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Week 5 Dr. Jenne Meyer.  Article review 5-Step Hypothesis Testing Procedure Step 1: Set up the null and alternative hypotheses. Step 2: Pick the level.

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Presentation on theme: "Week 5 Dr. Jenne Meyer.  Article review 5-Step Hypothesis Testing Procedure Step 1: Set up the null and alternative hypotheses. Step 2: Pick the level."— Presentation transcript:

1 Week 5 Dr. Jenne Meyer

2  Article review

3 5-Step Hypothesis Testing Procedure Step 1: Set up the null and alternative hypotheses. Step 2: Pick the level of significance (value of  ) and find the rejection region. Step 3: Calculate the test statistics. Step 4: Decide whether or not to reject the null hypothesis. Step 5: Interpret the statistical decision in terms of the stated problem.

4 Two-tail test H0:  = 750 HA:   750 Lower-tail testUpper-tail test H0:   700H0:   800 HA:  800

5  One-tailedTwo-tailed /2/2 /2/2 The Rejection Region is the range of values of the test statistics that will lead you to reject the null hypothesis.

6  For a large sample:  For a small sample: **At least 30 units

7 Apply hypothesis testing to different populations and samples in business research situations  Test of single population, small sample size  Test of a single proportion  Test of two populations, large sample size  Test of two populations, small sample size  Test for difference in two population proportions The 5-Step Hypothesis Testing Procedure is the same for all these processes.

8  For a small sample:  Small sample and unknown σ  Calculations are identical to those for z  Becomes identical to z for n > 30  Uses degrees of freedom: df = n - 1

9 Review t-table Common Values of  and df and the Corresponding t-Values

10 Example A State Highway Patrol periodically samples vehicle speeds at various locations on a particular roadway. The sample of vehicle speeds is used to test the hypothesis H0: m < 65mph The locations where H0 is rejected (average speed exceeds 65mph) are the best for radar traps. At Location X, a sample of 16 vehicles shows a mean speed of 68.2 mph with a standard deviation of 3.8 mph. Use an level of significance=.05 to test the hypothesis.

11  Example, cont.  =.05 d.f.=16-1=15, t a = 1.753 n = 16 = 68.2 mph s = 3.8 mph Rejection Region t 1.753 Since 3.37 > 1.753, we reject H 0. Conclusion: We are 95% confident that the mean speed of vehicles at Location X is greater than 65 mph. Location X is a good candidate for a radar trap. H 0 :  < 65mph H A :  > 65mph

12  Use if concerned with a proportion of the population, , that have a particular characteristic Can be used with nominal data Can be used with nominal data Use the same 5-Step Hypothesis Testing Procedures Use the same 5-Step Hypothesis Testing Procedures Test Statistic calculated Test Statistic calculated Z = p -   (1-  ) / n √

13  Example  For a Christmas and New Year’s week, the National Safety Council estimated that 500 people would be killed and 25,000 injured on the nation’s roads. The NSC claimed that 50% of the accidents would be caused by drunk driving.  A sample of 120 accidents showed that 67 were caused by drunk driving. Use these data to test the NSC’s claim with a = 0.05.

14  Example, cont. H 0 :  =.5 H A : .5 (67/120) -.5 = 1.278.5(1 -.5) 120  =.05 Rejection Region p = 67/120 n = 120 Z = Since –1.96 < 1.278 < 1.96, we do not reject H 0. Conclusion: There is insufficient evidence to suggest that the population proportion of accidents caused by drunk driving is different from 50%

15  Example, cont. Rejection Region Z 1.645 250 )1036.1(. 300 )1036.1(. 0880.1167. - + - - = Since 1.099 < 1.645, we do not reject H 0. Conclusion: There is insufficient evidence to suggest that there is an difference between the proportion of unmarried workers missing more than 5 days of work than the proportion of married ones = 1.099

16  Often we are interested in comparing two different, independent populations Figure 13.1 Two Populations and Two Samples

17  When comparing two different, independent populations the Null Hypothesis takes on the form: H 0 :  s -  p = 0 H 0 :  s =  p H 0 :  s ≤  p

18  When comparing two different, independent populations the with large n, the test statistic looks like If population std. dev. are unknown, use s 1 and s 2 instead of σ ’s

19  Example A study was conducted to compare the mean years of service for those retiring in 1979 with those retiring last year at Acme Manufacturing Co. At the.01 significance level can we conclude that the workers retiring last year gave more service based on the following sample data? Note: Let pop #1= “last year”

20  Example, cont. H 0 :  LY <  1979 H A :  LY >  1979 Rejection Region Z 2.326  =.01

21  Example, cont. Z 2.326 Since 6.80 > 2.326, we reject H 0. Conclusion: There is sufficient evidence at the 99% confidence level to suggest that the mean years of service of those retiring last year is greater than the mean years of service of those retiring in 1979.

22  When comparing two different, independent populations with unknown variances that are assumed equal) with small n, the test statistic looks like (Pooled Sample Variance) df = n 1 + n 2 – 2 t ( XX s nn p          12 2 12 11  )

23  Example To determine whether there is a difference in the time involved in using two versions of software, the new version of the software is compared to the original. Samples are taken from two independent groups using the software (data below). At the.01 significance level, is there a difference in the mean amount of time required to use two versions of software?

24  Example, cont. H 0 :  1 -  2 = 0 H A :  1 -  2 = 0 /  =.01 Because we have a two tailed test, there is  /2 =.005 in each tail df = n1 + n2 – 2 = 5 + 6 – 2 = 9 From t-table, critical cutoffs for two-tail, alpha/2=.005, df=9 is 3.25

25  Example, cont. 83. 963. 80. )6/15/1(53.2 0.78.7     )/1/1( 21 2 2 1    nn S XX t p Since.83 < 3.25, we do not reject H 0. Conclusion: There is insufficient evidence to suggest that there is a difference between the mean time to use the two versions of software

26  When comparing two different population proportions, the Null Hypothesis takes on the form:  The test statistic looks like: H 0 :  1 -  2 = 0 H 0 :  1 =  2 where = (the weighted mean of the two sample proportions)

27  Are unmarried workers more likely to be absent from work than married workers? A sample of 250 married workers showed 22 missed more than 5 days last year, while a sample of 300 unmarried workers showed 35 missed more than five days. Use a.05 significance level. Note: let pop #1= unmarried workers.

28  Example, cont. H 0 : p u = p m H A : p u > p m  =.05 Rejection Region Z 1.645 p u = Unmarried Workers = X 1 /n 1 = 35/300 =.1167 p m = Married Workers = X 2 /n 2 = 22/250 =.0880 1036. 250300 2235 = + + = c p

29  Chapter 9: problems 10, 15, 17, 18, 20, 40  Chapter 10: problems 12, 14 (two sample), 32, 33 (proportions)


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