= = = 24.


A number of arrangements here are 24.


(b) two R occurs in initials


When two R are chosen then 1 pair is included twice.


Selection of 1 letter from the remaining 3 letters is P(3,1)


Formula:


A number of permutations of n objects in which p objects are alike of one kind = n!/p!


Selections = P(3,1) ×


= × = 9


total number of arrangements for 3 initials are 33


(iv) The number of initials is 4


(a) Two R do not occur in initials


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 4 different objects in 4 places is


P(4,4) =


= = = 24.


A number of arrangements here are 24.


(b) Two R occurs in the initials


When two R are chosen then 1 pair is included twice.


Selection of 2 letters from the remaining 3 letters is P(3,2)


Formula:


A number of permutations of n objects in which p objects are alike of one kind = n!/p!


Selections = P(3,2) ×


= × = 36


total number of arrangements for 4 initials are 60


(v) The number of initials is 5


Formula:


A number of permutations of n objects in which p objects are alike of one kind = n!/p!


Selections = = 60.


Total number of arrangements are 4 + 13 + 33 + 60 + 60 = 170



Question 10.

Ten students are participating in a race. In how many ways can the first three prizes be won?


Answer:

To find: number of ways of winning the first three prizes.


The first price can go to any of the 10 students.


The second price can go to any of the remaining 9 students.


The third price can go to any of the remaining 8 students.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 10 different objects in 3 places is


P(10,3) =


= = = 720.


Therefore, there are 10 × 9 × 8 = 720 ways to win first three prizes.



Question 11.

If there are 6 periods on each working day of a school, in how many ways can one arrange 5 subjects such that each subject is allowed at least one period?


Answer:

To find: number of ways of arranging 5 subjects in 6 periods.


Condition: at least 1 period for each subject.


5 subjects in 6 periods can be arranged in P (6,5).


Remaining 1 period can be arranged in P (5,1)


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Total arrangements = P(6,5) × P(5,1) = ×


= × = 720 × 5 = 3600.


Total number of ways is 3600 ways.



Question 12.

In how many ways can 6 pictures be hung from 4 picture nails on a wall?


Answer:

To find: number of ways of hanging 6 pictures on 4 picture nails.


There are 6 pictures to be placed in 4 places.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 6 different objects in 4 places is


P(6,4) = = = = 360


This can be done by 360 ways.



Question 13.

Find the number of words formed (may be meaningless) by using all the letters of the word ‘EQUATION’, using each letter exactly once.


Answer:

There are 8 alphabets in the word EQUATION.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 8 different objects in 8 places is


P(8,8) = = = = 40320


Hence there are 40320 words formed.



Question 14.

Find the number of different 4-letter words (may be meaningless) that can be formed from the letters of the word ‘NUMBERS’,


Answer:

To find: 4 lettered word from letters of word NUMBERS


There are 7 alphabets in word NUMBERS.


The word is a 4 different letter word.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 7 different objects in 4 places is


P(7,4) = = = = 840.


Hence, they can be arranged in 840 words.



Question 15.

How many words can be formed from the letters of the word ‘SUNDAY’? How many of these begin with D?


Answer:

There are 6 letters in the word SUNDAY.


Different words formed using 6 letters of the word SUNDAY is P(6,6)


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 6 different objects in 6 places is


P(6,6) = = = = 720.


720 words can be formed using letters of the word SUNDAY.


When a word begins with D.


Its position is fixed, i.e. the first position.


Now rest 5 letters are to be arranged in 5 places.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 5 different objects in 5 places is


P(5,5) = = = = 120.


Therefore, the total number of words starting with D are 120.



Question 16.

How many words beginning with C and ending with Y can be formed by using the letters of the word ‘COURTESY’?


Answer:

To find: number of words starting with C and end with Y


There are 8 letters in word COURTESY.


Here the position of the letters C and Y are fixed which is 1st and 8th.



Rest 6 letters are to be arranged in 6 places which can be done in P(6,6).


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 6 different objects in 6 places is


P(6,6) = = = = 720.


Therefore, total number of words starting with C and ending with Y is 720.



Question 17.

Find the number of permutations of the letters of the word ‘ENGLISH’. How many of these begin with E and end with I?


Answer:

There are 7 letters in the word ENGLISH.


Permutation of 7 letters in 7 places can be done in P(7,7) ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 7 different objects in 7 places is


P(7,7) = = = = 5040.


Hence, the total number of permutations is P 5040.


To find a number of words starting with E and ending with I, let us consider their position which is 1st and 7th.



The rest 5 letters are to be arranged in 5 places which can be done in P (5,5)


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 5 different objects in 5 places is


P(5,5) = = = = 120.


Therefore, there are 120 words starting with E and ending with I.



Question 18.

In how many ways can the letters of the word ‘HEXAGON’ be permuted? In how many words will the vowels be together?


Answer:

There are 7 letters in the word HEXAGON.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 7 different objects in 7 places is


P(7,7) = = = = 5040.


They can be permuted in P (7,7) = 5040 ways.


The vowels in the word are E, A, O.


Consider this as a single group.


Now considering vowels as a single group, there are total 5 groups (4 letters and 1 vowel group) can be permuted in P (5,5)


Now vowel can be arranged in 3! ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, the arrangement of 5 groups and vowel group is


P(5,5)×3! = = × 3! = × 6 = 720.


