EBK STATISTICS FOR BUSINESS & ECONOMICS
EBK STATISTICS FOR BUSINESS & ECONOMICS
12th Edition
ISBN: 9780100460461
Author: Anderson
Publisher: YUZU
bartleby

Concept explainers

bartleby

Videos

Textbook Question
Book Icon
Chapter 7.5, Problem 26E

The mean annual cost of automobile insurance is $939 (CNBC, February 23, 2006). Assume that the standard deviation is σ = $245.

  1. a. What is the probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for each of the following sample sizes: 30, 50, 100, and 400?
  2. b. What is the advantage of a larger sample size when attempting to estimate the population mean?

a.

Expert Solution
Check Mark
To determine

Find the probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for each of the following sample sizes: 30, 50, 100, and 400.

Answer to Problem 26E

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 30 is 0.4246.

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 50 is 0.5284.

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 100 is 0.6922.

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 400 is 0.9586.

Explanation of Solution

Calculation:

The standard deviation is σ=$245 and the mean annual cost of automobile insurance is $939.

Sampling distribution of x¯:

  • The expected value of x¯ is, E(x¯)=μ.
  • The standard deviation of x¯ is

    For finite population, σx¯=NnN1(σn)

    For infinite population, σx¯=σn

  • When the population size is infinite or finite and nN0.05 then the standard deviation of x¯ is σx¯=σn.

The expected value of x¯ is obtained below:

E(x¯)=μ=$939

Thus, the expected value of x¯ is $939.

For sample size 30:

The standard deviation is σx¯=σn

Substitute σ as $245 and n as 30 in the formula,

σx¯=σn=24530=2455.4772=44.73

Thus, the standard deviation of x¯ is $44.73.

Therefore, the sampling distribution of the sample mean x¯ is approximately normal with μ=$939 and σx¯=$44.73.

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 30 is calculated as follows:

P(|x¯|μ±25)=P(μ25x¯μ+25)=P[25σx¯x¯μσx¯25σx¯]=P(2544.73z2544.73)=P(0.56z0.56)=P(z0.56)P(z0.56)

For z=0.56:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value 0.5 in the first column.
  • Locate the value 0.06 in the first row corresponding to the value 0.5 in the first column.
  • The intersecting value of row and column is 0.7123.

For z=0.56:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value –0.5 in the first column.
  • Locate the value 0.06 in the first row corresponding to the value –0.5 in the first column.
  • The intersecting value of row and column is 0.2877.

Therefore,

P(μ25x¯μ+25)=0.71230.2877=0.4246

Thus, the probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 30 is 0.4246.

For sample size 50:

The standard deviation is obtained below:

Substitute σ as $245 and n as 50 in the formula.

σx¯=σn=24550=2457.0711=34.65

Thus, the standard deviation of x¯ is 34.65.

Therefore, the sampling distribution of the sample mean x¯ is approximately normal with μ=$939 and σx¯=$34.65.

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 50 is calculated as follows:

P(|x¯|μ±25)=P(μ25x¯μ+25)=P[25σx¯x¯μσx¯25σx¯]=P(2534.65z2534.65)=P(0.72z0.72)=P(z0.72)P(z0.72)

For z=0.72:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value 0.7 in the first column.
  • Locate the value 0.02 in the first row corresponding to the value 0.7 in the first column.
  • The intersecting value of row and column is 0.7642.

For z=0.72:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value – 0.7 in the first column.
  • Locate the value 0.02 in the first row corresponding to the value –0.7 in the first column.
  • The intersecting value of row and column is 0.2358.

Therefore,

P(μ25x¯μ+25)=0.76420.2358=0.5284

Thus, the probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 50 is 0.5284.

For sample size 100:

The standard deviation is obtained below:

Substitute σ as $245 and n as 100 in the formula.

σx¯=σn=245100=24510=24.5

Thus, the standard deviation of x¯ is $24.5.

