Class 10 - Maths - Probability

Exercise 15.1

Question 1:

Complete the following statements:

(i) Probability of an event E + Probability of the event ‘not E’ = _______.

(ii) The probability of an event that cannot happen is _________. Such as event is called _________.

(iii) The probability of an event that is certain to happen is _________. Such as event is called ________.

(iv) The sum of the probabilities of all the elementary events of an experiment is _________.

(v) The probability of an event is greater than or equal to _______ and less than or equal to _______.

(i) Probability of an event E + Probability of the event ‘not E’ = 1.

(ii) The probability of an event that cannot happen is 0. Such as event is called impossible

event.

(iii) The probability of an event that is certain to happen is 1. Such as event is called sure event

or certain event.

(iv) The sum of the probabilities of all the elementary events of an experiment is 1.

(v) The probability of an event is greater than or equal to 0 and less than or equal to 1.

Question 2:

Which of the following experiments have equally likely outcomes? Explain.

(i) A driver attempts to start a car. The car starts or does not start.

(ii) A player attempts to shoot a basketball. She/he shoots or misses the shot.

(iv) A baby is born. It is a boy or a girl.

(i) It is not an equally likely event, as it depends on various factors such as whether the car will

start or not. And factors for both the conditions are not the same.

(ii) It is not an equally likely event, as it depends on the player’s ability and there is no

(iii) It is an equally likely event.

(iv) It is an equally likely event.

Question 3:

Why is tossing a coin considered to be a fair way of deciding which team should get the ball at the beginning of a football game?

When we toss a coin, the possible outcomes are only two, head or tail, which are equally likely

outcomes. Therefore, the result of an individual toss is completely unpredictable.

Question 4:

Which of the following cannot be the probability of an event?

(a) 2/3                                   (b) -1.5                          (c) 15%                             (d) 0.7

Probability of an event (E) is always greater than or equal to 0. Also, it is always less than or

equal to one. This implies that the probability of an event cannot be negative or greater than

1. Therefore, out of these alternatives, −1.5 cannot be a probability of an event.

Hence, option (B) is the correct answer.

Question 5:

If P(E) = 0.05, what is the probability of ‘not E’?

We know that,

P(E) = 1 – P(E)

= 1 – 0.05

= 0.95

Therefore, the probability of ‘not E’ is 0.95.

Question 6:

A bag contains lemon flavored candies only. Malini takes out one candy without looking into the bag.

What is the probability that she takes out

(i) an orange flavored candy?                               (ii) a lemon flavored candy?

(i) The bag contains lemon flavored candies only. It does not contain any orange flavored

candies. This implies that every time, she will take out only lemon flavored candies. Therefore,

event that Malini will take out an orange flavored candy is an impossible event.

Hence, P(an orange flavored candy) = 0

(ii) As the bag has lemon flavored candies, Malini will take out only lemon flavored candies.

Therefore, event that Malini will take out a lemon flavored candy is a sure event.

Hence, P(a lemon flavored candy) = 1

Question 7:

It is given that in a group of 3 students, the probability of 2 students not having the same birthday is 0.992.

What is the probability that the 2 students have the same birthday?

Probability that two students are not having same birthday P(E) = 0.992

Probability that two students are having same birthday P (E) = 1 − P(E)

= 1 − 0.992

= 0.008

Question 8:

A bag contains 3 red balls and 5 black balls. A ball is drawn at random from the bag.

What is the probability that the ball drawn is (i) red?              (ii) not red?

(i) Total number of balls in the bag = 8

Probability of getting red ball = Number of favorable outcomes/Total possible outcomes

= 3/8

(ii) Probability of not getting red ball = 1 − Probability of getting a red ball

= 1 – 3/8

= 5/8

Question 9:

A box contains 5 red marbles, 8 white marbles and 4 green marbles. One marble is taken out of the box at random.

What is the probability that the marble taken out will be                           (i) red?

(ii) white?                                        (iii) not green?