Hence total number of arrangements possible is 720.



Question 19.

How many words can be formed out of the letters of the word ‘ORIENTAL’ so that the vowels always occupy the odd places?


Answer:

To find: number of words formed


Condition: vowels occupy odd places


There are 8 letters in the word ORIENTAL and vowels are 4 which are O, I, E,A respectively.



There is 4 odd places in which 4 vowels are to be arranged.


The rest 4 letters can be arranged in 4! Ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, the total arrangement is


P(4,4) × 4! = × 4! = ×4! = × 24 = 576.


Therefore, total number of words formed are 576.



Question 20.

In how many ways can the letters of the word ‘FAILURE’ be arranged so that the consonants may occupy only odd positions?


Answer:

To find: number of words


Condition: consonants occupy odd places


There are total of 7 letters in the word FAILURE.


There are 3 consonants, i.e. F, L, R which are to be arranged in 4 places.


The rest 5 letters can be arranged in 4! Ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, the total nuber of words are


P(4,3) ×4! = ×4! = ×4! = ×24 = 576.


Hence total number of arrangements is 576.



Question 21.

In how many arrangements of the word ‘GOLDEN’ will the vowels never occur together?


Answer:

To find: number of words


Condition: vowels should never occur together.


There are 6 letters in the word GOLDEN in which there are 2 vowels.


Total number of words in which vowels never come together =


Total number of words – total number of words in which the vowels come together.


A total number of words is 6! = 720 words.


Consider the vowels as a group.


Hence there are 5 groups that can be arranged in P(5,5) ways, and vowels can be arranged in P(2,2,) ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Total arrangements = P(5,5) × P(2,2) = ×


= × = 120 × 2 = 240.


Hence a total number of words having vowels together is 240.


Therefore, the number of words in which vowels don’t come together is 720 – 240 = 480 words.



Question 22.

Find the number of ways in which the letters of the word ‘MACHINE’ can be arranged such that the vowels may occupy only odd positions.


Answer:

To find: number of words


Condition: vowels occupy odd positions.


There are 7 letters in the word MACHINE out of which there are 3 vowels namely A C E.


There are 4 odd places in which 3 vowels are to be arranged which can be done P(4,3).


The rest letters can be arranged in 4! ways


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, the total number of words is


P(4,3)4!× = ×4!


= ×4! = ×24= 576.


Hence the total number of word in which vowel occupy odd positions only is 576.



Question 23.

How many permutations can be formed by the letters of the word ‘VOWELS’, when

(i) there is no restriction on letters;

(ii) each word begins with E;

(iii) each word begins with O and ends with L;

(iv) all vowels come together;

(v) all consonants come together?


Answer:

(i) There is no restriction on letters


The word VOWELS contain 6 letters.


The permutation of letters of the word will be 6! = 720 words.


(ii) Each word begins with


Here the position of letter E is fixed.


Hence, the rest 5 letters can be arranged in 5! = 120 ways.


(iii) Each word begins with O and ends with L


The position of O and L are fixed.


Hence the rest 4 letters can be arranged in 4! = 24 ways.


(iv) All vowels come together


There are 2 vowels which are O ,E.


Consider this group.


Therefore, the permutation of 5 groups is 5! = 120


The group of vowels can also be arranged in 2! = 2 ways.


Hence the total number of words in which vowels come together are 120×2 = 240 words.


(v) All consonants come together


There are 4 consonants V,W,L,S. consider this a group.


Therefore, a permutation of 3 groups is 3! = 6 ways.


The group of consonants also can be arranged in 4! = 24 ways.


Hence, the total number of words in which consonants come together is 6×24 = 144 words.



Question 24.

How many numbers divisible by 5 and lying between 3000 and 4000 can be formed by using the digits 3, 4, 5, 6, 7, 8 when no digit is repeated in any such number?


Answer:

For a number to be divisible by 5, the last digit should either be 5 or 0.


In this case, 5 is only possible.


For a four digit number to be between 3000 to 4000, in this case, should start with 3.


Therefore, the other 2 digits can be arranged by 4 numbers in P(4,2)


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of 4 different objects in 2 places is


P(4,2) =


= = = 12.


Therefore, there are 12 numbers present between 3000 to 4000 formed by using numbers 3,1,5,6,7,8.



Question 25.

In an examination, there are 8 candidates out of which 3 candidates have to appear in mathematics and the rest in different subjects. In how many ways can they are seated in a row if candidates appearing in mathematics are not to sit together?


Answer:

Candidates in mathematics are not sitting together = total ways – the


Students are appearing for mathematic sit together.


The total number of arrangements of 8 students is 8! = 40320


When students giving mathematics exam sit together, then consider


them as a group.


Therefore, 6 groups can be arranged in P(6,6) ways.


The group of 3 can also be arranged in 3! Ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, total arrangments are


P(6,6) × 3! = ×3!


= ×3! = ×6 = 4320.


The total number of possibilities when all the students giving


mathematics exam sits together is 4320 ways.


Therefore, number of ways in which candidates appearing


mathematics exam is 40320 – 4320 = 36000.



Question 26.

