Bayes' Theorem, Lecture notes of Probability and Statistics

This document introduces the concept of conditional probability and extends the discussion to include applications of Bayes' theorem. The definitions of prior probability and posterior probability are explained with an example. a formula for finding conditional probability and an intuitive approach for finding it. Sequential events and the use of new information to revise the probability of the initial event are discussed. useful for students studying probability and statistics.

Typology: Lecture notes

2022/2023

Uploaded on 05/11/2023

daryth
daryth 🇺🇸

4.5

(2)

232 documents

1 / 9

Toggle sidebar

This page cannot be seen from the preview

Don't miss anything!

bg1
1
Bayes' Theorem
by Mario F. Triola
The concept of conditional probability is introduced in Elementary Statistics. We noted
that the conditional probability of an event is a probability obtained with the additional
information that some other event has already occurred. We used P(B|A) to denoted the
conditional probability of event B occurring, given that event A has already occurred. The
following formula was provided for finding P(B|A):
P B A P A B
P A
( | ) ( )
( )
=and
In addition to the above formal rule, the textbook also included this "intuitive approach
for finding a conditional probability":
The conditional probability of B given A can be found by assuming that event
A has occurred and, working under that assumption, calculating the probability
that event B will occur.
In this section we extend the discussion of conditional probability to include applications
of Bayes' theorem (or Bayes' rule), which we use for revising a probability value based
on additional information that is later obtained. One key to understanding the essence of
Bayes' theorem is to recognize that we are dealing with sequential events, whereby new
additional information is obtained for a subsequent event, and that new information is
used to revise the probability of the initial event. In this context, the terms prior
probability and posterior probability are commonly used.
Definitions
A prior probability is an initial probability value originally obtained before any
additional information is obtained.
A posterior probability is a probability value that has been revised by using additional
information that is later obtained.
Example 1
The Gallup organization randomly selects an adult American for a survey about credit
card usage. Use subjective probabilities to estimate the following.
a. What is the probability that the selected subject is a male?
b. After selecting a subject, it is later learned that this person was smoking a cigar
during the interview. What is the probability that the selected subject is a male?
c. Which of the preceding two results is a prior probability? Which is a posterior
probability?
pf3
pf4
pf5
pf8
pf9

Partial preview of the text

Download Bayes' Theorem and more Lecture notes Probability and Statistics in PDF only on Docsity!

Bayes' Theorem

by Mario F. Triola

The concept of conditional probability is introduced in Elementary Statistics. We noted

that the conditional probability of an event is a probability obtained with the additional

information that some other event has already occurred. We used P ( B | A ) to denoted the

conditional probability of event B occurring, given that event A has already occurred. The

following formula was provided for finding P ( B | A ):

P B A

P A B

P A

and

In addition to the above formal rule, the textbook also included this "intuitive approach

for finding a conditional probability":

The conditional probability of B given A can be found by assuming that event

A has occurred and, working under that assumption, calculating the probability

that event B will occur.

In this section we extend the discussion of conditional probability to include applications

of Bayes' theorem (or Bayes' rule ), which we use for revising a probability value based

on additional information that is later obtained. One key to understanding the essence of

Bayes' theorem is to recognize that we are dealing with sequential events, whereby new

additional information is obtained for a subsequent event, and that new information is

used to revise the probability of the initial event. In this context, the terms prior

probability and posterior probability are commonly used.

Definitions

A prior probability is an initial probability value originally obtained before any

additional information is obtained.

A posterior probability is a probability value that has been revised by using additional

information that is later obtained.

Example 1

The Gallup organization randomly selects an adult American for a survey about credit

card usage. Use subjective probabilities to estimate the following.

a. What is the probability that the selected subject is a male?

b. After selecting a subject, it is later learned that this person was smoking a cigar

during the interview. What is the probability that the selected subject is a male?

c. Which of the preceding two results is a prior probability? Which is a posterior

probability?

Solution

a. Roughly half of all Americans are males, so we estimate the probability of

selecting a male subject to be 0.5. Denoting a male by M, we can express this

probability as follows: P (M) = 0.5.

b. Although some women smoke cigars, the vast majority of cigar smokers are

males. A reasonable guess is that 85 % of cigar smokers are males. Based on this

additional subsequent information that the survey respondent was smoking a

cigar, we estimate the probability of this person being a male as 0. 85. Denoting a

male by M and denoting a cigar smoker by C, we can express this result as

follows: P (M | C) = 0. 85.

c. In part (a), the value of 0.5 is the initial probability, so we refer to it as the prior

probability. Because the probability of 0. 85 in part (b) is a revised probability

based on the additional information that the survey subject was smoking a cigar,

this value of 0. 85 is referred to a posterior probability.

