Download - Chapter 5 Probability in our Daily Lives
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Chapter 5Probability in our Daily Lives
Section 5.1: How can Probability Quantify Randomness?
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Learning Objectives
1. Random Phenomena2. Law of Large Numbers3. Probability4. Independent Trials5. Finding probabilities6. Types of Probabilities: Relative Frequency
and Subjective
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Learning Objective 1:Random Phenomena
For random phenomena, the outcome is uncertain In the short-run, the proportion of times that
something happens is highly random In the long-run, the proportion of times that
something happens becomes very predictable
Probability quantifies long-run randomness
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Learning Objective 2:Law of Large Numbers
As the number of trials increase, the proportion of occurrences of any given outcome approaches a particular number “in the long run”
For example, as one tosses a die, in the long run 1/6 of the observations will be a 6.
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Learning Objective 3:Probability
With random phenomena, the probability of a particular outcome is the proportion of times that the outcome would occur in a long run of observations
Example: When rolling a die, the outcome of “6” has
probability = 1/6. In other words, the proportion of times that a 6 would occur in a long run of observations is 1/6.
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Learning Objective 4:Independent Trials
Different trials of a random phenomenon are independent if the outcome of any one trial is not affected by the outcome of any other trial.
Example: If you have 20 flips of a coin in a row that are
“heads”, you are not “due” a “tail” - the probability of a tail on your next flip is still 1/2. The trial of flipping a coin is independent of previous flips.
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Learning Objective 5:How can we find Probabilities?
Calculate theoretical probabilities based on assumptions about the random phenomena. For example, it is often reasonable to assume that outcomes are equally likely such as when flipping a coin, or a rolling a die.
Observe many trials of the random phenomenon and use the sample proportion of the number of times the outcome occurs as its probability. This is merely an estimate of the actual probability.
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Learning Objective 6:Types of Probability: Relative Frequency vs. Subjective The relative frequency definition of probability is the
long run proportion of times that the outcome occurs in a very large number of trials - not always helpful/possible.
When a long run of trials is not feasible, you must rely on subjective information. In this case, the subjective definition of the probability of an outcome is your degree of belief that the outcome will occur based on the information available. Bayesian statistics is a branch of statistics that uses
subjective probability as its foundation
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Chapter 5: Probability in Our Daily Lives
Section 5.2: How Can We Find Probabilities?
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Learning Objectives
1. Sample Space2. Event3. Probabilities for a sample space4. Probability of an event5. Basic rules for finding probabilities about a
pair of events
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Learning Objectives
6. Probability of the union of two events7. Probability of the intersection of two events
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Learning Objective 1:Sample Space
For a random phenomenon, the sample space is the set of all possible outcomes.
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Learning Objective 2:Event
An event is a subset of the sample space An event corresponds to a particular outcome
or a group of possible outcomes. For example;
Event A = student answers all 3 questions correctly = (CCC)
Event B = student passes (at least 2 correct) = (CCI, CIC, ICC, CCC)
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Learning Objective 3:Probabilities for a sample space
Each outcome in a sample space has a probability
The probability of each individual outcome is between 0 and 1
The total of all the individual probabilities equals 1.
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Learning Objective 4:Probability of an Event
The probability of an event A, denoted by P(A), is obtained by adding the probabilities of the individual outcomes in the event.
When all the possible outcomes are equally likely:
space sample in the outcomes ofnumber Aevent in outcomes ofnumber )( AP
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Learning Objective 4:Example: What are the Chances of being Audited?
What is the sample space for selecting a taxpayer?
{(under $25,000, Yes), (under $25,000, No), ($25,000 - $49,000, Yes) …}
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Learning Objective 4:Example: What are the Chances of being Audited?
For a randomly selected taxpayer in 2002, What is the probability of an audit?
310/80200=0.004 What is the probability of an income of
$100,000 or more? 10700/80200=0.133
What income level has the greatest probability of being audited? $100,000 or more = 80/10700= 0.007
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Learning Objective 5:Basic rules for finding probabilities about a pair of events Some events are expressed as the outcomes
that Are not in some other event (complement of
the event) Are in one event and in another event
(intersection of two events) Are in one event or in another event (union of
two events)
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Learning Objective 5:Complement of an event
The complement of an event A consists of all outcomes in the sample space that are not in A.
The probabilities of A and of Ac add to 1 P(Ac) = 1 – P(A)
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Learning Objective 5:Disjoint events
Two events, A and B, are disjoint if they do not have any common outcomes
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Learning Objective 5:Intersection of two events
The intersection of A and B consists of outcomes that are in both A and B
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Learning Objective 5:Union of two events
The union of A and B consists of outcomes that are in A or B or in both A and B.