In how many ways can 5 children be arranged in a line such that

(i) two of them, Rajan and Tanvy, are always together?

(ii) two of them, Rajan and Tanvy, are never together,


Answer:

(i) two of them, Rajan and Tanvy, are always together


Consider Rajan and Tanvy as a group which can be arranged in 2! = 2 ways.


The 3 children with this 1 group can be arranged in 4! = 24 ways.


The total number of possibilities in which they both come together is 2×24 = 48 ways.


(ii) two of them, Rajan and Tanvy, are never together


Two of them are never together = total number of possible ways of sitting – total number of ways in which they sit together.


A total number of possible way of arrangement of 5 students is 5! = 120 ways.


Therefore, the total number of arrangement when they both don’t sit together is = 120 – 48 = 72.



Question 27.

when a group photograph is taken, all the seven teachers should be in the first row, and all the twenty students should be in the second row. If the tow corners of the second row are reserved for the two tallest students, interchangeable only between them, and if the middle seat of the front row is reserved for the principal, how many arrangements are possible?


Answer:

For the first row:


There are 7 teachers in which the position of principal is fixed.


Therefore, the teachers can be arranged in p(7,7) = 5040.


For the second row:


The tallest students are at the ends and can be arranged in 2! = 2 ways.


Rest 18 students can be arranged in P(18,18) ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of 18 different objects in 18 places is


P(18,18) =


= = = 18!


Therefore, a total number of arrangements of the second row is 2 × 18!


Total arrangements = 2 × 18! × 5040 = 10080 × 18!


The total number of arrangements is 10080×18!



Question 28.

Find the number of ways in which m boys and n girls may be arranged in a row so that no two of the girls are together; it is given that m > n.


Answer:

In this question, n girls are to be seated alternatively between m boys.


There are m+1 spaces in which girls can be arranged.



The number of ways of arranging n girls is P(m+1,n) = ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, permutation of n different objects in m+1 places is


P(m+1,n) =


=


The arrangement of m boys can be done in P(m,m) ways.


Formula:


Number of permutations of n distinct objects among r different places, where repetition is not allowed, is


P(n,r) = n!/(n-r)!


Therefore, a permutation of m different objects in m places is


P(m,m) = = = m!


Therefore the total number of arrangements is .




Exercise 8e
Question 1.

Find the total number of permutations of the letters of each of the words given below:

(i) APPLE (ii) ARRANGE

(iii) COMMERCE (iv) INSTITUTE

(v) ENGINEERING

(vi) INTERMEDIATE


Answer:

To find: number of permutations of the letters of each word


Number of permutations of n distinct letters is n!


Number of permutations of n letters where r letters are of one kind, s letters of another kind, t letters of a third kind and so on =


(i) Here n = 5


P is repeated twice


So the number of permutations =


(ii) Here n = 7


A is repeated twice, and R is repeated twice


So, the number of permutations =


(iii) Here n = 8


M and E are repeated twice


So, the number of permutations =


(iv) Here n = 9


I is repeated twice, T is repeated thrice


So, the number of permutations =


(v) Here n = 11


E, N is repeated thrice, I,G are repeated twice


So the number of permutations =


(vi) Here n = 12


I and T are repeated twice, E is repeated thrice


So, the number of permutations =



Question 2.

In how many ways can the letters of the expression x2y2z4 be arranged when written without using exponents?


Answer:

To find: number of ways the letters can be arranged


The following table shows the possible arrangements



However, we see that case 1 = is the same as case 4 =


Similarly (case2,case 5), (case 3,case 6) are the same


So there are only 3 distinct cases


Hence the letters can be arranged in 3 distinct ways



Question 3.

There are 3 blue balls, 4 red balls and 5 green balls. In how many ways can they are arranged in a row?


Answer:

To find: no of ways in which the balls can be arranged in a row where some balls are of the same kind


Total number of balls = 3+4+5 = 12


3 are of 1 kind, 4 are of another kind, 5 are of the third kind


Number of ways =


They can be arranged in 27720 ways



Question 4.

A child has three plastic toys bearing the digits 3, 3, 5 respectively. How many 3 - digit numbers can he make using them?


Answer:

To find: number of 3 digit numbers he can make


If all were distinct, he could have made 3! = 6 numbers


But 2 number are the same


So the number of possibilities =


He can make 3 three - digit numbers using them



Question 5.

How many different signals can be transmitted by arranging 2 red, 3 yellow and 2 green flags on a pole, if all the seven flags are used to transmit a signal?


Answer:

To find: Number of distinct signals possible


Total number of fags = 7


2 are of 1 kind, 3 are of another kind, and 2 are of the 3rd kind


number of distinct signals =


Hence 210 different signals can be made



Question 6.

How many words can be formed by arranging the letters of the word ‘ARRANGEMENT’, so that the vowels remain together?


Answer:

To find: number of words where vowels are together


Vowels in the above word are: A,A,E,E


Consonants in the above word: R,R,N,G,M,N,T


Let us denote the all the vowels by a single letter say Z


the word now has the letters, R,R,N,G,M,N,T,Z


R and N are repeated twice


Number of permutations =


Now Z is comprised of 4 letters which can be permuted amongst themselves


A and E are repeated twice


number of permutations of Z =


Total number of permutations =


The number of words that can be formed is 60480



Question 7.

