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LECTURE 6 OF 6
CONDITIONAL PROBABILITY
& BAYES’ THEOREM
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At the end of the lesson, students should be able to:
(a) understand and use Bayes’ Theorem to solve
probability problems
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REMEMBER – THE PREVIOUS LECTURE
• the conditional probability of A given B is written as
P(A | B)
The event that has already occurredThe event whose
probability is to bedetermined
P(A B)
P(B)
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P(B | A) = 0.2
P(A | B) = ?
When the condition is reversed , Bayes’ Theorem is used to solve
such problems.
If you are given
How do you find ?
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A
B
B
B’
B’
A’
P( B | A’ )
P( A)
P( B | A )
P( A’)
P( B ) = P(A) x P( B | A ) + P(A’) x P( B | A’ )
TOTAL PROBABILITY OF EVENT B = P(B)
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In general, if events A1 ,A2, .……., An aremutually exclusive and exhaustive events,then the probability of event B is given by :
P( B ) = P(A1) x P( B | A1 ) + P(A2) x P( B | A2 )
+ P(A3) x P( B | A3 ) +…..+ P(An) x P( B | An )
TOTAL PROBABILITY OF EVENT B = P(B)
THE TOTAL PROBABILITY THEOREM
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P( A B)P( A|B )
P(B)
P(B A )P(B|A )
P(A)
P (A|B) : “the probability of A given B”
P (B|A) : “the probability of B given A”
P(B|A ) P(A) P(B A)
P( A|B ) P(B) P(A B)
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P( A B )P( A|B )
P(B)
P(B|A ) P(A) P(B A)
P(B|A) P(A)P( A|B )
P(B)
Since P A B P(B A)
BAYES’ THEOREM
(2)
(1)
Substitute (2) into (1) , we get :
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BAYES’ THEOREM
i i
i
P(B|A ) P(A )P( A |B )
P(B)
where A1 , A2 , ….. , An are n mutuallyexclusive and exhaustive events so thatA1 A2 ……. An = S , the possibility space, and B is an arbitrary event of S ( i = 1,2,3,…..,n ) .P(B) is the total probability of event B.
Bayes’ Theorem is useful when we haveto ‘ reverse the conditions ’ in a problem.
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Example 1
There are 12 red balls and 8 green balls in a bucket. Two balls are taken out in sequence without replacement. By using a tree diagram , find the probability that
(a) the first ball is red
(b) the second one is red if the first is red
(c) the second one is red if the first is green
(d) the second one is red
(e) the first one is red if the second is red
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Solution:
1st draw
R1
G1820
1220
1119
2nd draw
819 1219
719
G2
R2
G2
R2
R ~ red ball G ~ green ball
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(a) P( first ball is red) = P(R1)12 3
20 5
(b) P( R2 | R1 ) 11
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tree diagram
Or using the formula of conditional probability
P( R2 | R1 )1 2
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P( R R )
P(R )
12 1120 19
1220
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(c) P( R2 | G1 )1219
Direct from the tree diagram
(d) P( R2)
8 1220 19
12 11
20 19
3
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= P( R1 ∩ R2) + P(G1 ∩ R2)
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(e) P(R1 | R2 ) = 2 1 1
2
P( R R ) P(R )
P(R )
11 1219 20
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‘Reverse condition’use Bayes’ Theorem
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Example 2
I travel to work by route A or route B. The probability that I choose route A is .
The probability that I am late for work if I go via
route A is and the corresponding probability ifI go via route B is .
(a) What is the probability that I am late for work
on Monday ?(b) Given that I am late for work, what is the
probability that I went via route B ?
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Solution:
ROUTE
B34
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13 13
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A L’ (not late)
L (late)
L’ (not late)
L (late)
ARRIVE AT WORK
P(A) x P(L|A)
P(B) x P(L|B)
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P(A) x P( L | A )
(a) P ( L ) = + P(B) x P( L | B) 1 2 3 1
4 3 4 3
512
(b)
P(L|B) P(B)P(B|L )
P(L)
1 333 4
5 512
BAYES’ THEOREM
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Example 3
Aishah, Siti and Muna pack biscuits in a factory. Aishah packs 55%, Siti 30% and Muna 15% from the batch allotted to them.The probability that Aishah breaks some biscuits in a packet is 0.7, and the respective probabilities for Siti and Munaare 0.2 and 0.1. What is the probabilitythat a packet with broken biscuits found bythe checker was packed by Aishah ?
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Solution:
A
B
B
B’
B’
S
M
0.3
0.55
0.7
B
B’
0.15
A – Aishah, S – Siti , M - MunaB – Broken Biscuits
0.3
0.2
0.80.1
0.9
P( A|B )
P(B|A) P(A)P(B)
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P(B|A) P(A)P( A|B )
P(B)
0.7 0.55(0.55 0.7) (0.3 0.2) (0.15 0.1)
0.7 0.550.837
0.46
BAYES’ THEOREM
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Example 4
According to a firm’s internal survey, ofthose employees living more than 2 milesfrom work , 90% travel to work by car. Of the remaining employees, only 50% travelto work by car. It is known that 75% of employees live more than 2 miles from work. Determine :(i) the overall proportion of employees who travel to work by car.(ii) the probability that an employee who travels to work by car lives more than 2 miles from work.
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Define the events C , B1 , B2 as follows :
C : Travels to work by car
B1 : Lives more than 2 miles from work
B2 : Lives not more than 2 miles from work
The events B1 and B2 are mutually exclusiveand exhaustive.P(B1) = 0.75 , P(B2) = 0.25
P( C | B1 ) = 0.9 and P( C | B2 ) = 0.5
Solution:
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B20.25
0.75
0.9
0.1
0.5
B1C’
C
C
C’0.5
(i) P(C) =
P(B1) x P( C | B1 ) + P(B2) x P( C | B2 )
= ( 0.75 x 0.9 ) + ( 0.25 x 0.5 )
= 0.8
P( C | B1 ) = 0.9 P( C | B2 ) = 0.5
P(B1) = 0.75,P(B2) = 0.25
Solution:
80% of employeestravel to work by car.
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1 1
1
P(C|B ) P(B )P(B |C )
P(C)
0.9 0.750.8
0.84375
BAYES’ THEOREM(ii)
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BAYES’ THEOREM
i i
i
P(B|A ) P(A )P( A |B )
P(B)
THE TOTAL PROBABILITY THEOREM
P( B ) = P(A1) x P( B | A1 ) + P(A2) x P( B | A2 )
+ P(A3) x P( B | A3 ) +…..+ P(An) x P( B | An )
TOTAL PROBABILITY OF EVENT B = P(B)
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Exercise :
1.Three children, Azman, Mariam and Nasir, have equal plots in a circular patch of garden. The boundaries are marked out by pebbles, Azman has 80 red and 20 white flowers in her patch, Mariam has 30 red and 40 white flowers and Nasir has 10 red and 60 white flowers. Their young sister,Mumtaz, wants to pick a flower for her teacher.
(a) Find the probability that she picks a red flowerif she chooses a flower at random from the gardenignoring the boundaries.(b) Find the probability that she picks a red flowerif she first chooses a plot at random.
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(c) If she picks a red flower by the method described in (b), find the probability that it comes from Mariam’s plot.
Answer :
(a) 0.5 (b) (c) 1635
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