Total number of marbles = 5 + 8 + 4 = 17

(i) Number of red marbles = 5

Probability of getting a red marble = Number of favorable outcomes/Total possible outcomes

= 5/17

(ii) Number of white marbles = 8

Probability of getting a white marble = Number of favorable outcomes/Total possible

outcomes

= 8/17

(iii) Number of green marbles = 4

Probability of getting a green marble = Number of favorable outcomes/Total possible

outcomes

= 4/17

Probability of not getting a green marble = 1 – 4/17 = 13/17

Question 10:

A piggy bank contains hundred 50 p coins, fifty Rs 1 coins, twenty Rs 2 coins and ten Rs 5 coins.

If it is equally likely that one of the coins will fall out when the bank is turned upside down, what is the probability that the coin:

(i) Will be a 50 p coin?                                  (ii) Will not be a Rs.5 coin?

Total number of coins in a piggy bank = 100 + 50 + 20 + 10 = 180

(i) Number of 50 p coins = 100

Probability of getting a 50 p coin = Number of favorable outcomes/Total possible outcomes

= 100/180

= 5/9

(i) Number of Rs 5 coins = 10

Probability of getting a Rs 5 coin = Number of favorable outcomes/Total possible outcomes

= 10/180

= 1/18

Probability of not getting a Rs 5 coin = 1 - Probability of getting a Rs 5 coin

= 1 – 1/18

= 17/18

Question 11:

Gopi buys a fish from a shop for his aquarium. The shopkeeper

takes out one fish at random from a tank containing 5 male fish  and 8 female fish (see Fig. 15.4).

What is the probability that the fish taken out is a male fish?

Total number of fishes in a tank = Number of male fishes + Number of female fishes

= 5 + 8

= 13

Probability of getting a male fish = Number of favorable outcomes/Total possible outcomes

= 5/13

Question 12:

A game of chance consists of spinning an arrow which comes to rest pointing at one of the numbers

1, 2, 3, 4, 5, 6, 7, 8 (see Fig. 15.5 ), and these are equally likely outcomes. What is the probability that it will

point at

(i) 8?         (ii) an odd number?        (iii) a number greater than 2?      (iv) a number less than 9?

Total number of possible outcomes = 8

(i) Probability of getting 8 = Number of favorable outcomes/Total possible outcomes

= 1/8

(ii) Total number of odd numbers on spinner = 4

Probability of getting an odd number = Number of favorable outcomes/Total possible outcomes

= 4/8 = 1/2

(iii) The numbers greater than 2 are 3, 4, 5, 6, 7, and 8.

Therefore, total numbers greater than 2 = 6

Probability of getting a number greater than 2

= Number of favorable outcomes/Total possible outcomes

= 6/8

= 3/4

(iv) The numbers less than 9 are 1, 2, 3, 4, 6, 7, and 8.

Therefore, total numbers less than 9 = 8

Probability of getting a number less than 9 = 8/8 = 1

Question 13:

A die is thrown once. Find the probability of getting

(i) a prime number;          (ii) a number lying between 2 and 6;            (iii) an odd number.

The possible outcomes when a dice is thrown = {1, 2, 3, 4, 5, 6}

Number of possible outcomes of a dice = 6

(i) Prime numbers on a dice are 2, 3, and 5.

Total prime numbers on a dice = 3

Probability of getting a prime number = 3/6 = 1/2

(ii) Numbers lying between 2 and 6 = 3, 4, 5

Total numbers lying between 2 and 6 = 3

Probability of getting a number lying between 2 and 6 = 3/6 = 1/2

(iii) Odd numbers on a dice = 1, 3, and 5

Total odd numbers on a dice = 3

Probability of getting an odd number = 3/6 = 1/2

Question 14:

One card is drawn from a well-shuffled deck of 52 cards. Find the probability of getting

(i) a king of red colour                     (ii) a face card                             (iii) a red face card

(iv) the jack of hearts                      (v) a spade                                    (vi) the queen of diamonds

Total number of cards in a well-shuffled deck = 52

(i) Total number of kings of red colour = 2

P(getting a king of red colour) = Number of favorable outcomes/Total possible outcomes

= 2/52

= 1/26

(ii) Total number of face cards = 12

P(getting a face card) = Number of favorable outcomes/Total possible outcomes

= 12/52

= 3/13

(iii) Total number of red face cards = 6

P(getting a red face card) = Number of favorable outcomes/Total possible outcomes