The sampling distribution of the sample mean x¯ is approximately normal with μ=$939 and σx¯=$24.5.

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 100 is calculated as follows:

P(|x¯|μ±25)=P(μ25x¯μ+25)=P[25σx¯x¯μσx¯25σx¯]=P(2524.5z2524.5)=P(1.02z1.02)=P(z1.02)P(z1.02)

For z=1.02:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value 1.0 in the first column.
  • Locate the value 0.02 in the first row corresponding to the value 1.0 in the first column.
  • The intersecting value of row and column is 0.8461.

For z=1.02:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value –1.0 in the first column.
  • Locate the value 0.02 in the first row corresponding to the value –1.0 in the first column.
  • The intersecting value of row and column is 0.1539.

Therefore,

P(μ25x¯μ+25)=0.84610.1539=0.6922

Thus, the probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 100 is 0.6922.

For sample size 400:

The standard deviation is obtained below:

Substitute σ as $245 and n as 400 in the formula.

σx¯=σn=245400=24520=12.25

Thus, the standard deviation of x¯ is $12.25.

The sampling distribution of the sample mean x¯ is approximately normal with μ=$939 and σx¯=$12.25.

The probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 400 is calculated as follows:

P(|x¯|μ±25)=P(μ25x¯μ+25)=P[25σx¯x¯μσx¯25σx¯]=P(2512.25z2512.25)=P(2.04z2.04)=P(z2.04)P(z2.04)

For z=2.04:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value 2.0 in the first column.
  • Locate the value 0.04 in the first row corresponding to the value 2.0 in the first column.
  • The intersecting value of row and column is 0.9793.

For z=2.04:

From Table 1: Cumulative probabilities for the standard normal distribution,

  • Locate the value –2.0 in the first column.
  • Locate the value 0.04 in the first row corresponding to the value –2.0 in the first column.
  • The intersecting value of row and column is 0.0207.

Therefore,

P(μ25x¯μ+25)=0.97930.0207=0.9586

Thus, the probability that a sample of automobile insurance policies will have a sample mean within $25 of the population mean for the sample size 400 is 0.9586.

b.

Expert Solution
Check Mark
To determine

Explain the advantage of a larger sample size to estimate the population mean.

Explanation of Solution

From part a, it was observed that the probability of being with ±25 of μ is from 0.4246 for sample size 30 to 0.9586 for sample size 400.

Hence, it can be concluded that as the sample size increases, the probability becomes closer to 1.

Want to see more full solutions like this?

Subscribe now to access step-by-step solutions to millions of textbook problems written by subject matter experts!
Students have asked these similar questions
Homework Let X1, X2, Xn be a random sample from f(x;0) where f(x; 0) = (-), 0 < x < ∞,0 € R Using Basu's theorem, show that Y = min{X} and Z =Σ(XY) are indep. -
Homework Let X1, X2, Xn be a random sample from f(x; 0) where f(x; 0) = e−(2-0), 0 < x < ∞,0 € R Using Basu's theorem, show that Y = min{X} and Z =Σ(XY) are indep.
An Arts group holds a raffle.  Each raffle ticket costs $2 and the raffle consists of 2500 tickets.  The prize is a vacation worth $3,000.    a. Determine your expected value if you buy one ticket.     b. Determine your expected value if you buy five tickets.     How much will the Arts group gain or lose if they sell all the tickets?

