`\color{green} ✍️` we have studied some methods of assigning probability to an event associated with an experiment having known the number of total outcomes.

`\color{green} ✍️ ` Axiomatic approach is another way of describing probability of an event. In this approach some axioms or rules are depicted to assign probabilities.

Let `S` be the sample space of a random experiment.

The probability `P` is a real valued function whose domain is the power set of `S` and range is the interval `[0,1]` satisfying the following axioms

`color(red)((i))` For any event `E, \ \ P (E) ≥ 0`

`color(red)((ii))\ \ P (S) = 1`

`color(red)((iii))` If `E` and `F` are `color(blue)("mutually exclusive events")`, then `color(green)(P(E ∪ F) = P(E) + P(F).)`

It follows from `(iii)` that `P(φ) = 0.`

To prove this, we take `F = φ` and note that `E` and `φ` are disjoint events.

Therefore, from axiom `(iii),` we get `color(blue)(P (E ∪ φ) = P (E) + P (φ))` or `color(green)(P(E) = P(E) + P (φ))` i.e. `color(red)(P (φ) = 0.)`

Let `S` be a sample space containing outcomes `ω_1 , ω_2 ,...,ω_n` , i.e.,

`S = {ω_1, ω_2, ..., ω_n}`

It follows from the axiomatic definition of probability that

`color(red)((i)) color(green)(0 ≤ P (ω_i) ≤ 1)` for each `ω_i ∈ S`

`color(red)((ii)) P (ω_1) + P (ω_2) + ... + P (ω_n) = 1`

`color(red)((iii))` For any event `A,` `color(green)(P(A) = Σ P(ω_i ), \ \ ω_i ∈ A.)`

`color{blue} "Key Point : "` It may be noted that the singleton `{ω_i}` is called elementary event and for notational convenience, we write `P(ω_i ) ` for `P({ω_i }`).

For example, in ‘a coin tossing’ experiment we can assign the number `1/2 ` to each of the outcomes H and T.

`\color{fuchsia} {ul★ " Probability of an event"}`

Let `S` be a sample space associated with the experiment ‘examining three consecutive pens produced by a machine and classified as Good (non-defective) and bad (defective)’.

We may get 0, 1, 2 or 3 defective pens as result of this examination.

A sample space associated with this experiment is

` " " color(blue)(S = {BBB, BBG, BGB, GBB, BGG, GBG, GGB, GGG})`

where `B` stands for a defective or bad pen and `G` for a non – defective or good pen.

Let the probabilities assigned to the outcomes be as follows

`tt ( (text{Sample point :} , BBB , BBG , BGB , GBB , BGG , GBG , GGB , GGG) , ( text{Probability:} , 1/8 , 1/8 , 1/8 , 1/8 , 1/8 , 1/8 , 1/8 , 1/8))`

Let `color(red)("event A: there is exactly one defective pen")` and

`color(red)("event B: there are atleast two defective pens.")`

Hence `A = {BGG, GBG, GGB}` and `B = {BBG, BGB, GBB, BBB}`

Now `color(red)(P(A)) = Sigma P(omega_i) AA omega_i in A`

`" " = P (BGG) +P(GBG)+P(GGB) = 1/8+1/8+1/8 = 3/8`

and `color(red)(P(B)) = Sigma P(omega_i) AA omega_i in B`

`" " = P(BBG) + P(BGB) + P(GBB) + P(BBB) = 1/8+1/8+1/8+1/8 = 4/8 = 1/2`

Let a sample space of an experiment be

`S = {ω_1, ω_2,..., ω_n}`.

Let all the outcomes are equally likely to occur, i.e., the chance of occurrence of each simple event must be same

i.e. `P ( ω_i ) = p` , for all ` ω_i ∈ S` where ` 0 le p le 1`

Since `sum_(i=1)^n P( ω_i) =1` i.e, `p + p + ... + p (n" times") = 1 `

`np = 1` i.e, `p = 1/n`

Let `S` be a sample space and E be an event, such that `n(S) = n` and `n(E) = m`.

If each out come is equally likely, then it follows that

`color(red)(P(E) = m/n = ( text (Number of outcomes favourable to E ) )/( text ( Total possible outcomes ) ) )`

Let us now find the probability of event `"‘A or B’"`, i.e., `P (A ∪ B)`

Let `A = {HHT, HTH, THH}` and `B = {HTH, THH, HHH} ` be two events associated with ‘tossing of a coin thrice’

Clearly `A ∪ B = {HHT, HTH, THH, HHH}`

Now `P (A ∪ B) = P(HHT) + P(HTH) + P(THH) + P(HHH)`

If all the outcomes are equally likely, then

`P (A ∪ B) = 1/8 + 1/8 + 1/8 + 1/8 = 4/8 = 1/2`

Also` P(A) = P(HHT) + P(HTH) + P(THH) = 3/8`

and `P(B) = P(HTH) + P(THH) + P(HHH) = 3/8`

Therefore` P(A) + P(B) = 3/8 + 3/8 = 6/8`

It is clear that` P(A∪ B) ≠ P(A) + P(B)`

The points `HTH` and `THH ` are common to both `A` and `B .`

In the computation of `P(A) + P(B)` the probabilities of points `HTH` and `THH`, i.e., the elements of `A ∩B` are included twice.

