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Chapter 8: Estimation

Understandable Statistics Eighth Edition By Brase and Brase Prepared by: Lynn Smith Gloucester County College Edited by: Jeff, Yann, Julie, and Olivia. Chapter 8: Estimation. Section 8.1. Estimating μ When σ Is Known. Focus Points.

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Chapter 8: Estimation

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  1. Understandable StatisticsEighth Edition By Brase and BrasePrepared by: Lynn SmithGloucester County CollegeEdited by: Jeff, Yann, Julie, and Olivia Chapter 8: Estimation

  2. Section 8.1 Estimating μ When σ Is Known

  3. Focus Points • Explain the meaning of confidence level, error of estimate, and critical value. • Find the critical value corresponding to a given confidence level. • Compute confidence intervals for μ when σ is known. Interpret the results.

  4. Statistics Quote “There are three kinds of lies—lies, damned lies, and statistics.”  —Benjamin Disraeli

  5. Assumptions About the Random Variable x • We have a simple random sample of size n drawn from a population of x values. • The value of sigma, the population standard deviation of x, is known. • If the x distribution is normal, then our methods work for any sample size n. • If x has an unknown distribution, then we require a sample size n≥ 30. However, if the x distribution is distinctly skewed and definitely not mound-shaped, a sample size of 50 or even 100 or higher may be necessary.

  6. Point Estimate an estimate of a population parameter given by a single number

  7. Examples of Point Estimates

  8. Examples of Point Estimates • is used as a point estimate for .

  9. Examples of Point Estimates • is used as a point estimate for . • s is used as a point estimate for .

  10. Margin of Error the magnitude of the difference between the point estimate and the true parameter value

  11. The margin of error using as a point estimate for  is

  12. Confidence Level • A confidence level, c, is a measure of the degree of assurance we have in our results. • The value of c may be any number between zero and one. • Typical values for c include 0.90, 0.95, and 0.99.

  13. Critical Value for a Confidence Level, c the value zc such that the area under the standard normal curve falling between – zc and zc is equal to c.

  14. Critical Value for a Confidence Level, c P(– zc < z < zc ) = c

  15. Area Between –z.99 and z.99 is .99

  16. – z.90 0 z.90 Find z0.90 such that 90% of the area under the normal curve lies between z-0.90 and z0.90. P(-z0.90 < z < z0.90 ) = 0.90 .90

  17. – z.90 0 z.90 Find z0.90 such that 90% of the area under the normal curve lies between z-0.90 and z0.90. • P(0< z < z0.90 ) = 0.90/2 = 0.4500 .4500

  18. – z.90 0 z.90 Find z0.90 such that 90% of the area under the normal curve lies between z-0.90 and z0.90. • P( z < z0.90 ) = .5 + 0.4500 = .9500 .9500

  19. Find z0.90 such that 90% of the area under the normal curve lies between z-0.90 and z0.90. • According to Table 5a in Appendix II, 0.9500 lies exactly halfway between two area values in the table (.9495 and .9505). • Averaging the z values associated with these areas gives z0.90 = 1.645.

  20. Common Levels of Confidence and Their Corresponding Critical Values

  21. More Confidence Values

  22. C Confidence Interval for μ An interval computed from sample data in such a way that c is the probability of generating an interval containing the actual value of μ

  23. Confidence Interval for the Mean of Large Samples (n  30)

  24. Confidence Interval for the Mean of Large Samples (n  30)

  25. Confidence Interval for the Mean of Large Samples (n  30)

  26. Confidence Interval for the Mean of Large Samples (n  30)

  27. Confidence Interval for the Mean of Large Samples (n  30)

  28. Confidence Interval for the Mean of Large Samples (n  30)

  29. Create a 95% confidence interval for the mean driving time between Philadelphia and Boston. Assume that the mean driving time of 64 trips was 6.4 hours with a standard deviation of 0.9 hours.

  30. = 6.4 hourss = 0.9 hoursc = 95%, so zc = 1.96n = 64

  31. = 6.4 hourss = 0.9 hoursApproximate  as s = 0.9 hours. 95% Confidence interval will be from

  32. = 6.4 hourss = 0.9 hoursc = 95%, so zc = 1.96n = 64

  33. 95% Confidence Interval: 6.4 – .2205 <  < 6.4 + .2205 6.1795 <  < 6.6205 We are 95% sure that the true time is between 6.18 and 6.62 hours.

  34. Calculator Instructions CONFIDENCE INTERVALS FOR A POPULATION MEAN The TI-83 Plus and TI-84 Plus fully support confidence intervals. To access the confidence interval choices, press Stat and select TESTS. The confidence interval choices are found in items 7 through B.

  35. Example (σis known with a Large Sample) Suppose a random sample of 250 credit card bills showed an average balance of $1200. Also assume that the population standard deviation is $350. Find a 95% confidence interval for the population mean credit card balance.

  36. Example (σ is known) • Since σ is known and we have a large sample, we use the normal distribution. Select 7:ZInterval. • In this example, we have summary statistics, so we will select the STATS option for input. We enter the value of σ, the value of x and the sample size n. Use 0.95 for the C-Level.

  37. Example (σ is known) • Highlight Calculate and press Enter to get the results. Notice that the interval is given using standard mathematical notation for an interval. The interval for μ goes from $1156.6 to $1232.4.

  38. Section 8.1, Problem 3 Diagnostic Tests: Plasma Volume Total plasma volume is important in determining the required plasma the overall health and physical activity of an individual. (Reference: See Problem 2.) Suppose that a random sample of 45 male firefighters are tested and that they have a plasma volume sample mean of x-bar = 37.5 mL/kg (milliliters plasma per kilogram body weight). Assume that σ = 7.50 mL/kg for the distribution of blood plasma. (a) Find a 99% confidence interval for the population mean blood plasma volume in male firefighters. What is the margin of error? (b) What conditions are necessary for your calculations? (c) Give a brief interpretation of your results in the context of this problem.

  39. Solution

  40. Section 8.1, Problem 7 Salaries: College Administrators How much do college administrators (not teachers or service personnel) make each year? Suppose you read the local newspaper and find that the average annual salary of administrators in the local college is x-bar = $58,940. Assume that σ is known to be $18,490 for college administrator salaries (Reference: The Chronicle of Higher Education). (a) Suppose that x-bar = $58,940 is based on a random sample of n = 36 administrators. Find a 90% confidence interval for the population mean annual salary of local college administrators. What is the margin of error?

  41. Section 8.1, Problem 7 (b)   Suppose that x-bar = $58,940 is based on a random sample of n = 64 administrators. Find a 90% confidence interval for the population mean annual salary of local college administrators. What is the margin of error? (c)   Suppose that x-bar = $58,940 is based on a random sample of n = 121 administrators. Find a 90% confidence interval for the population mean annual salary of local college administrators. What is the margin of error? (d)   Compare the margins of error for parts (a) through (c). As the sample size increases, does the margin of error decrease? (e)   Compare the lengths of the confidence intervals for parts (a) through (c). As the sample size increased, does the length of a 90% confidence interval decrease?

  42. Solution

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