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1/71 Statistics Inferences About Population Variances.

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1 1/71 Statistics Inferences About Population Variances

2 Contents Inference about a Population Variance n Inferences about the Variances of Two Populations

3 STATISTICS in PRACTICE The U.S. General Accounting Office (GAO) evaluators studied a Department of Interior program established to help clean up the nation’s rivers and lakes. The audits reviewed sample data on the oxygen content, the pH level, and the amount of suspended solids in the effluent.

4 STATISTICS in PRACTICE The hypothesis test was conducted about the variance in pH level for the population of effluent. The population variance in pH level expected at a properly functioning plant. In this chapter you will learn how to conduct statistical inferences about the variances of one and two populations.

5 Inferences About a Population Variance Chi-Square Distribution(  2 ) Interval Estimation of  2 Hypothesis Testing

6 Chi-Square Distribution The chi-square distribution is based on sampling from a normal population. The chi-square distribution is the sum of squared standardized normal random variables such as

7 Chi-Square Distribution where Mean: k Variance: 2k n Probability density function

8 Chi-Square Distribution We can use the chi-square distribution to develop interval estimates and conduct hypothesis tests about a population variance. The sampling distribution of ( n - 1) s 2 /  2 has a chi-square distribution whenever a simple random sample of size n is selected from a normal population.

9 Examples of Sampling Distribution of (n - 1)s 2 /  2 0 0 With 2 degrees of freedom of freedom With 2 degrees of freedom of freedom With 5 degrees of freedom of freedom With 5 degrees of freedom of freedom With 10 degrees of freedom of freedom With 10 degrees of freedom of freedom

10 Chi-Square Distribution n For example, there is a.95 probability of obtaining a (chi-square) value such that We will use the notation to denote the value for the chi-square distribution that provides an area of  to the right of the stated value.

11 Chi-Square Distribution A Chi-Square Distribution with 19 Degrees of Freedom

12 Chi-Square Distribution Selected Values form the Chi-Square Distribution Table

13 Chi-Square Distribution

14 95% of the possible  2 values 95% of the possible  2 values 22 22 0 0.025 Interval Estimation of  2

15 Substituting (n – 1)s 2 /  2 for the  2 we get n Performing algebraic manipulation we get There is a (1 –  ) probability of obtaining a  2 value such that

16 Interval Estimate of a Population Variance Interval Estimation of  2 where the    values are based on a chi-square distribution with n - 1 degrees of freedom and where 1 -  is the confidence coefficient.

17 Interval Estimation of  Interval Estimate of a Population Standard Deviation Taking the square root of the upper and lower limits of the variance interval provides the confidence interval for the population standard deviation.

18 Buyer’s Digest rates thermostats manufactured for home temperature control. In a recent test, 10 thermostats manufactured by The rmoRite were selected and placed in a test room that was maintained at a temperature of 68 o F. The temperature readings of the ten thermostats are shown on the next slide. Interval Estimation of  2 n Example: Buyer’s Digest (A)

19 Interval Estimation of  2 We will use the 10 readings below to develop a 95% confidence interval estimate of the population variance. n Example: Buyer’s Digest (A) Temperature 67.4 67.8 68.2 69.3 69.5 67.0 68.1 68.6 67.9 67.2 Thermostat 1 2 3 4 5 6 7 8 9 10

20 Selected Values from the Chi-Square Distribution Table Our value For n - 1 = 10 - 1 = 9 d.f. and  =.05 Interval Estimation of  2

21 22 22 0 0.025 Area in Upper Tail =.975 2.700 For n - 1 = 10 - 1 = 9 d.f. and  =.05 Interval Estimation of  2

22 Selected Values from the Chi-Square Distribution Table For n - 1 = 10 - 1 = 9 d.f. and  =.05 Our value Interval Estimation of  2

23 22 22 0 0.025 2.700 n - 1 = 10 - 1 = 9 degrees of freedom and  =.05 19.023 Area in Upper Tail =.025 Area in Upper Tail =.025 Interval Estimation of  2

24 Sample variance s 2 provides a point estimate of  2. Interval Estimation of  2.33 <  2 < 2.33 n A 95% confidence interval for the population variance is given by:

25 Left-Tailed Test Hypothesis Testing About a Population Variance n Test Statistic n Hypotheses where is the hypothesized value for the population variance

26 where is based on a chi-square distribution with n - 1 d.f. Left-Tailed Test (continued) Reject H 0 if p-value <  p-Value approach : Critical value approach: n Rejection Rule Reject H 0 if Hypothesis Testing About a Population Variance

27 n Right-Tailed Test n Test Statistic n Hypotheses where is the hypothesized value for the population variance Hypothesis Testing About a Population Variance

28 Reject H 0 if Right-Tailed Test (continued) Reject H 0 if p-value <  p -Value approach: Critical value approach: n Rejection Rule where is based on a chi-square distribution with n - 1 d.f. Hypothesis Testing About a Population Variance

29 n Two-Tailed Test n Test Statistic n Hypotheses where is the hypothesized value for the population variance Hypothesis Testing About a Population Variance

30 Two-Tailed Test (continued) Reject H 0 if p -value <  p-Value approach: Critical value approach: n Rejection Rule Reject H 0 if where and are based on a chi-square distribution with n - 1 d.f. Hypothesis Testing About a Population Variance