Thus to get the probability `P(A ∪ B) `we have to subtract the probabilities of the sample points in `A ∩ B` from `P(A) + P(B)`

i.e. `P(A∪B) = P(A) + P(B) − ΣP(ω_i ),∀ ω_i ∈ A∩ B`

`= P(A) + P(B) − P(A ∩B)`

Thus we observe that, `P(A∪ B) = P(A) + P(B) − P(A ∩B)`

In general, if A and B are any two events associated with a random experiment, then by the definition of probability of an event, we have

` P(A ∪ B ) = Σ p(ω_i ),∀ ω_i ∈ A ∪ B`.

Since `A∪B = (A–B) ∪ (A ∩B)∪(B–A)` ,
we have

`P(A ∪ B) = [ Σ P(ω_i ) ∀ ω_i ∈ (A–B)] + [ Σ P(ω_i ) ∀ ω_i ∈ A ∩ B ] + [ ΣP ( ω_i ) ∀ ω_i ∈ B – A]`

(because `A–B, A ∩ B` and `B – A `are mutually exclusive) ... (1)



Also `P(A) + P(B) = [Σ p(ω_i ) ∀ω_i ∈A]+[ Σ p(ω_i ) ∀ω_i ∈B]`

`= [ Σ P (ω_i )∀ω_i ∈(A–B)∪(A∩B)] + [ Σ P (ω_i )∀ω_ i ∈(B – A)∪(A∩B)]`

`= [ Σ P (ω_i )∀ω_i ∈(A – B ) ] + [ Σ P ( ω_i ) ∀ ω_i ∈(A∩B)] + [ Σ P (ω_i ) ∀ω_i ∈ (B–A)] +

[ Σ P(ω_i )∀ω_ i ∈(A∩ B)]`

`= P(A∪B) + [ Σ P (ω_i )∀ ω_i ∈A∩B]` [using (1)]

`= P(A∪ B)+P(A ∩B) `.

Hence `P(A∪B)=P (A)+P(B) – P(A∩B)` .

Alternatively, it can also be proved as follows:

`A ∪ B = A ∪ (B – A)`, where A and `B – A` are mutually exclusive,

and `B = (A ∩ B) ∪ (B – A)`, where `A ∩ B` and B – A are mutually exclsuive.

Using Axiom (iii) of probability, we get

`P (A ∪B) = P (A) + P (B – A)` ... (2)

and `P(B) = P ( A ∩ B) + P (B – A)` ... (3)

Subtracting (3) from (2) gives

`P (A ∪ B) – P(B) = P(A) – P (A ∩ B)`

or `P(A ∪ B) = P(A) + P (B) – P (A ∩ B)`

The above result can further be verified by observing the Venn Diagram (Fig 16.1)

`color(red)(=> P(A ∪B) = P(A) + P(B)) `,

`color(blue)("If A and B are disjoint sets")`, i.e., they are mutually exclusive events, then `color(red)(A ∩ B = φ)`

Therefore `color(blue)(P(A∩B) = P (φ) = 0)`

Thus, for mutually exclusive events `A` and `B`, we have

`P(A ∪B) = P(A) + P(B) `,

which is Axiom (iii) of probability.

Also, we know that `A′` and `A` are mutually exclusive and exhaustive events i.e.,

`A ∩ A′ = φ` and `A ∪ A′ = S`

or `color(blue)(P(A ∪ A′) = P(S))`

Now `P(A) + P(A′) = 1`,

or `color(red)(P( A′ ) = P ( "not " A ) = 1 – P(A))`


`color(red)(=> "Consider the event " A = {2, 4, 6, 8})`

associated with the experiment of drawing a card from a deck of ten cards numbered from `1` to `10.`

Clearly the `color(blue)("sample space is "S = {1, 2, 3, ...,10})`

If all the outcomes `1, 2, ...,10` are considered to be equally likely, then the probability of each outcome is `1/10`

Now `P(A) = P(2) + P(4) + P(6) + P(8)`

`" " =1/10 + 1/10 + 1/10 + 1/10 = 4/10 = 2/5`

Also event ‘not `A’ = A′ = {1, 3, 5, 7, 9, 10}`

Now `color(blue)(P(A′)) = P(1) + P(3) + P(5) + P(7) + P(9) + P(10)`

` " " = 6/10 = 3/5`

Thus , `color(red)(P(A') )= 3/5 = 1-2/5 = color(red)(1 -P(A))`