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Learning Objective 6:Probability of the Union of Two Events
Addition Rule:For the union of two events, P(A or B) = P(A) + P(B) – P(A and B)
If the events are disjoint, P(A and B) = 0, so P(A or B) = P(A) + P(B)
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Learning Objective 6:Example
80.2 million tax payers (80,200 thousand) Event A = being audited Event B = income greater than $100,000 P(A and B) = 80/80200=.001
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Learning Objective 7:Probability of the Intersection of Two Events
Multiplication Rule: For the intersection of two independent events,
A and B,P(A and B) = P(A) x P(B)
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Learning Objective 7:Example
What is the probability of getting 3 questions correct by guessing?
Probability of guessing correctly is .2
What is the probability that a student answers at least 2 questions correctly?
P(CCC) + P(CCI) + P(CIC) + P(ICC) =
0.008 + 3(0.032) = 0.104
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Learning Objective 7:Assuming independence
Don’t assume that events are independent unless you have given this assumption careful thought and it seems plausible.
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Learning Objective 7:Events Often Are Not Independent
Example: A Pop Quiz with 2 Multiple Choice Questions Data giving the proportions for the actual
responses of students in a class
Outcome: II IC CI CCProbability: 0.26 0.11 0.05 0.58
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Learning Objective 7:Events Often Are Not Independent
Define the events A and B as follows: A: {first question is answered correctly} B: {second question is answered correctly}
P(A) = P{(CI), (CC)} = 0.05 + 0.58 = 0.63 P(B) = P{(IC), (CC)} = 0.11 + 0.58 = 0.69 P(A and B) = P{(CC)} = 0.58
If A and B were independent, P(A and B) = P(A) x P(B) = 0.63 x 0.69 = 0.43Thus, in this case, A and B are not independent!
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Chapter 5Probability in Our Daily Lives
Section 5.3: Conditional Probability:What’s the Probability of A, Given B?
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Learning Objectives
1. Conditional probability2. Multiplication rule for finding P(A and B)3. Independent events defined using
conditional probability
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Learning Objective 1:Conditional Probability
For events A and B, the conditional probability of event A, given that event B has occurred, is:
P(A|B) is read as “the probability of event A, given event B.” The vertical slash represents the word “given”. Of the times that B occurs, P(A|B) is the proportion of times that A also occurs
)() ()|P(
BPBandAPBA
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Learning Objective 1:Conditional Probability
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Learning Objective 1:Example 1
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Learning Objective 1:Example 1
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Learning Objective 1:Example 1
What was the probability of being audited, given that the income was ≥ $100,000? Event A: Taxpayer is audited Event B: Taxpayer’s income ≥ $100,000
007.01334.00010.0
P(B)B) andP(A B)|P(A
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Learning Objective 1:Example 1
What is the probability of being audited given that the income level is < $25,000
Let A =Event being Audited Let B = Income < $25,000
P(A and B) = .0011 P(B)=.1758 .0011/.1758=.0063
)() ()|P(
BPBandAPBA
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Learning Objective 1:Example 2
A study of 5282 women aged 35 or over analyzed the Triple Blood Test to test its accuracy
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Learning Objective 1:Example 2
A positive test result states that the condition is present
A negative test result states that the condition is not present
False Positive: Test states the condition is present, but it is actually absent
False Negative: Test states the condition is absent, but it is actually present
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Learning Objective 1:Example 2
Assuming the sample is representative of the population, find the estimated probability of a positive test for a randomly chosen pregnant woman 35 years or older
P(POS) = 1355/5282 = 0.257
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Given that the diagnostic test result is positive, find the estimated probability that Down syndrome truly is present
Summary: Of the women who tested positive, fewer than 4% actually had fetuses with Down syndrome
Learning Objective 1:Example 2
035.0257.0009.0
5282/13555282/48
P(POS)POS) and P(D POS)|P(D
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Learning Objective 2:Multiplication Rule for Finding P(A and B)
For events A and B, the probability that A and B both occur equals:
P(A and B) = P(A|B) x P(B)also
P(A and B) = P(B|A) x P(A)
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Learning Objective 2:Example
Roger Federer – 2006 men’s champion in the Wimbledon tennis tournament He made 56% of his first serves He faulted on the first serve 44% of the
time Given that he made a fault with his first
serve, he made a fault on his second serve only 2% of the time
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Learning Objective 2:Example
Assuming these are typical of his serving performance, when he serves, what is the probability that he makes a double fault?