= 6/52

= 3/26

(iv) Total number of Jack of hearts = 1

P(getting a Jack of hearts) = Number of favorable outcomes/Total possible outcomes

= 1/52

(v) Total number of spade cards = 13

P(getting a spade card) = Number of favorable outcomes/Total possible outcomes

= 13/52

= 1/4

(vi) Total number of queen of diamonds = 1

P(getting a queen of diamond) = Number of favorable outcomes/Total possible outcomes

= 1/52

Question 15:

Five cards−−the ten, jack, queen, king and ace of diamonds, are well-shuffled with their face downwards. One card is then picked up at random.

(i) What is the probability that the card is the queen?

(ii) If the queen is drawn and put aside, what is the probability that the second card picked up is

(a) an ace?                (b) a queen?

(i) Total number of cards = 5

Total number of queens = 1

P (getting a queen) = Number of favorable outcomes/Total possible outcomes

= 1/5

(ii) When the queen is drawn and put aside, the total number of remaining cards will be 4.

(a) Total number of aces = 1

P (getting an ace) = Number of favorable outcomes/Total possible outcomes

= 1/4

(b) As queen is already drawn, therefore, the number of queens will be 0.

P (getting a queen) = Number of favorable outcomes/Total possible outcomes

= 0/4 = 0

Question 16:

12 defective pens are accidentally mixed with 132 good ones. It is not possible to just look at a pen and tell whether or not it is defective.

One pen is taken out at random from this lot. Determine the probability that the pen taken out is a good one.

Total number of pens = 12 + 132 = 144

Total number of good pens = 132

P (getting a good pen) = Number of favorable outcomes/Total possible outcomes

= 132/144

= 11/12

Question 17:

(i) A lot of 20 bulbs contain 4 defective ones. One bulb is drawn at random from the lot.

What is the probability that this bulb is defective?

(ii) Suppose the bulb drawn in (i) is not defective and is not replaced. Now one bulb is drawn at random from the rest.

What is the probability that this bulb is not defective?

(i) Total number of bulbs = 20

Total number of defective bulbs = 4

P (getting a defective bulb) = Number of favorable outcomes/Total possible outcomes

= 4/20

= 1/5

(ii) Remaining total number of bulbs = 19

Remaining total number of non-defective bulbs = 16 − 1 = 15

P (getting a not defective bulb) = Number of favorable outcomes/Total possible outcomes

= 15/19

Question 18:

A box contains 90 discs which are numbered from 1 to 90. If one disc is drawn at random from the box, find the probability that it bears

(i) a two-digit number

(ii) a perfect square number

(iii) a number divisible by 5.

Total number of discs = 90

(i) Total number of two-digit numbers between 1 and 90 = 81

P (getting a two-digit number) = Number of favorable outcomes/Total possible outcomes

= 81/90

= 9/10

(ii) Perfect squares between 1 and 90 are 1, 4, 9, 16, 25, 36, 49, 64, and 81.

Therefore, total number of perfect squares between 1 and 90 is 9.

P (getting a perfect square) = Number of favorable outcomes/Total possible outcomes

= 9/90

= 1/10

(iii) Numbers that are between 1 and 90 and divisible by 5 are 5, 10, 15, 20, 25, 30, 35, 40, 45,

50, 55, 60, 65, 70, 75, 80, 85, and 90.

Therefore, total numbers divisible by 5 = 18

Probability of getting a number divisible by 5 = 18/90 = 1/5

Question 19:

A child has a die whose six faces shows the letters as given below:

The die is thrown once. What is the probability of getting             (i) A?            (ii) D?

Total number of possible outcomes on the dice = 6

(i) Total number of faces having A on it = 2

P (getting A) = 2/6 = 1/3

(ii) Total number of faces having D on it = 1

P (getting D) = 1/6

Question 20:

Suppose you drop a die at random on the rectangular region shown in the in Fig. 15.6.

What is the probability that it will land inside the circle with diameter 1 m?