The Reverend Thomas Bayes [1701 (approximately) − 1761] was an English

minister and mathematician. Although none of his work was published during his

lifetime, later (posterior?) publications included the following theorem (or rule) that he

developed for determining probabilities of events by incorporating information about

subsequent events.

Bayes' Theorem

The probability of event A, given that event B has subsequently occurred, is

P A B

P A P B A

P A P B A P A P B A

[ ( ) ( | )] [ ( ) ( | )]

That's a formidable expression, but we will simplify its calculation. See the following

example, which illustrates use of the above expression, but also see the alternative

method based on a more intuitive application of Bayes' theorem.

Example 2

In Orange County, 51% of the adults are males. (It doesn't take too much advanced

mathematics to deduce that the other 49% are females.) One adult is randomly selected

for a survey involving credit card usage.

a. Find the prior probability that the selected person is a male.

b. It is later learned that the selected survey subject was smoking a cigar. Also, 9.5%

of males smoke cigars, whereas 1.7% of females smoke cigars (based on data

from the Substance Abuse and Mental Health Services Administration). Use this

additional information to find the probability that the selected subject is a male.

Intuitive Bayes Theorem

The preceding solution illustrates the application of Bayes' theorem with its calculation

using the formula. Unfortunately, that calculation is complicated enough to create an

abundance of opportunities for errors and/or incorrect substitution of the involved

probability values. Fortunately, here is another approach that is much more intuitive and

easier:

Assume some convenient value for the total of all items involved, then

construct a table of rows and columns with the individual cell frequencies

based on the known probabilities.

For the preceding example, simply assume some value for the adult population of

Orange County, such as 100,000, then use the given information to construct a table, such

as the one shown below.

Finding the number of males who smoke cigars: If 51% of the 100,000 adults are

males, then there are 51,000 males. If 9.5% of the males smoke cigars, then the number

of cigar−smoking males is 9.5% of 51,000, or 0.095 × 51,000 = 4845. See the entry of

4845 in the table. The other males who do not smoke cigars must be 51,000 − 4845 =

46,155. See the value of 46,155 in the table.

Finding the number of females who smoke cigars: Using similar reasoning, 49%

of the 100,000 adults are females, so the number of females is 49,000. Given that 1.7% of

the females smoke cigars, the number of cigar−smoking females is 0.017 × 49,000 =

  1. The number of females who do not smoke cigars is 49,000 − 833 = 48,167. See the

entries of 833 and 48,167 in the table.

C

(Cigar Smoker)

C

(Not a Cigar Smoker)

Total

M (male) 4845 46,155 51,

M (female)

Total 5678 94,322 100,

The above table involves relatively simple arithmetic. Simply partition the

assumed population into the different cell categories by finding suitable percentages.

Now we can easily address the key question as follows: To find the probability of

getting a male subject, given that the subject smokes cigars, simply use the same

conditional probability described in the textbook. To find the probability of getting a

male given that the subject smokes, restrict the table to the column of cigar smokers, then

find the probability of getting a male in that column. Among the 5678 cigar smokers,

there are 4845 males, so the probability we seek is 4845/5678 = 0.85329341. That is,

P (M | C) = 4845/5678 = 0.85329341 = 0.853 (rounded).

Bayes' Theorem Generalized

The preceding formula for Bayes' theorem and the preceding example use exactly two

categories for event A (male and female), but the formula can be extended to include

more than two categories. The following example illustrates this extension and it also

illustrates a practical application of Bayes' theorem to quality control in industry. When

dealing with more than the two events of A and A, we must be sure that the multiple

events satisfy two important conditions:

  1. The events must be disjoint (with no overlapping).
  2. The events must be exhaustive , which means that they combine to include

all possibilities.

Example 3

An aircraft emergency locator transmitter (ELT) is a device designed to transmit a signal

in the case of a crash. The Altigauge Manufacturing Company makes 80% of the ELTs,

the Bryant Company makes 15% of them, and the Chartair Company makes the other

5%. The ELTs made by Altigauge have a 4% rate of defects, the Bryant ELTs have a 6%

rate of defects, and the Chartair ELTs have a 9% rate of defects (which helps to explain

why Chartair has the lowest market share).

a. If an ELT is randomly selected from the general population of all ELTs, find the

probability that it was made by the Altigauge Manufacturing Company.

b. If a randomly selected ELT is then tested and is found to be defective, find the

probability that it was made by the Altigauge Manufacturing Company.