How many words can be formed by arranging the letters of the word ‘INDIA’, so that the vowels are never together?


Answer:

To find: Number of words that can be formed so that vowels are never together


Number of words such that vowels are never the together = Total number of words - Number of words where vowels are together


Total number of words =


To find a number of words where vowels are together


Let the vowels I, I, A be represented by a single letter Z


the new word is NDZ


A number of permutations = 3! = 6


Z is composed of 3 letters which can be permuted amongst themselves.


Number of permutations of Z =


Number of words where vowels are together = = 18


Number of words where vowels are not together = 60 - 18 = 42


There are 42 words where vowels are not together



Question 8.

Find the number of arrangements of the letters of the word ‘ALGEBRA’ without altering the relative positions of the vowels and the consonants.


Answer:

To find: number of arrangements without changing the relative position


The following table shows where the vowels and consonants can be placed


Consonants can be placed in the blank places



There are 3 spaces for vowels


There are 3 vowels out of which 2 are alike


Vowels can be placed in 3 ways


There are 4 consonants, and they can be placed in = 24 ways


Total number of arrangements = = 72 ways


72 arrangements can be made



Question 9.

How many words can be formed from the letters of the word ‘SERIES’, which start with S and end with S?


Answer:

To find: number of words which start and end with S



There are 4 places to fill up with 4 letters out of which 2 are of the same kind


Number of words =


12 words are possible



Question 10.

In how many ways can the letters of the word ‘PARALLEL’ be arranged so that all L’s do not come together?


Answer:

To find: number of words where L do not come together


Let the three L’s be treated as a single letter say Z


Number of words with L not the together = Total number of words - Words with L’s together


The new word is PARAEZ


Total number of words =


Words with L together =


Words with L, not together = 3360 - 720 = 2640


There are 2640 words where L do not come together



Question 11.

How many different words can be formed with the letters of the word ‘CAPTAIN’? In how many of these C and T are never together?


Answer:

To find: number of words such that C and T are never together


Number of words where C and T are never the together = Total numbers of words - Number of words where C and T are together


Total number of words =


Let C and T be denoted by a single letter Z


New word is APAINZ


This can be permuted in = 360 ways


Z can be permuted among itself in 2 ways


number of words where C and T are together = 360 × 2 = 720


number of words where C and T are never together = 2520 - 720 = 1800


There are 1800 words where C and T are never together



Question 12.

In how many ways can the letters of the word ‘ASSASSINATION’ be arranged so that all S’s are together?


Answer:

To find: number of ways letters can be arranged such that all S’s are together


Let all S’s be represented by a single letter Z


New word is AAINATIONZ


Number of arrangements =


Letters can be arranged in 151200 ways



Question 13.

(i)How many arrangements can be made by using all the letters of the word ‘MATHEMATICS’?

(ii) How many of them begin with C?

(iii) How many of them begin with T?


Answer:

(i) There are 11 letters of which 2 are of 1 kind, 2 are of another kind, 2 are of the 3rd kind


Total number of arrangements =


(ii)



There are 10 spaces to be filled by 10 letters of which 2 are of 3 different kinds


Number of arrangements = 453600


(iii)



There are 10 spaces to be filled by 10 letters of which 2 are of 2 different kinds


Number of arrangements =



Question 14.

In how many ways can the letters of the word ‘INTERMEDIATE’ be arranged so that:

(i) the vowels always occupy even places?

(ii) the relative orders of vowels and consonants do not change?


Answer:

(i)



There are 6 even places and 6 vowels out of which 2 are of 1 kind, 3 are of the 2nd kind


The vowels can be arranged in 60


There are 6 consonants out of which 2 is of one kind


Number of permutations = 360


Total number of words =


(ii)



There are 6 vowels to arrange in


There are 6 consonants which can be arranged in


Total number of ways = 21600



Question 15.

(i)Find the number of different words by using all the letters of the word, ‘INSTITUTION’.

In how many of them

(ii) are the three T’ s together

(iii) are the first two letters the two N’ s?


Answer:

(i) There are 11 letters of which 3 are of 1 kind, 2 are of the 2nd kind ,3 are of the 3rd kind


Number of arrangements = 554400


(ii) Let all the three T’s be denoted by a single letter Z


New word is INSIUIONZ


Number of permutations = 30240


(iii)



There are 9 places to be filled by 9 letters of which 3 are of 2 different kinds


Number of permutations =



Question 16.

How many five - digit numbers can be formed with the digits 5, 4, 3, 5, 3?


Answer:

To find: Number of 5 - digit numbers that can be formed


2 numbers are of 1 kind, and 2 are of another kind


Total number of permutations =


30 number can be formed



Question 17.

How many numbers can be formed with the digits 2, 3, 4, 5, 4, 3, 2 so that the odd digits occupy the odd places?


Answer:

The table shows the places where the odd digits can be placed



There are 4 places


And 3 odd digits out of which 2 are of the same kind


Choose any 3 places out of the four places in 4C3 ways = 4 ways


In each way, the 3 digits can be placed in ways = 3 ways


total number of ways in which odd digits occupy odd places = = 12


Now there are 4 remaining digits out of which 2 are same of 1 kind, and 2 are same as another kind


they can be arranged in the remaining places in = 6 ways


total number of numbers where odd digit occupies odd places = 12 × 6 = 72


There are 72 such numbers



Question 18.