Chapter 7 Solutions

EBK STATISTICS FOR BUSINESS & ECONOMICS

Ch. 7.3 - The following data are from a simple random...Ch. 7.3 - A survey question for a sample of 150 individuals...Ch. 7.3 - A sample of 5 months of sales data provided the...Ch. 7.3 - BusinessWeek published information on 283 equity...Ch. 7.3 - Many drugs used to treat cancer are expensive....Ch. 7.3 - A sample of 426 U.S. adults age 50 and older were...Ch. 7.3 - The American Association of Individual Investors...Ch. 7.5 - A population has a mean of 200 and a standard...Ch. 7.5 - A population has a mean of 200 and a standard...Ch. 7.5 - Assume the population standard deviation is = 25....Ch. 7.5 - Suppose a random sample of size 50 is selected...Ch. 7.5 - Refer to the EAI sampling problem. Suppose a...Ch. 7.5 - In the EAI sampling problem (see Figure 7.5), we...Ch. 7.5 - Barrons reported that the average number of weeks...Ch. 7.5 - The College Board reported the following mean...Ch. 7.5 - The mean annual cost of automobile insurance is...Ch. 7.5 - The Economic Policy Institute periodically issues...Ch. 7.5 - The average score for male golfers is 95 and the...Ch. 7.5 - The mean preparation fee HR Block charged retail...Ch. 7.5 - To estimate the mean age for a population of 4000...Ch. 7.6 - A sample of size 100 is selected from a population...Ch. 7.6 - A population proportion is .40. A sample of size...Ch. 7.6 - Assume that the population proportion is .55....Ch. 7.6 - The population proportion is .30. What is the...Ch. 7.6 - The president of Doerman Distributors, Inc.,...Ch. 7.6 - The Wall Street Journal reported that the age at...Ch. 7.6 - People end up tossing 12% of what they buy at the...Ch. 7.6 - Forty-two percent of primary care doctors think...Ch. 7.6 - In 2008 the Better Business Bureau settled 75% of...Ch. 7.6 - The Grocery Manufacturers of America reported that...Ch. 7.6 - The Food Marketing Institute shows that 17% of...Ch. 7 - U.S. News World Report publishes comprehensive...Ch. 7 - The latest available data showed health...Ch. 7 - Foot Locker uses sales per square foot as a...Ch. 7 - The mean television viewing time for Americans is...Ch. 7 - After deducting grants based on need, the average...Ch. 7 - Three firms carry inventories that differ in size....Ch. 7 - A researcher reports survey results by stating...Ch. 7 - A production process is checked periodically by a...Ch. 7 - About 28% of private companies are owned by women...Ch. 7 - A market research firm conducts telephone surveys...Ch. 7 - Advertisers contract with Internet service...Ch. 7 - The proportion of individuals insured by the...Ch. 7 - Lori Jeffrey is a successful sales representative...
Knowledge Booster
Background pattern image
Statistics
Learn more about
Need a deep-dive on the concept behind this application? Look no further. Learn more about this topic, statistics and related others by exploring similar questions and additional content below.
Similar questions
SEE MORE QUESTIONS
Recommended textbooks for you
Text book image
Glencoe Algebra 1, Student Edition, 9780079039897...
Algebra
ISBN:9780079039897
Author:Carter
Publisher:McGraw Hill
Text book image
Big Ideas Math A Bridge To Success Algebra 1: Stu...
Algebra
ISBN:9781680331141
Author:HOUGHTON MIFFLIN HARCOURT
Publisher:Houghton Mifflin Harcourt
Statistics 4.1 Point Estimators; Author: Dr. Jack L. Jackson II;https://www.youtube.com/watch?v=2MrI0J8XCEE;License: Standard YouTube License, CC-BY
Statistics 101: Point Estimators; Author: Brandon Foltz;https://www.youtube.com/watch?v=4v41z3HwLaM;License: Standard YouTube License, CC-BY
Central limit theorem; Author: 365 Data Science;https://www.youtube.com/watch?v=b5xQmk9veZ4;License: Standard YouTube License, CC-BY
Point Estimate Definition & Example; Author: Prof. Essa;https://www.youtube.com/watch?v=OTVwtvQmSn0;License: Standard Youtube License
Point Estimation; Author: Vamsidhar Ambatipudi;https://www.youtube.com/watch?v=flqhlM2bZWc;License: Standard Youtube License