Solution

We use the following notation:

A = ELT manufactured by Altigauge

B = ELT manufactured by Bryant

C = ELT manufactured by Chartair

D = ELT is defective

D = ELT is not defective (or it is good)

a. If an ELT is randomly selected from the general population of all ELTs, the

probability that it was made by Altigauge is 0.8 (because Altigauge manufactures

80% of them).

b. If we now have the additional information that the ELT was tested and was found

to be defective, we want to revise the probability from part (a) so that the new

information can be used. We want to find the value of P (A|D), which is the

probability that the ELT was made by the Altigauge company given that it is

defective. Based on the given information, we know these probabilities:

Exercises

Pregnancy Test Results. In Exercises 1 and 2, refer to the results summarized in the

table below.

Positive Test Result

(Pregnancy is indicated)

Negative Test Result

(Pregnancy is not indicated)

Subject is Pregnant 80 5

Subject is Not Pregnant 3 11

1. a. If one of the 99 test subjects is randomly selected, what is the probability of

getting a subject who is pregnant?

b. A test subject is randomly selected and is given a pregnancy test. What is the

probability of getting a subject who is pregnant, given that the test result is

positive?

2. a. One of the 99 test subjects is randomly selected. What is the probability of getting

a subject who is not pregnant?

b. A test subject is randomly selected and is given a pregnancy test. What is the

probability of getting a subject who is not pregnant, given that the test result is

negative?

3. Survey Results In Orange County, 51% of the adults are males. One adult is

randomly selected for a survey involving credit card usage. (See Example 2 in this

section.)

a. Find the prior probability that the selected person is a female.

b. It is later learned that the selected survey subject was smoking a cigar. Also, 9.5%

of males smoke cigars, whereas 1.7% of females smoke cigars (based on data

from the Substance Abuse and Mental Health Services Administration). Use this

additional information to find the probability that the selected subject is a female.

4. Emergency Locator Transmitters An aircraft emergency locator transmitter

(ELT) is a device designed to transmit a signal in the case of a crash. The

Altigauge Manufacturing Company makes 80% of the ELTs, the Bryant

Company makes 15% of them, and the Chartair Company makes the other 5%.

The ELTs made by Altigauge have a 4% rate of defects, the Bryant ELTs have a

6% rate of defects, and the Chartair ELTs have a 9% rate of defects. (These are

the same results from Example 3 in this section.)

a. Find the probability of randomly selecting an ELT and getting one manufactured

by the Bryant Company.

b. If an ELT is randomly selected and tested, find the probability that it was

manufactured by the Bryant Company if the test indicates that the ELT is

defective.

5. Emergency Locator Transmitters Use the same ELT data from Exercise 4.

a. Find the probability of randomly selecting an ELT and getting one manufactured

by the Chartair Company.

b. An ELT is randomly selected and tested. If the test indicates that the ELT is

defective, find the probability that it was manufactured by the Chartair Company.

6. Emergency Locator Transmitters Use the same ELT data from Exercise 4. An

ELT is randomly selected and tested. If the test indicates that the ELT is not

defective, find the probability that it is from the Altigauge Company.

7. Pleas and Sentences In a study of pleas and prison sentences, it is found that

45% of the subjects studied were sent to prison. Among those sent to prison, 40%

chose to plead guilty. Among those not sent to prison, 55% chose to plead guilty.

a. If one of the study subjects is randomly selected, find the probability of getting

someone who was not sent to prison.

b. If a study subject is randomly selected and it is then found that the subject entered

a guilty plea, find the probability that this person was not sent to prison.

8. Pleas and Sentences Use the same data given in Exercise 7.

a. If one of the study subjects is randomly selected, find the probability of getting

someone who was sent to prison.

b. If a study subject is randomly selected and it is then found that the subject entered

a guilty plea, find the probability that this person was sent to prison.

9. HIV The New York State Health Department reports a 10% rate of the HIV virus

for the “at-risk” population. Under certain conditions, a preliminary screening test

for the HIV virus is correct 95% of the time. (Subjects are not told that they are

HIV infected until additional tests verify the results.) If someone is randomly

selected from the at-risk population, what is the probability that they have the

HIV virus if it is known that they have tested positive in the initial screening?

10. HIV Use the same data from Exercise 9. If someone is randomly selected from

the at-risk population, what is the probability that they have the HIV virus if it is

known that they have tested negative in the initial screening?

11. Extending Bayes' Theorem Example 3 in this section included an extension of

Bayes' theorem to include three events, denoted by A, B, C. Write an expression

that extends Bayes' theorem so that it can be used to find P (A|Z), assuming that

the initial event can occur in one of four ways: A, B, C, D.

12. Extensions of Bayes' Theorem In Example 2, we used only the initial events of

A and A. In Example 3, we used initial events of A, B, and C. If events B and C

in Example 3 are combined and denoted as A, we can find P (A|D) using the

simpler format of Bayes' theorem given in Example 2. How would the resulting

value of P (A|D) in Example 3 be affected by using this simplified approach?