INTRODUCTION
In our daily life, we say that there is a probability that something will happen when it is likely to happen. We often use phrases such as :
"There is a probability that it will rain today",
"There is a probability that it will be a hot day tomorrow",
"There is a probability that he may be right", etc.
The statements:
"It will rain today."
"It will be a hot day tomorrow."
"He may be right."
are the events (or situations) about which have an element of uncertainty in our mind, that the event may happen or may not happen. The happening of an event rules out the possibility of the non-happening of the event and vice-versa. The element of uncertainty about the happening and non-happening of an event can be measured mathematically. The branch of Mathematics, which deals with it, is called Theory of Probability.
HISTORY OF PROBABILITY THEORY
In old times, dice games was a common mode of gambling. In 1654, a French gambler Chevalier De-Mere, approached the well known 17th century French philosopher and mathematician Blaise Pascal (1623-1662) regarding some dice problems. Pascal discussed this problem with another French mathematician, Pierre De-Fermat (1601-1665). Both these mathematicians solved the problem independently. This work of Pascal and Fermat laid the foundation of the probability theory.
The first book on the subject was published in 1663. The title of the book was "Book on Games of Chance".
Significant contributions in the field were also made by mathematicians J. Bernoulli (1654-1705), P. Laplace (1749- 1827), A.A. Markov (1856-1922) and A.N. Kolmogorov (in the 20th century).
DIFFERENT APPROACHES
There are following three approaches to theory of probability:
(i) Experimental approach or Empirical approach or Observed frequency approach.
(ii) Classical approach.
(iii) Axiomatic approach.
Here, in this chapter, we shall study only the Empirical probability and not the other two approaches. The remaining two kinds of approaches are to be left for the time being and we will study these in the next classes.
RANDOM EXPERIMENT
In theory of probability, we deal with situations which are outcomes of a random experiment. This experiment is of a different nature in comparison to the experiment made in physical sciences. Here, an experiment repeated under same conditions, may not give the same result (or outcome). For example, we' toss a coin and we get head but there is no guarantee that we must have the same result on the second toss. In this case, it may be tail.
When we perform a random experiment, it is called a trial. For example, if we toss a coin (fair coin) once, the possible outcomes (i,e., results) are H and T. Here, H means head and T means tail. Now, we toss a pair of two similar fair coins and the possible outcome of one toss, i.e., one trial are:
(i) Tail on both the coins, i.e., no head.
(ii) Tail on one coin and head on the other coin, i.e., exactly one head and one tail.
(iii) Head on both the coins, i.e., we get two heads.
The above outcomes can be expressed in numerical numbers as 0, 1, 2. So, there are three possible outcomes of one trial of tossing two coins simultaneously and these outcomes are written as 0, 1, 2. Here, 0 means that no head occurs ; 1 means that exactly one head occurs ; and 2 means that exactly two heads occur. There is no possibility of any other value or outcome of this random experiment.
Similarly, if we toss three similar (fair) coins simultaneously, then the possible outcomes will be 0, 1, 2 and 3.
TOSSING OF A DIE AND ITS POSSIBLE OUTCOMES
A die is a fair and balanced cube with its six faces marked with dots from one to six as below:
If a die is tossed, we find one face out of the six faces at the top. We count the number of dots on this face.
The outcome is 'n' if the number of dots on the top face are n ; n = 1, 2, 3, 4, 5, 6. Thus, in this random experiment, there are six possible outcomes. The possible outcomes are :
1. i.e., we get 1 on the top face ;
2. i.e., we get 2 on the top face ;
3. i.e., we get 3 on the top face ;
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6, i.e., we get 6 on the top face.
EVENT ASSOCIATED WITH A RANDOM EXPERIMENT
An event associated with a random experiment is a collection of some outcomes out of the possible outcomes of the random experiment. Events are generally denoted by the capital letters A, B, E, F, etc.