How many 7 - digit numbers can be formed by using the digits 1, 2, 0, 2, 4, 2, 4?


Answer:

To find: number of 7 digit


0 can not be in the first place because that would make a 6 digit number


Total number of 7 - digit numbers = Total number of number possible - Number of numbers with 0 at the first place


Total number of numbers possible =


Number of numbers with 0 at first place =


Number of 7 - digit numbers = 420 - 60 = 360


360 seven - digit numbers are possible



Question 19.

How many 6 - digit numbers can be formed by using the digits 4, 5, 0, 3, 4, 5?


Answer:

To find: number of 6 digit


0 cannot be in the first place because that would make a 5 - digit number


Total number of 6 - digit numbers = Total number of number possible - Number of numbers with 0 at the first place


Total number of numbers possible =


Number of numbers with 0 at first place =


Number of 6 - digit numbers = 180 - 30 = 150


150 six - digit numbers are possible



Question 20.

The letters of the word ‘INDIA’ are arranged as in a dictionary. What are the 1st, 13th, 49th and 60th words?


Answer:

Alphabetical arrangement of letters: A,D,I,N


1st word: ADIIN


To find other words:


Case 1: words starting with A


Number of words =


13th word starts with D and is DAIIN


Case 2: words starting with D


Number of words =


Case 3: Words starting with I


Number of words =


(12+12+24+1)th = 49th word starts with N and is NAIID


Case 4: Words starting with N


Number of words =


(48+12)th word is the last word which starts with N


60th word = NDIIA


1st word: ADIIN


13th word: DAIIN


49th word: NAIID


60th word: NDIIA




Exercise 8f
Question 1.

A child has 6 pockets. In how many ways, he can put 5 marbles in his pocket?


Answer:

The first marble can be put into the pockets in 6 ways,

i.e. Choose 1 Pocket From 6 by 6C1=6


Similarly second, third, Fourth, fifth & Sixth marble. Thus, the number of ways in which the child can put the marbles is 65



Question 2.

In how many ways can 5 bananas be distributed among 3 boys, there being no restriction to the number of bananas each boy

may get?





Answer:

As there is 5 banana, So suppose it as B1, B2, B3, B4, B5 And Let the Boy be A1, A2, A3

So B1 can Be distributed to 3 Boys (A1, A2, A3) by 3 ways,


Similarly, B2, B3, B4, B5 Can be distributed to 3 Boys by 34


So total number of ways is 35



Question 3.

In how many ways can 3 letters can be posted in 2 letterboxes?


Answer:

Let Suppose Letterbox be B1, B2 and letters are L1, L2, L3

So L1 can be posted in any 2 letterboxes (B1, B2) by 2 ways


Similarly, L2 can be posted in any 2 letterbox(B1, B2) by 2 ways


Similarly, L3 can be posted in any 2 letterbox(B1, B2) by 2 ways


So total number of ways is 23 = 8



Question 4.

How many 3-digit numbers are there when a digit may be repeated any numbers of time?


Answer:

Let Suppose 3 digit number as 3 boxes as shown below.First Box is at 100thplace, the Second box is at 10th place, and the Third box be at 1st place.


To make a 3 digit number,


1st box can be filled with nine numbers(1, 2, 3, 4, 5, 6, 7, 8, 9) if we include 0 in 1st box then it become 2 digit number(i.e 010 is 2 digit number not 3 digit)


2nd box can be filled with ten numbers(1, 2, 3, 4, 5, 6, 7, 8, 9, 0) as repetation is allowed.


Similarly 3rd box can be filled with ten numbers(1, 2, 3, 4, 5, 6, 7, 8, 9, 0)


Total number of ways is 9 × 10 × 10 = 900



Question 5.

How many 4-digit numbers can be formed with the digits 0, 2, 3, 4, 5 when a digit may be repeated any numbers of time in any arrangement?


Answer:

Let Suppose 4 digit number as 4 boxes as shown below.First Box is at 1000thplace, the Second box is at 100th place, the Third box is at 10th place, and Fourth box is at 1st place.


The 1st box can be filled with four numbers(2, 3, 4, 5) if we include 0 in the 1st box then it becomes 3 digit number(i.e. 0234 is 3 digit number, not 4 digits)


The 2nd box can be filled with five numbers(0, 2, 3, 4, 5) as repetition is allowed.


Similarly, the 3rd box can be filled with five numbers(0, 2, 3, 4, 5) as repetition is allowed.


Similarly, the 4th box can be filled with five numbers(0, 2, 3, 4, 5) as repetition is allowed.


Total number of ways is 4 × 5 × 5 × 5 = 500



Question 6.

In how many ways can 4 prizes be given to 3 boys when a boy is eligible for all prizes?


Answer:

Let suppose 4 prizes be P1, P2, P3, P4 and 3 boys be B1, B2, B3

Now P1 can be distributed to 3 boys(B1, B2, B3) by 3 ways,


Similarly, P2 can be distributed to 3 boys(B1, B2, B3) by 3 ways,


Similarly, P3 can be distributed to 3 boys(B1, B2, B3) by 3 ways,


And P4 can be distributed to 3 boys(B1, B2, B3) by 3 ways


So total number of ways is 3 × 3 × 3 × 3 =81



Question 7.

