3.4 Contingency tables and probability trees

Introductory statistics Page 1 / 6

Contingency tables

A contingency table provides a way of portraying data that can facilitate calculating probabilities. The table helps in determining conditional probabilities quite easily. The table displays sample values in relation to two different variables that may be dependent or contingent on one another. Later on, we will use contingency tables again, but in another manner.

Suppose a study of speeding violations and drivers who use cell phones produced the following fictional data:

	Speeding violation in the last year	No speeding violation in the last year	Total
Cell phone user	25	280	305
Not a cell phone user	45	405	450
Total	70	685	755

The total number of people in the sample is 755. The row totals are 305 and 450. The column totals are 70 and 685. Notice that 305 + 450 = 755 and 70 + 685 = 755.

Calculate the following probabilities using the table.

a. Find P (Person is a car phone user).

a. $\frac{number of car phone users}{total number in study} = \frac{305}{755}$

b. Find P (person had no violation in the last year).

b. $\frac{number that had no violation}{total number in study} = \frac{685}{755}$

c. Find P (Person had no violation in the last year $\cap$ was a car phone user).

c. $\frac{280}{755}$

d. Find P (Person is a car phone user $\cup$ person had no violation in the last year).

d. $(\frac{305}{755} + \frac{685}{755}) - \frac{280}{755} = \frac{710}{755}$

e. Find P (Person is a car phone user $|$ person had a violation in the last year).

e. $\frac{25}{70}$ (The sample space is reduced to the number of persons who had a violation.)

f. Find P (Person had no violation last year $|$ person was not a car phone user)

f. $\frac{405}{450}$ (The sample space is reduced to the number of persons who were not car phone users.)

Try it

[link] shows the number of athletes who stretch before exercising and how many had injuries within the past year.

	Injury in last year	No injury in last year	Total
Stretches	55	295	350
Does not stretch	231	219	450
Total	286	514	800

What is P (athlete stretches before exercising)?
What is P (athlete stretches before exercising $|$ no injury in the last year)?

P (athlete stretches before exercising) = $\frac{350}{800}$ = 0.4375
P (athlete stretches before exercising $|$ no injury in the last year) = $\frac{295}{514}$ = 0.5739

[link] shows a random sample of 100 hikers and the areas of hiking they prefer.

Hiking area preference
Sex	The Coastline	Near Lakes and Streams	On Mountain Peaks	Total
Female	18	16	___	45
Male	___	___	14	55
Total	___	41	___	___

a. Complete the table.

Hiking area preference
Sex	The Coastline	Near Lakes and Streams	On Mountain Peaks	Total
Female	18	16	11	45
Male	16	25	14	55
Total	34	41	25	100

b. Are the events "being female" and "preferring the coastline" independent events?

Let F = being female and let C = preferring the coastline.

Find $P (F \cap C)$ .
Find P ( F ) P ( C )

Are these two numbers the same? If they are, then F and C are independent. If they are not, then F and C are not independent.

$P (F \cap C) = \frac{18}{100}$ = 0.18
P ( F ) P ( C ) = $(\frac{45}{100}) (\frac{34}{100})$ = (0.45)(0.34) = 0.153

$P (F \cap C)$ ≠ P ( F ) P ( C ), so the events F and C are not independent.

c. Find the probability that a person is male given that the person prefers hiking near lakes and streams. Let M = being male, and let L = prefers hiking near lakes and streams.

What word tells you this is a conditional?
Fill in the blanks and calculate the probability: P (___ $|$ ___) = ___.
Is the sample space for this problem all 100 hikers? If not, what is it?

The word 'given' tells you that this is a conditional.
P ( M $|$ L ) = $\frac{25}{41}$
No, the sample space for this problem is the 41 hikers who prefer lakes and streams.

d. Find the probability that a person is female or prefers hiking on mountain peaks. Let F = being female, and let P = prefers mountain peaks.

Find P ( F ).
Find P ( P ).
Find $P (F \cap P)$ .
Find $P (F \cup P)$ .

P ( F ) = $\frac{45}{100}$
P ( P ) = $\frac{25}{100}$
$P (F \cap P)$ = $\frac{11}{100}$
$P (F \cup P)$ = $\frac{45}{100}$ + $\frac{25}{100}$ - $\frac{11}{100}$ = $\frac{59}{100}$

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Source: OpenStax, Introductory statistics. OpenStax CNX. Aug 09, 2016 Download for free at http://legacy.cnx.org/content/col11776/1.26

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