For example, a pair of coins are tossed simultaneously and the possible outcomes are, 0 number of heads, 1 head and 2 heads. If E be the event of getting at least one head, then E = {1, 2}. Here we say that the outcomes 1 and 2 of the random experiment favours the happening of the event E but the outcome 0 does not favour the happening of the event E or in other words, the outcome 0 favours the happening of the event 'not E'. A teacher gives four coins (fair) of same type to a student and asks him throw these four coins on the floor. The teacher makes enquiry about the number of heads from the other student. The correct answer given by that student is as below :
Either 0 number of heads (all four are tails)
or 1 head (other three are tails)
or 2 heads (other two are tails)
or 3 heads (one is tail)
or 4 heads (no tail)
Now, the teacher say that an event E is to get more than 1 heads. The third student is asked by the teacher to name the outcomes which favour the happening of the event E.
The third students reply is as under:
The favourable outcomes are 2, 3 and 4.
We can write E = {2, 3, 4}.
Two students play a game by throwing a die. Student X says that he will win if he gets an even number on the die and he will lose the game to the second student Y if the outcome is more than 4. Now, the question arises, who is more beneficial, X or Y ? Let us examine the truth.
The possible outcomes are 1, 2, 3, 4, 5 and 6.
Here, X wins the game if the outcomes are 2, 4 and 6, i.e., the three outcomes favours X. But if the outcomes are of values more than 4, then X loses the game and Y wins the game. Such outcomes are 5 and 6. Thus, only two outcomes favours Y. Clearly X is more beneficial than Y.
In the above activity, event E is to get an even number and the favourable outcomes are 2, 4 and 6. Now, we denot the event of getting a number greater than 4 as F. So, the favourable outcomes for the, happening of the event F are 5 and 6.
DATA OF MORE THAN ONE TRIALS
A single trial as a random experiment gives exactly one outcome at a time. On this basis, we cannot claim that the occurence of all outcomes have equal chances. We will confirm, through practical activity, that the chances for the happening of all outcomes is equally likely.
Practical Activity
Take a fair coin, toss it 50 times and record the outcome after every toss in the form of values H (for head) and T (for tail). Here, the number of trials are 50 and the data has two distinct values as H and T. Now, prepare a frequency distribution table as below :
Outcomes Number of times i.e., frequency
Outcomes | Number of times i.e., frequency |
H | f1 |
T | f2 |
Total Number of Trials | = f1 + f2 = 50 |
Observe the values of the fractions . You will notice the following :
i.e., the possibility of the occurences of head and tail is equally likely for each.
Practical Activity
Toss a pair of coins simultaneously 50 times and record the outcomes as 0, 1 and 2 for each toss or trial. As usual, 0 means no head and all tails; 1 means one head and one tail; and 2 means two heads and no tail.
Now, prepare a frequency distribution table as below:
Outcomes as number of heads | Nmriber of times i.e., frequency |
0 | f1 |
1 | f2 |
2 | f3 |
Total number of tosses or trials | = f1 + f2 + f3 = 50 |
Observe the values of the fractions . You will notice the following:
(i) All the fractions are approximately equal to 1/3 , i.e., 0.33....., equally likely chances for the happening of 0, 1 and 2.
EMPIRICAL PROBABILITY OF AN EVENT
In practical activity 1, the values are the empirical probabilities for the happening of the outcomes H and T respectively.
In practical activity 2, the values are the empirical probabilities for the happening of the outcomes 0, 1 and 2 respectively. In this activity, if we say that the event E happens when we get atleast one head and then prepare frequency distribution table for two events which are E and not E as below :
Event | Frequency |
E (happens for (1 and 2) not-E (happens for 0) | |
Total number of trials | 50 |
Here, the values of the fractions are empirical probabilities of the events E and not-E respectively.
For example, if we toss a pair of coins 20 times and we get 0, 7 times ; 1, 7 times; and 2, 6 times, we have the table for the events E and not-E as below :
Event | Frequency |
E not-E | 7 + 6= 13 7 |
Total marker of trials | 20 |
Probability of the event E = 13/20 and probability of the event not-E =
Also, we find that Probability of E + Probability of not-E
P (E) denotes the empirical probability for the happening of an event E. In this chapter, we shall use word probability in place of empirical probability. We define,
REMARK 1. P (E) + P (not-E) = 1.
REMARK 2 . 0 < P (E) < 1.