Area of rectangle = l * b = 3 * 2 = 6 m2

Area of circle (of diameter 1 m) = πr2 = π(1/2)2

= π/4

P (die will land inside the circle) = (π/4)/6 = π/24

Question 21:

A lot consists of 144 ball pens of which 20 are defective and the others are good.

Nuri will buy a pen if it is good, but will not buy if it is defective.

The shopkeeper draws one pen at random and gives it to her. What is the probability that

Total number of pens = 144

Total number of defective pens = 20

Total number of good pens = 144 − 20 = 124

(i) Probability of getting a good pen = 124/144 = 31/36

P(Nuri buys a pen) = 31/36

(ii) P(Nuri will not buy a pen) = 1 – 31/36 = 5/36

Question 22:

Refer to Example 13. (i) Complete the following table:

(ii) A student argues that ‘there are 11 possible outcomes 2, 3, 4, 5, 6, 7, 8, 9, 10, 11 and 12.

Therefore, each of them has a probability 1/11. Do you agree with this argument?

(i) It can be observed that,

To get the sum as 2, possible outcomes = (1, 1)

To get the sum as 3, possible outcomes = (2, 1) and (1, 2)

To get the sum as 4, possible outcomes = (3, 1), (1, 3), (2, 2)

To get the sum as 5, possible outcomes = (4, 1), (1, 4), (2, 3), (3, 2)

To get the sum as 6, possible outcomes = (5, 1), (1, 5), (2, 4), (4, 2), (3, 3)

To get the sum as 7, possible outcomes = (6, 1), (1, 6), (2, 5), (5, 2), (3, 4), (4, 3)

To get the sum as 8, possible outcomes = (6, 2), (2, 6), (3, 5), (5, 3), (4, 4)

To get the sum as 9, possible outcomes = (3, 6), (6, 3), (4, 5), (5, 4)

To get the sum as 10, possible outcomes = (4, 6), (6, 4), (5, 5)

To get the sum as 11, possible outcomes = (5, 6), (6, 5)

To get the sum as 12, possible outcomes = (6, 6)

(ii) Probability of each of these sums will not be as these sums are not equally likely.

Question 23:

A game consists of tossing a one rupee coin 3 times and noting its outcome each time.

Hanif wins if all the tosses give the same result i.e., three heads or three tails, and loses otherwise.

Calculate the probability that Hanif will lose the game.

The possible outcomes are

{HHH, TTT, HHT, HTH, THH, TTH, THT, HTT}

Number of total possible outcomes = 8

Number of favorable outcomes = 2 {i.e., TTT and HHH}

P(Hanif will win the game) = 2/8 = 1/4

P(Hanif will lose the game) = 1 – 1/4 = 3/4

Question 24:

A die is thrown twice. What is the probability that

(i) 5 will not come up either time?                   (ii) 5 will come up at least once?

[Hint: Throwing a die twice and throwing two dice simultaneously are treated as the same experiment].

Total number of outcomes = 6 × 6 = 36

(i) Total number of outcomes when 5 come up on either time are (5, 1), (5, 2), (5, 3), (5, 4),

(5, 5), (5, 6), (1, 5), (2, 5), (3, 5), (4, 5), (6, 5)

Hence, total number of favorable cases = 11

P (5 will come up either time) = 11/36

P (5 will not come up either time) = 1 – 11/36 = 25/36

(ii) Total number of cases, when 5 can come at least once = 11

P (5 will come at least once) = 11/36

Question 25:

Which of the following arguments are correct and which are not correct? Give reasons for your answer.

(i) If two coins are tossed simultaneously there are three possible outcomes−−two heads, two tails or one of each.

Therefore, for each of these outcomes, the probability is 1/3.

(ii) If a die is thrown, there are two possible outcomes−−an odd number or an even number.

Therefore, the probability of getting an odd number is 1/2.

(i) Incorrect

When two coins are tossed, the possible outcomes are (H, H), (H, T), (T, H), and (T, T). It can be

observed that there can be one of each in two possible ways − (H, T), (T, H).

Therefore, the probability of getting two heads is 1/4, the probability of getting two tails is

1/4, and the probability of getting one of each is 1/2. It can be observed that for each

outcome, the probability is not 1/3.