There are 4 candidates for the post of a chairman, and one is to be elected by votes of 5 men. In how many ways can the vote be given?


Answer:

Let suppose 4 candidates be C1, C2, C3, C4 and 5 men be M1, M2, M3, M4, M5

Now M1 choose any one candidates from four (C1, C2, C3, C4) and give the vote to him by any 4 ways


Similarly, M2 choose any one candidates from four (C1, C2, C3, C4) and give the vote to him by any 4 ways


Similarly, M3 choose any one candidates from four (C1, C2, C3, C4) and give the vote to him by any 4 ways


Similarly, M4 choose any one candidates from four (C1, C2, C3, C4) and give the vote to him by any 4 ways


And M5 choose any one candidates from four (C1, C2, C3, C4) and give the vote to him by any 4 ways


So total numbers of ways are 4 × 4 × 4 × 4 × 4=1024




Exercise 8g
Question 1.

In how many ways can 6 persons be arranged in

(i) a line, (ii) a circle?


Answer:

(i) Let choose 1 person from 6 by 6C1=6 and arranged it in line


Now choose another person from remaining 5 by 5C1=5 and arranged it in line


Similarly, choose another person from remaining 4 by 4C1=4 and arranged it in line


Similarly, choose another person from remaining 3 by 3C1=3 and arranged it in line


Similarly, choose another person from remaining 2 by 2C1=2 and arranged it in line


And choose another person from remaining 1 by 1C1=1 and arranged it in line


So total number of ways is 6! =720


(ii) It is the same as above, by converting line arrangement into the circle but you need to remove some arrangement


Let suppose 6 persons as A, B, C, D ,E, F you need to arrange this 6 persons into a circle.


First, we arranged 6 persons in line(number of ways = 6!)


NOTE: A, B, C, D ,E, F and B, C, D, E, F, A consider as a different line, but when we arranged this 2 combination in circle then it becomes same,


i.e. Let takes us an example we need to arrange A, N, O, D, E.


We arrange it as shown. When we rotate first one, then 1st and 2nd became identical and so on that’s why all 5 are identical, and we count it as 1



Now come back to our questions


So total number of arrangement is (6-1)! = 5! = 120


NOTE: When you want to arrange n persons in circle then a total number of ways is n!/n,


i.e. Total number of ways = (n-1)!



Question 2.

There are 5 men and 5 ladies to dine at a round table. In how many ways can they sit so that no ladies are together?


Answer:

Let first arranged 5 men in the round table by 4! (by using the formula (n-1)! Mention above)

Now there are 5 gaps created between 5 men (check the figure)



So we arrange 5 ladies in this gap by 5!


A total number of ways to arrange 5 men and 5 ladies is 5! × 4! = 2880



Question 3.

In how many ways can 11 members of a committee sit at a round table so that the secretary and the joint secretary are always the neighbours of the president?


Answer:

First assume the president(P), Joint secretary(JS) and secretary(S) to be 1 members(as shown below)


So there are 9 members, a number of ways to arrange this 9 people is 8! (the formula used (n-1)!)


Now we need to look at the internal arrangement. There are 2 arrangement possible




So total number of arrangement are (8!) × 2 = 80,640



Question 4.

In how many ways can 8 persons be seated at a round table so that all shall not have the same neighbours in any two arrangement?


Answer:

By using the formula (n-1)! (mention in Solution-1)

So 8 persons can be arranged by 7!


Now each person have the same neighbours in the clockwise and anticlockwise arrangement


Total number of arrangement are (7!)/2 = 2520



Question 5.

In how many differents ways can 20 different pearls be arranged to form a necklace?


Answer:

We know that necklace in the form of a circle, So we need to arrange 20 pearls in Circle

20 pearls can be arranged by 19!


Now each pearl have the same neighbours in the clockwise and anticlockwise arrangement


Total number of arrangement are (19!)/2



Question 6.

In how many different ways can a garland of 16 different flowers be made?


Answer:

It is also in the form of a circle, So we need to arrange 16flowers in Circle

16 flowers can be arranged by 15!


Now each flower have the same neighbours in the clockwise and anticlockwise arrangement


Total number of arrangement are (15!)/2




Exercise 8h
Question 1.

If (n + 1)! = 12 × [(n – 1)!], find the value of n.


Answer:

To Find: Value of n


Given: (n+1)! = 12× [(n-1)!]


Formula Used: n! = (n) × (n-1) × (n-2) × (n-3) ………. 3 × 2 × 1


Now, (n+1)! = 12× [(n-1)!]


⇒ (n+1) × (n) × [(n-1)!] = 12 × [(n-1)!]


⇒ (n+1) × (n) = 12


⇒ n2+n = 12


⇒ n2+n-12 = 0


⇒ (n-3) (n+4) = 0


⇒ n = 3 or, n = -4


But, n=-4 is not possible because in case of factorial (!) n can not be negative.


Hence, n=3 is the correct answer.



Question 2.

If, find the value of x.