P(F1) = 0.44 P(F2|F1) = 0.02
P(F1 and F2) = P(F2|F1) x P(F1) = 0.02 x 0.44 = 0.009
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Learning Objective 3:Independent Events Defined Using Conditional Probabilities
Two events A and B are independent if the probability that one occurs is not affected by whether or not the other event occurs
Events A and B are independent if:P(A|B) = P(A), or equivalently, P(B|A) = P(B)
If events A and B are independent, P(A and B) = P(A) x P(B)
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Learning Objective 3:Checking for Independence
To determine whether events A and B are independent: Is P(A|B) = P(A)? Is P(B|A) = P(B)? Is P(A and B) = P(A) x P(B)?
If any of these is true, the others are also true and the events A and B are independent
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Learning Objective 3:Example
The diagnostic blood test for Down syndrome:
POS = positive result NEG = negative result D = Down Syndrome DC = Unaffected Status POS NEG Total
D 0.009 0.001 0.010
Dc 0.247 0.742 0.990
Total 0.257 0.743 1.000
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Are the events POS and D independent or dependent? Is P(POS|D) = P(POS)?
P(POS|D) =P(POS and D)/P(D) = 0.009/0.010 = 0.90 P(POS) = 0.257 The events POS and D are dependent
Learning Objective 3:Example: Checking for Independent
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Chapter 5: Probability in Our Daily Lives
Section 5.4: Applying the Probability Rules
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Learning Objectives
1. Is a “Coincidence” Truly an Unusual Event?2. Probability Model3. Probabilities and Diagnostic Testing4. Simulation
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Learning Objective 1:Is a “Coincidence” Truly an Unusual Event?
The law of very large numbers states that if something has a very large number of opportunities to happen, occasionally it will happen, even if it seems highly unusual
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What is the probability that at least two students in a group of 25 students have the same birthday?
Learning Objective 1:Example: Is a Matching Birthday Surprising?
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P(at least one match) = 1 – P(no matches)
Learning Objective 1:Example: Is a Matching Birthday Surprising?
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P(no matches) = P(students 1 and 2 and 3 …and 25 have different birthdays)
Learning Objective 1:Example: Is a Matching Birthday Surprising?
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P(no matches) =
(365/365) x (364/365) x (363/365) x … x (341/365)
P(no matches) = 0.43
Learning Objective 1:Example: Is a Matching Birthday Surprising?
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P(at least one match) = 1 – P(no matches) = 1 – 0.43 = 0.57
Not so surprising when you consider that there are 300 pairs of students who can share the same birthday!
Learning Objective 1:Example: Is a Matching Birthday Surprising?
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Learning Objective 2:Probability Model
We’ve dealt with finding probabilities in many idealized situations
In practice, it’s difficult to tell when outcomes are equally likely or events are independent
In most cases, we must specify a probability model that approximates reality
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Learning Objective 2:Probability Model
A probability model specifies the possible outcomes for a sample space and provides assumptions on which the probability calculations for events composed of these outcomes are based
Probability models merely approximate reality
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Learning Objective 2:Example: Probability Model
Out of the first 113 space shuttle missions there were two failures
What is the probability of at least one failure in a total of 100 missions? P(at least 1 failure)=1-P(0 failures) =1-P(S1 and S2 and S3 … and S100) =1-P(S1)xP(S2)x…xP(S100) =1-[P(S)]100=1-[0.971]100=0.947
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Learning Objective 2:Example: Probability Model
This answer relies on the assumptions of Same success probability on each flight Independence
These assumptions are suspect since other variables (temperature at launch, crew experience, age of craft, etc.) could affect the probability
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Learning Objective 3:Probabilities and Diagnostic Testing
Sensitivity = P(POS|S) Specificity = P(NEG|SC)
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Learning Objective 3:Example: Probabilities and Diagnostic Testing
Random Drug Testing of Air Traffic Controllers
Sensitivity of test = 0.96 Specificity of test = 0.93 Probability of drug use at a given time ≈
0.007 (prevalence of the drug)
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Learning Objective 3:Example: Probabilities and Diagnostic Testing
What is the probability of a positive test result?P(POS)=P(S and POS)+P(SC and POS) P(S and POS)=P(S)P(POS|S)
= 0.007x0.96=0.0067 P(SC and POS)=P(SC)P(POS|SC)
= 0.993x0.07=0.0695 P(POS)=.0067+.0695=0.0762
Even though the prevalence is < 1%, there is an almost 8% chance of the test suggesting drug use!
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Learning Objective 4:Simulation
Some probabilities are very difficult to find with ordinary reasoning. In such cases, we can approximate an answer by simulation.
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Learning Objective 4:Simulation
Carrying out a Simulation: Identify the random phenomenon to be
simulated Describe how to simulate observations Carry out the simulation many times (at least
1000 times) Summarize results and state the conclusion