(ii) Correct

When a dice is thrown, the possible outcomes are 1, 2, 3, 4, 5, and 6. Out of these, 1, 3, 5 are

odd and 2, 4, 6 are even numbers.

Therefore, the probability of getting an odd number is 1/2.

Exercise 15.2 (Optional)*

Question 1:

Two customers Shyam and Ekta are visiting a particular shop in the same week (Tuesday to Saturday).

Each is equally likely to visit the shop on any day as on another day. What is the probability that both will visit the shop on

(i) the same day?                             (ii) consecutive days?                       (iii) different days?

There are a total of 5 days.

Shyam can go to the shop in 5 ways and Ekta can go to the shop in 5 ways.

Therefore, total number of outcomes = 5 * 5 = 25

(i) They can reach on the same day in 5 ways.

i.e., (t, t), (w, w), (th, th), (f, f), (s, s)

P (both will reach on same day)

(ii) They can reach on consecutive days in these 8 ways

i.e (t, w), (w, th), (th, f), (f, s), (w, t), (th, w), (f, th), (s, f).

Therefore, P (both will reach on consecutive days) = 5/25 = 1/5

(iii) P (both will reach on same day) = 1/5          [(From part (i)]

P (both will reach on different days) = 1 – 1/5 = 4/5

Question 2:

A die is numbered in such a way that its faces show the number 1, 2, 2, 3, 3, 6. It is thrown two times and the total score in two throws is noted.

Complete the following table which gives a few values of the total score on the two throws:

What is the probability that the total score is:     (i) even?             (ii) 6?            (iii) at least 6?

Total number of possible outcomes when two dice are thrown = 6 * 6 = 36

(i) Total times when the sum is even = 18

P(getting an even number) = 18/36 = 1/2

(ii) Total times when the sum is 6 = 4

P(getting sum as 6) = 4/26 = 1/9

(iii) Total times when the sum is at least 6 (i.e., greater than 5) = 15

P(getting sum at least 6) = 15/36 = 5/12

Question 3:

A bag contains 5 red balls and some blue balls. If the probability of drawing a blue ball is double that of a red ball,

determine the number of blue balls in the bag.

Let us assume number of blue balls = x

Then, total number of balls = x + 5

Then;

P(red) = 5/(5 + x)

P(blue)= x/(5 + x)

According to question,

x/(5 + x) = 2 * 5/(5 + x)

=> x/(5 + x) = 10/(5 + x)

=> x(5 + x) = 10(x + 5)

=> 5x + x2 = 10x + 50

=> x2 + 5x - 10x – 50 = 0

=> x2 - 5x - 50 = 0

=> x2 -10x + 5x – 50 = 0

=> x(x – 10) + 5(x - 10) = 0

=> (x - 10)(x + 5) = 0

=> x = 10, -5

However, the number of balls cannot be negative.

Hence, number of blue balls = 10

Question 4:

A box contains 12 balls out of which x are black. If one ball is drawn at random from the box,

what is the probability that it will be a black ball? If 6 more black balls are put in the box,

the probability of drawing a black ball is now double of what it was before. Find x.

Total number of balls = 12

Total number of black balls = x

P (getting a black ball) = x/12

If 6 more black balls are put in the box, then

Total number of balls = 12 + 6 = 18

Total number of black balls = x + 6

P (getting a black ball now) = (x + 6)/18

According to the condition given in the question,

2(x/12) = (x + 6)/18

=> 2x/12 = (x + 6)/18

=> 2x * 18 = 12(x + 6)

=> 36x = 12x + 72

=> 36x - 12x = 72

=> 24x = 72

=> x = 72/24

=> x = 3

Question 5:

A jar contains 24 marbles, some are green and others are blue. If a marble is drawn at random from the jar,

the probability that it is green is 2/3. Find the number of blue balls in the jar.

Total number of marbles = 24

Let the total number of green marbles be x.

Then, total number of blue marbles = 24 − x

P (getting a given marble) = x/24

According to the condition given in the question,

x/24 = 2/3

=> 3x = 24 * 2

=> 3x = 48

=> x = 48/3

=> x = 16

Therefore, total number of green marbles in the jar = 16

Hence, total number of blue marbles = 24 - x = 24 − 16 = 8