REMARK 3. Sum of the probabilities of all the outcomes of a random experiment is 1.
Sure Event
When all the outcomes of a random experiment favour an event, the event is called a sure event and its empirical probability is 1.
Impossible Event
When no outcome of a random experiment favours an event, the event is called an impossible event and its empirical probability is 0.
Ex.1 There are 40 students in a class and their results is presented as below :
Result (Pass/Fail) | Pass | Fail |
Number of Students | 30 | 10 |
If a student chosen at random out of the class, find the probability that the student has passed the examination.
Sol. Total number of chances = 40
Chances or trials which favour a student to pass = 30
The probability of the required event, i.e., the student has passed the examination = 30/40 = 0.75
Ex.2 A coin is tossed 150 times and the outcomes are recorded. The frequency distribution of the outcomes H (i.e., head) and T (i.e., tail) is given below :
Outcome | H | T |
Frequency | 85 | 65 |
Find the value of P (H), i.e., probability of getting a head in a single trial.
Sol. Total number of trials = 150
Chances or trials which favour the outcome H = 85.
P (H) = 85/150 = 0.567 (approx)
Ex.3 A die is tossed 120 times and the outcomes are recorded as below:
Outcome | 1 | Eveu Number less than 6 | Odd number greater than 1 | 6 |
Frequency | 20 | 35 | 30 | 15 |
Find the probability in a trial of getting
(i) The number 1
(ii) The number 6
(iii) The even number less than 6.
(iv) The odd number greater than 1.
Sol. Total number of trials = 120
(i) Chances which favour the outcome 1 are 20.
So, P (getting 1) = 20/120 = 0.167 (approx)
(ii) P (getting 6) = 15/120 = 0.125
(iii) Now, getting an even number less than 6 implies that the outcomes 2 or 4.
The total number of chances of getting 2 or 4, i.e., an even number less than 6 = 35
P (even number less than 6)
(iv) Getting an odd number greater than 1, i.e., 3 or 5.
The chances favouring an odd number greater than 1 = 30.
So, P (an odd number greater than 1) = 30/120 = 1/4 0.25
Ex.4 Two similar coins were tossed simultaneously 1000 times and the frequency distribution of heads obtained on each toss is as below :
No. of heads | 0 | 1 | 2 |
Frequency | 200 | 500 | 300 |
Find the probabilities of the following :
(i) Probability of getting one head.
(ii) Probability of getting two heads.
(iii) Probability of getting at least one head
(iv) Probability of getting less than two heads.
(v) Probability of getting three heads.
(vi) Probability of getting not more than two heads.
Sol. Total number of trials = 1000
(i) Total number of chances favouring the event of getting one head = 500. So, P (one head) = 500/1000 = 0.5
(ii) P (two heads) = 300/1000 = 0.3
(iii) P (at least one head) = P (1 head or 2 heads)
(iv) P (less than two heads) = P (0 head or 1 head)
(v) P (three heads) = 0/1000 (No chance favour the occurence of three heads) = 0
(vi) P (not more than two heads) =
Ex.5 A die is thrown 1000 times with the frequencies for the outcomes 1, 2, 3, 4, 5 and 6 as given in the data below:
Outcome | 1 | 2 | 3 | 4 | 5 | 6 |
Frequency | 180 | 150 | 158 | 145 | 176 | 191 |
Find the probability of getting each outcome. Also, show that the sum of the probabilities of all outcomes is 1.
Sol. We denote the event of getting 1 by E1 and similarly, E2, E3. E4. E5 and E6 for getting 2, 3, 4, 5 and 6 respectively. From the table, we have
Similarly,
Now,
P(E1) +P(E2) +P(E3) + P(E4) +P(E5) +P(E6)
= 0·180 + 0·150 + 0·158 + 0·145 + 0·176 + 0·191 = 1·000, i.e., 1.
Hence, the sum of the probabilities of all the outcomes is 1 .
Ex.6 There are 500 packets in a large box and each packet contains 4 electric devices in it. On testing, at the time of packing, it was noted that there are some faulty pieces in the packets. The data is as below :
No. of faulty devices a packet | 0 | 1 | 2 | 3 | 4 | Total number of packets |
Number of packets | 300 | 100 | 50 | 30 | 20 | 500 |
If one packet is drawn from the box, what is the probability that all the four devices in the packet are without any fault?