Answer:

To Find: Value of n


Given:


Formula Used: n! = (n) × (n-1) × (n-2) × (n-3) ………. 3 × 2 × 1


Now,


(4! = 24, 5! = 120)




⇒ x = 36



Question 3.

How many 3-digit numbers are there with no digit repeated?


Answer:

Given: We have 10 numbers i.e. 0,1,2,3,4,5,6,7,8,9


To Find: Number of 3-digit numbers formed with no repetition of digits.


Conditions: No digit is repeated


Let us represent the 3-digit number



First place can be filled with 9 numbers, i.e. 1,2,3,4,5,6,7,8,9 (0 cannot be placed as it will make it a 2-digit number) = 9 ways


Second place can be filled with remaining 9 numbers (as one number is used already) = 9 ways


Similarly, third place can be filled with 8 numbers = 8 ways


Total number of 3-digit numbers which can be formed


= 9 × 9 × 8= 648



Question 4.

How many 3-digit numbers above 600 can be formed by using the digits 2, 3, 4, 5, 6, if repetition of digits is allowed?


Answer:

Given: We have 5 digits i.e. 2,3,4,5,6


To Find: Number of 3-digit numbers


Condition: (i) Number should be greater than 600


(ii) Repetition of digits is allowed


For forming a 3 digit number, we have to fill 3 vacant spaces.


But as the number should be above 600, hence the first place must be occupied with 6 only because no other number is greater than 6.


Let us represent the 3-digit number



So the first place is filled with 6 = 1 ways


Second place can be filled with 5 numbers = 5 ways


Third place can be filled with 5 numbers = 5 ways


Total number of ways = 1 × 5 × 5 = 25


Total number of 3-digit numbers above 600 which can be formed by using the digits 2, 3, 4, 5, 6 with repetition allowed is 25



Question 5.

How many numbers divisible by 5 and lying between 4000 and 5000 can be formed from the digits 4, 5, 6, 7, 8 if repetition of digits is allowed?


Answer:

Given: We have 5 digits, i.e. 4,5,6,7,8


To Find: Number of numbers divisible by 5


Condition: (i) Number should be between 4000 and 5000


(ii) Repetition of digits is allowed


Here as the number is lying between 4000 and 5000, we can conclude that the number is of 4-digits and the number must be starting with 4.


Now, for a number to be divisible by 5 must ends with 5


Let us represent the 4-digit number



Therefore,


The first place is occupied by 4 = 1 way


The fourth (last) place is occupied by 5 = 1 way


The second place can be filled by 5 numbers = 5 ways


The third place can be filled by 5 numbers = 5 ways


Total numbers formed = 1 × 5 × 5 × 1 = 25


There are 25 numbers which are divisible by 5 and lying between 4000 and 5000 and can be formed from the digits 4, 5, 6, 7, 8 with repetition of digits.



Question 6.

In how many ways can the letters of the word ‘CHEESE’ be arranged?


Answer:

Given: We have 6 letters


To Find: Number of words formed with Letter of the word ‘CHEESE.’


The formula used: The number of permutations of n objects, where p1 objects are of one kind, p2 are of the second kind, ..., pk is of a kth kind and the rest if any, are of a different kind is


Suppose we have these words – C,H,E1,E2,S,E3


Now if someone makes two words as CHE1E3SE2 and CHE2E3SE1


These two words are different because E1, E2 and E3 are different but we have three similar E’s hence, in our case these arrangements will be a repetition of same words.


In the word CHEESE, 3 E’s are similar


∴ n = 6, p1 = 3



In 120 ways the letters of the word ‘CHEESE’ can be arranged.



Question 7.

In how many ways can the letters of the word ‘PERMUTATIONS’ be arranged if each word starts with P and ends with S?


Answer:

Given: We have 12 letters


To Find: Number of words formed with Letter of the word ‘PERMUTATIONS.’


The formula used: The number of permutations of n objects, where p1 objects are of one kind, p2 are of the second kind, ..., pk is of a kth kind and the rest if any, are of a different kind is


In the word ‘PERMUTATIONS’ we have 2 T’s.


We have to start the word with P and end it with S, hence the first and last position is occupied with P and S respectively.


As two positions are occupied the remaining 10 positions are to be filled with 10 letters in which we have 2 T’s.


NOTE:- Unless specified , assume that repetition is not allowed.


Let us represent the arrangement




Hence,


The first place is occupied by P = 1 way


The last place (12th) is occupied by S = 1 way


For the remaining 10 places:


Using the above formula


Where,


n=10


p1=2



Total number of ways are ways.


In 1814400 ways the letters of the word ‘PERMUTATIONS’ can be arranged if each word starts with P and ends with S.



Question 8.

How many different words can be formed by using all the letters of the word ‘ALLAHABAD’?


Answer:

Given: We have 9 letters


To Find: Number of words formed with Letter of the word ‘ALLAHABAD.’


The formula used: The number of permutations of n objects, where p1 objects are of one kind, p2 are of the second kind, ..., pk is of a kth kind and the rest if any, are of a different kind is


‘ALLAHABAD’ consist of 9 letters out of which we have 4 A’s and 2 L’s.


Using the above formula


Where,


n=9


p1=4


p2=2



7560 different words can be formed by using all the letters of the word ‘ALLAHABAD.’