31 Recall that Buyer’s Digest is rating ThermoRite thermostats. Buyer’s Digest gives an “acceptable” rating to a thermo- stat with a temperature variance of 0.5 or less. n Example: Buyer’s Digest (B) We will conduct a hypothesis test (with  =.10) to determine whether the ThermoRite thermostat’s temperature variance is “acceptable”. Hypothesis Testing About a Population Variance

32 Using the 10 readings, we will conduct a hypothesis test (with  =.10) to determine whether the ThermoRite thermostat’s temperature variance is “acceptable”. n Example: Buyer’s Digest (B) Temperature 67.4 67.8 68.2 69.3 69.5 67.0 68.1 68.6 67.9 67.2 Thermostat 1 2 3 4 5 6 7 8 9 10 Hypothesis Testing About a Population Variance

33 Hypotheses Reject H 0 if  2 > 14.684 n Rejection Rule Hypothesis Testing About a Population Variance

34 Selected Values from the Chi-Square Distribution Table For n - 1 = 10 - 1 = 9 d.f. and  =.10 Our value Hypothesis Testing About a Population Variance

35 22 22 0 0 14.684 Area in Upper Tail =.10 Area in Upper Tail =.10 n Rejection Region Reject H 0 Hypothesis Testing About a Population Variance

36 Test Statistic Because  2 = 12.6 is less than 14.684, we cannot reject H 0. The sample variance s 2 =.7 is insufficient evidence to conclude that the temperature variance for ThermoRite thermostats is unacceptable. n Conclusion The sample variance s 2 = 0.7 Hypothesis Testing About a Population Variance

37 The rejection region for the ThermoRite thermostat example is in the upper tail; thus, the appropriate p-value is less than.90 (c 2 = 4.168) and greater than.10 (c 2 = 14.684). Using Excel to Conduct a Hypothesis Test about a Population Variance Using the p-Value The sample variance of s 2 =.7 is insufficient evidence to conclude that the temperature variance is unacceptable (>.5). Because the p –value > a =.10, we cannot reject the null hypothesis.

38 Hypothesis Testing About a Population Variance Summary

39 n One-Tailed Test Test Statistic Hypotheses Hypothesis Testing About the Variances of Two Populations Denote the population providing the larger sample variance as population 1.

40 Reject H 0 if F > F  One-Tailed Test (continued) Reject H 0 if p -value <  where the value of F  is based on an F distribution with n 1 - 1 (numerator) and n 2 - 1 (denominator) d.f. p-Value approach: Critical value approach: Rejection Rule Hypothesis Testing About the Variances of Two Populations

41 Two-Tailed Test Test Statistic Hypotheses Denote the population providing the larger sample variance as population 1. Hypothesis Testing About the Variances of Two Populations

42 Two-Tailed Test (continued) Reject H 0 if p-value <  p-Value approach: Critical value approach : Rejection Rule Reject H 0 if F > F  /2 where the value of F  /2 is based on an F distribution with n 1 - 1 (numerator) and n 2 - 1 (denominator) d.f. Hypothesis Testing About the Variances of Two Populations

43 F Distribution

44 Probability density function n where

45 F Distribution n mean for d 2 > 2 n Variance for d 2 > 2

46 F Distribution with (20, 20) Degrees of Freedom

47 F Distribution Selected Values From the F Distribution Table

48 F Distribution Table

49 Buyer’s Digest has conducted the same test, as was described earlier, on another 10 thermostats, this time manufactured by TempKing. The temperature readings of the ten thermostats are listed on the next slide. n Example: Buyer’s Digest (C) Hypothesis Testing About the Variances of Two Populations

50 n Example: Buyer’s Digest (C) We will conduct a hypothesis test with  =.10 to see if the variances are equal for ThermoRite’s thermostats and TempKing’s thermostats. Hypothesis Testing About the Variances of Two Populations

51 n Example: Buyer’s Digest (C) ThermoRite Sample TempKing Sample Temperature 67.4 67.8 68.2 69.3 69.5 67.0 68.1 68.6 67.9 67.2 Thermostat 1 2 3 4 5 6 7 8 9 10 Temperature 67.7 66.4 69.2 70.1 69.5 69.7 68.1 66.6 67.3 67.5 Thermostat 1 2 3 4 5 6 7 8 9 10 Hypothesis Testing About the Variances of Two Populations

52 The F distribution table (on next slide) shows that with with  =.10, 9 d.f. (numerator), and 9 d.f. (denominator), F.05 = 3.18. Hypotheses Reject H 0 if F > 3.18 (Their variances are not equal) (TempKing and ThermoRite thermostats have the same temperature variance) n Rejection Rule Hypothesis Testing About the Variances of Two Populations

53 Selected Values from the F Distribution Table Hypothesis Testing About the Variances of Two Populations

54 Test Statistic TempKing’s sample variance is 1.768 ThermoRite’s sample variance is.700 = 1.768/.700 = 2.53 Hypothesis Testing About the Variances of Two Populations

55 We cannot reject H 0. F = 2.53 < F.05 = 3.18. There is insufficient evidence to conclude that the population variances differ for the two thermostat brands. Conclusion Hypothesis Testing About the Variances of Two Populations

56 Determining and Using the p-Value Because  =.10, we have p-value >  and therefore we cannot reject the null hypothesis. But this is a two-tailed test; after doubling the upper-tail area, the p-value is between.20 and.10. Because F = 2.53 is between 2.44 and 3.18, the area in the upper tail of the distribution is between.10 and.05. Area in Upper Tail.10.05.025.01 F Value (df 1 = 9, df 2 = 9) 2.44 3.18 4.03 5.35 Hypothesis Testing About the Variances of Two Populations

57 Summary

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