Sol. When the packet has all the four devices without fault, it means the number of faulty devices in the packet is 0. Number of chances which are favourable to 0 are 300 as given in the table above.
Thus, the probability of packet containing all the four devices without any fault
Ex.7 A factory manufacturing car batteries made a survey in the field about the life of these batteries.
The data obtained is as under :
Life time (in months) | Less than 24 | 24 to 36 | 36 to 48 | more than 48 | Total number of batteries |
Frequency or the number of batteries | 40 | 220 | 540 | 200 | 1000 |
If you put a battery of this company in your car, what is the probability that
(i) the battery will last for more than 36 months?
(ii) the battery will last for less than 48 months?
(iii) the battery will last for 36 to 48 months?
Sol. Total frequency or the total number of trials made = 1000
(i) The total number of batteries which last for more than 36 months = 540 + 200 = 740
Now, P (battery will last for more than 36 months)
(ii) The total number of batteries which last for less than 48 months = 40 + 220 + 540 = 800
So, P (battery will last for less than 48 months)
(iii) The total number of batteries which last for 36 to 48 months = 540
So, P (battery will last for 36 to 48 months )
Ex.8 400 students of class X of a school appeared in a test of 100 marks in the subject of social studies and the data about the marks secured is as below :
Marks secured | 0-25 | 26-50 | 51-75 | Above 75 | Total number of students |
Number of Students | 50 | 220 | 100 | 30 | 400 |
If the result card of a student he picked up at random, what is the probability that the student
has secured more than 50 marks.
Sol. Total number of students, i.e . the total frequency = 400
The total number of students who secured more than 50 marks = 100 + 30 = 130
Probability that the marks secured are more than 50
Ex.9 100 plants each, were planted in 100 schools during Van Mahotsava. After one month, the number of plants that survived were recorded as in data below :
No, of faulty devices in a packet | 0 | 1 | 2 | 3 | 4 | Total number of packets |
Number of packets | 300 | 100 | 50 | 30 | 20 | 500 |
When a school is selected at random for inspection, what is the probability that:
(i) More than 25 plants survived in the school?
(ii) Less than 61 plants survived in the school?
(iii) 61 to 70 plants survived in the school?
Sol. Total frequency or the total number of schools in which plants were planted = 100
(i) Number of schools in which more than 25 plants survived = 20 + 30 + 30 + 5 = 85
P (more than 25 plants survived in the school) = 85/100 = 0.85
(ii) Number of schools in which less than 61 plants survived = 15 + 20 + 30 = 65
P (Less than 61 plants survived) = 65/100 = 0.65
(iii) P (61 to 70 plants survived) = 30/100 = 0.30
Ex.10 Fifty seeds were selected at random from each of 5 bags A, B, C, D, E of seeds, and were kept under standardised conditions equally favourable to germination. After 20 days, the number of seeds which had germinated in each collection were counted and recorded as follow :
Marks secured | 0-2 5 | 26-50 | 51 -7 5 | Above 75 | Tota 1 number of students |
Number of Students | 50 | 220 | 100 | 30 | 400 |
What is the probability of germination of
(i) more than 40 seeds in a bag?
(ii) 49 seeds in a bag?
(iii) more than 35 seeds in a bag?
Sol.
(i) Number of bags in which more than 40 seeds out of 50 seeds germinated = 3
(These are B, C and E)
Total number of bags = 5
So, P (more than 40 secds in a bag germinated = 3/5 = 0.60
(ii) Number of bags in which 49 seeds germinated = 0
So, P (49 seeds germinated in bag) = 0/5 = 0
(iii) Number of bags in which more than 35 seeds out 50 seeds germinated = 5
Total number of bags = 5
So, P (more than 35 seeds in a bag germinated) = 5/5 = 1
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1. What is probability and how is it calculated? |
2. Can you provide an example of calculating probability? |
3. What are mutually exclusive events in probability? |
4. How do you calculate the probability of two independent events? |
5. What is the difference between theoretical and experimental probability? |
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