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Essential Statistics Chapter 11 1
Chapter 11
General Rules of Probability
Essential Statistics Chapter 11 2
Probability Rules from Chapter 9
Essential Statistics Chapter 11 3
Venn Diagrams
Two disjoint events:
Two events that are not disjoint, and the event {A and B} consisting of the outcomes they have in common:
Essential Statistics Chapter 11 4
If two events A and B do not influence each other, and if knowledge about one does not change the probability of the other, the events are said to be independent of each other.
If two events are independent, the probability that they both happen is found by multiplying their individual probabilities:
P(A and B) = P(A) P(B)
Multiplication Rulefor Independent Events
Essential Statistics Chapter 11 5
Multiplication Rule for Independent Events
Example Suppose that about 20% of incoming male freshmen smoke.
Suppose these freshmen are randomly assigned in pairs to dorm rooms (assignments are independent).
The probability of a match (both smokers or both non-smokers):– both are smokers: 0.04 = (0.20)(0.20)– neither is a smoker: 0.64 = (0.80)(0.80)– only one is a smoker: ?
} 68%
32% (100% 68%) What if pairs are self-selected?
Essential Statistics Chapter 11 6
Addition Rule: for Disjoint Events
P(A or B) = P(A) + P(B)
Essential Statistics Chapter 11 7
General Addition Rule
P(A or B) = P(A) + P(B) P(A and B)
Essential Statistics Chapter 11 8
Case Study
Student DemographicsAt a certain university, 80% of the students were in-state students (event A), 30% of the students were part-time students (event B), and 20% of the students were both in-state and part-time students (event {A and B}). So we have that P(A) = 0.80, P(B) = 0.30, and P(A and B) = 0.20.
What is the probability that a student is either an in-state student or a part-time student?
Essential Statistics Chapter 11 9
Other Students
P(A or B) = P(A) + P(B) P(A and B) = 0.80 + 0.30 0.20 = 0.90
All Students
Part-time (B)
0.30{A and B}
0.20
Case Study
In-state (A)
0.80
Essential Statistics Chapter 11 10
Other Students
All Students
Part-time (B)
0.30
Case Study
{A and B}
0.20In-state (A)
0.80In-state, but not
part-time (A but not B):0.80 0.20 = 0.60
Essential Statistics Chapter 11 11
The probability of one event occurring, given that another event has occurred is called a conditional probability.
The conditional probability of B given A is denoted by P(B|A)– the proportion of all occurrences of A for
which B also occurs
Conditional Probability
Essential Statistics Chapter 11 12
Conditional Probability
P(A)
B) andP(A A)|P(B
When P(A) > 0, the conditional probability of B given A is
Essential Statistics Chapter 11 13
Case Study
Student DemographicsIn-state (event A): P(A) = 0.80Part-time (event B): P(B) = 0.30Both in-state and part-time: P(A and B) = 0.20.
Given that a student is in-state (A), what is the probability that the student is part-time (B)?
0.25 0.80
0.20
P(A)
B) andP(A A)|P(B
Essential Statistics Chapter 11 14
General Multiplication Rule
P(A and B) = P(A) P(B|A)
or P(A and B) = P(B) P(A|B)
For ANY two events, the probability that they both happen is found by multiplying the probability of one of the events by the conditional probability of the remaining event given that the other occurs:
Essential Statistics Chapter 11 15
Case Study
Student Demographics
At a certain university, 20% of freshmen smoke, and 25% of all students are freshmen.Let A be the event that a student is a freshman, and let B be the event that a student smokes.So we have that P(A) = 0.25, and P(B|A) = 0.20.
What is the probability that a student smokes and is a freshman?
Essential Statistics Chapter 11 16
Case Study
Student Demographics
P(A) = 0.25 , P(B|A) = 0.20
5% of all students are freshmen smokers.
P(A and B) = P(A) P(B|A)= 0.25 0.20= 0.05
Essential Statistics Chapter 11 17
Independent Events
Two events A and B that both have
positive probability are independent if
P(B|A) = P(B)
– General Multiplication Rule:P(A and B) = P(A) P(B|A)
– Multiplication Rule for independent events:P(A and B) = P(A) P(B)
Essential Statistics Chapter 11 18
Tree Diagrams Useful for solving probability problems that
involve several stages Often combine several of the basic probability
rules to solve a more complex problem– probability of reaching the end of any complete
“branch” is the product of the probabilities on the segments of the branch (multiplication rule)
– probability of an event is found by adding the probabilities of all branches that are part of the event (addition rule)
Essential Statistics Chapter 11 19
Case StudyBinge Drinking and Accidents
At a certain college, 30% of the students engage in binge drinking. Among college-aged binge drinkers, 18% have been involved in an alcohol-related automobile accident, while only 9% of non-binge drinkers of the same age have been involved in such accidents.Let event A = {accident related to alcohol}.Let event B = {binge drinker}.So we have P(A|B)=0.18, P(A|’not B’)=0.09, & P(B)=0.30 .
What is the probability that a randomly selected student has been involved in an alcohol-related automobile accident?
Essential Statistics Chapter 11 20
Case StudyBinge Drinking and Accidents
P(Accident) = P(A) = 0.054 + 0.063 = 0.117
0.054
0.637
0.063
0.246
P(A and B)
= P(B)P(A|B)
= (0.30)(0.18)
Accident
No accident
Accident
No accident
0.09
0.82
0.18
0.91
Bingedrinker
Non-binge drinker
0.30
0.70
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