Question 9.

How many permutations of the letters of the word ‘APPLE’ are there?


Answer:

Given: We have 5 letters


To Find: Number of words formed with Letter of the word ‘APPLE.’


The formula used: The number of permutations of n objects, where p1 objects are of one kind, p2 are of the second kind, ..., pk is of a kth kind and the rest if any, are of a different kind is


‘APPLE’ consists of 5 letters out of which we have 2 Ps.


Using the above formula


Where,


n=5


p1=2



There are 60 permutations of the letters of the word ‘APPLE’.



Question 10.

How many words can be formed by the letters of the word ‘SUNDAY’?


Answer:

Given: We have 6 letters


To Find: Number of words formed with Letter of the word ‘SUNDAY.’


‘SUNDAY’ consist of 6 letters.


NOTE: - Unless specified, assume that repetition is not allowed.


Let us represent the arrangement with an example



6 ways5 ways4 ways3 ways2 ways1 way


We have 6 places


First place can be filled with 6 letters, i.e. S,U,N,D,A,Y = 6 ways


Second place can be filled with 5 letters (as one letter is already used in the first place) = 5 ways


Similarly,


Third place can be filled with 4 letters = 4 ways


The fourth place can be filled with 3 letters = 3 ways


The fifth place can be filled with 2 letters = 2 ways


The sixth place can be filled with 1 letters = 1 ways


Total number of letters = 6 × 5 × 4 × 3 × 2 × 1 = 720


720 words can be formed by the letters of the word ‘SUNDAY.’



Question 11.

In how many ways can 4 letters be posted in 5 letter boxes?


Answer:

Given: We have 4 letters and 5 letter boxes


To Find: Number of ways of posting letters.


One letter can be posted in any of 5 letter boxes.


We have to assume that all the letters are different.


So for first letter i.e. , we have 5 ways


Similarly for,





Total number of ways = 5 × 5 × 5 × 5 = 625


In 625 ways 4 letters can be posted in 5 letter boxes.



Question 12.

In how many ways can 4 women draw water from 4 taps if no tap remains unused?


Answer:

Given: We have 4 women and 4 taps


To Find: Number of ways of drawing water


Condition: No tap remains unused


Let us represent the arrangement



The first woman can use any of the four taps


The second woman can use the remaining three taps = 3 ways


The third woman can use the remaining two taps = 2 ways


The fourth woman can use the remaining one tap = 1 way


Total number of ways = 4 × 3 × 2 × 1 = 24


There is 24 number of ways in which 4 women can draw water from 4 taps such that no tap remains unused.



Question 13.

How many 5-digit numbers can be formed by using the digits 0, 1 and 2?


Answer:

Given: We have 3 digits, i.e. 0, 1 and 2


To Find: Number of 5-digit numbers formed


Let us represent the arrangement



For forming a 5-digit number, we have to fill 5 vacant spaces.


But the first place cannot be filled with 0, hence for filling first place, we have only 1 and 2


First place can be filled with 2 numbers, i.e. 1, 2 = 2 ways


Second place can be filled with 3 numbers = 3 ways


Third place can be filled with 3 numbers = 3 ways


The fourth place can be filled with 3 numbers = 3 ways


The fifth place can be filled with 3 numbers = 3 ways


Total number of ways = 2 × 3 × 3 × 3 × 3 = 162


162 5-digit numbers can be formed by using the digits 0, 1 and 2.



Question 14.

In how many ways can 5 boys and 3 girls be seated in a row so that each girl is between 2 boys?


Answer:

Given: We have 5 boys and 3 girls


To Find: Number of ways of seating so that 5 boys and 3 girls are seated in a row and each girl is between 2 boys


The formula used: The number of permutations of n different objects taken r at a time (object does not repeat) is


The only arrangement possible is


B__B__B__B__B


Number of ways for boys





=120


There are 3 girls, and they have 4 vacant positions


Number of ways for girls




=24


Total number of ways = 24 × 120 = 2880


In 2880 ways 5 boys and 3 girls can be seated in a row so that each girl is between 2 boys.



Question 15.

A child has plastic toys bearing the digits 4, 4 and 5. How many 3-digit numbers can he make using them?


Answer:

Given: We have toys with bearing 4, 4 and 5


To Find: Number of 3-digit numbers he can make


The formula used: The number of permutations of n objects, where p1 objects are of one kind, p2 are of the second kind, ..., pk is of a kth kind and the rest, if any, are of a different kind is


The child has to form a 3-digit number.


Here the child has two 4’s.


We have to use the above formula


Where,


n=3


p1=2



The numbers are 544, 454 and 445.


He can make 3 3-digit numbers.



Question 16.

In how many ways can the letters of the word ‘PENCIL’ be arranged so that N is always next to E?


Answer:

Given: We have 6 letters


To Find: Number of ways to arrange letters P,E,N,C,I,L


Condition: N is always next to E


Here we need EN together in all arrangements.


So, we will consider EN as a single letter.


Now, we have 5 letters, i.e. P,C,I,L and ‘EN’.


5 letters can be arranged in





⇒ 120


In 120 ways we can arrange the letters of the word ‘PENCIL’ so that N is always next to E