Chapter 8 Testing Hypotheses

Exercises

Basic

1. Find the rejection region (for the standardized test statistic) for each hypothesis test.

   1. H0:μ=27 vs. Ha:μ<27 @ α=0.05.
   2. H0:μ=52 vs. Ha:μ≠52 @ α=0.05.
   3. H0:μ=−105 vs. Ha:μ>−105 @ α=0.10.
   4. H0:μ=78.8 vs. Ha:μ≠78.8 @ α=0.10.

2. Find the rejection region (for the standardized test statistic) for each hypothesis test.

   1. H0:μ=17 vs. Ha:μ<17 @ α=0.01.
   2. H0:μ=880 vs. Ha:μ≠880 @ α=0.01.
   3. H0:μ=−12 vs. Ha:μ>−12 @ α=0.05.
   4. H0:μ=21.1 vs. Ha:μ≠21.1@ α=0.05.

3. Find the rejection region (for the standardized test statistic) for each hypothesis test. Identify the test as left-tailed, right-tailed, or two-tailed.

   1. H0:μ=141 vs. Ha:μ<141 @ α=0.20.
   2. H0:μ=−54 vs. Ha:μ<−54 @ α=0.05.
   3. H0:μ=98.6 vs. Ha:μ≠98.6 @ α=0.05.
   4. H0:μ=3.8 vs. Ha:μ>3.8 @ α=0.001.

4. Find the rejection region (for the standardized test statistic) for each hypothesis test. Identify the test as left-tailed, right-tailed, or two-tailed.

   1. H0:μ=−62 vs. Ha:μ≠−62 @ α=0.005.
   2. H0:μ=73 vs. Ha:μ>73 @ α=0.001.
   3. H0:μ=1124 vs. Ha:μ<1124 @ α=0.001.
   4. H0:μ=0.12 vs. Ha:μ≠0.12 @ α=0.001.

5. Compute the value of the test statistic for the indicated test, based on the information given.

   1. Testing H0:μ=72.2 vs. Ha:μ>72.2, σ unknown, n = 55, x-=75.1, s = 9.25
   2. Testing H0:μ=58 vs. Ha:μ>58, σ = 1.22, n = 40, x-=58.5, s = 1.29
   3. Testing H0:μ=−19.5 vs. Ha:μ<−19.5, σ unknown, n = 30, x-=−23.2, s = 9.55
   4. Testing H0:μ=805 vs. Ha:μ≠805, σ = 37.5, n = 75, x-=818, s = 36.2

6. Compute the value of the test statistic for the indicated test, based on the information given.

   1. Testing H0:μ=342 vs. Ha:μ<342, σ = 11.2, n = 40, x-=339, s = 10.3
   2. Testing H0:μ=105 vs. Ha:μ>105, σ = 5.3, n = 80, x-=107, s = 5.1
   3. Testing H0:μ=−13.5 vs. Ha:μ≠−13.5, σ unknown, n = 32, x-=−13.8, s = 1.5
   4. Testing H0:μ=28 vs. Ha:μ≠28, σ unknown, n = 68, x-=27.8, s = 1.3

7. Perform the indicated test of hypotheses, based on the information given.

   1. Test H0:μ=212 vs. Ha:μ<212 @ α=0.10, σ unknown, n = 36, x-=211.2, s = 2.2
   2. Test H0:μ=−18 vs. Ha:μ>−18 @ α=0.05, σ = 3.3, n = 44, x-=−17.2, s = 3.1
   3. Test H0:μ=24 vs. Ha:μ≠24 @ α=0.02, σ unknown, n = 50, x-=22.8, s = 1.9

8. Perform the indicated test of hypotheses, based on the information given.

   1. Test H0:μ=105 vs. Ha:μ>105 @ α=0.05, σ unknown, n = 30, x-=108, s = 7.2
   2. Test H0:μ=21.6 vs. Ha:μ<21.6 @ α=0.01, σ unknown, n = 78, x-=20.5, s = 3.9
   3. Test H0:μ=−375 vs. Ha:μ≠−375 @ α=0.01, σ = 18.5, n = 31, x-=−388, s = 18.0

Applications

9. In the past the average length of an outgoing telephone call from a business office has been 143 seconds. A manager wishes to check whether that average has decreased after the introduction of policy changes. A sample of 100 telephone calls produced a mean of 133 seconds, with a standard deviation of 35 seconds. Perform the relevant test at the 1% level of significance.

10. The government of an impoverished country reports the mean age at death among those who have survived to adulthood as 66.2 years. A relief agency examines 30 randomly selected deaths and obtains a mean of 62.3 years with standard deviation 8.1 years. Test whether the agency’s data support the alternative hypothesis, at the 1% level of significance, that the population mean is less than 66.2.

11. The average household size in a certain region several years ago was 3.14 persons. A sociologist wishes to test, at the 5% level of significance, whether it is different now. Perform the test using the information collected by the sociologist: in a random sample of 75 households, the average size was 2.98 persons, with sample standard deviation 0.82 person.

12. The recommended daily calorie intake for teenage girls is 2,200 calories/day. A nutritionist at a state university believes the average daily caloric intake of girls in that state to be lower. Test that hypothesis, at the 5% level of significance, against the null hypothesis that the population average is 2,200 calories/day using the following sample data: n = 36, x-= 2,150, s = 203.

13. An automobile manufacturer recommends oil change intervals of 3,000 miles. To compare actual intervals to the recommendation, the company randomly samples records of 50 oil changes at service facilities and obtains sample mean 3,752 miles with sample standard deviation 638 miles. Determine whether the data provide sufficient evidence, at the 5% level of significance, that the population mean interval between oil changes exceeds 3,000 miles.

14. A medical laboratory claims that the mean turn-around time for performance of a battery of tests on blood samples is 1.88 business days. The manager of a large medical practice believes that the actual mean is larger. A random sample of 45 blood samples yielded mean 2.09 and sample standard deviation 0.13 day. Perform the relevant test at the 10% level of significance, using these data.

15. A grocery store chain has as one standard of service that the mean time customers wait in line to begin checking out not exceed 2 minutes. To verify the performance of a store the company measures the waiting time in 30 instances, obtaining mean time 2.17 minutes with standard deviation 0.46 minute. Use these data to test the null hypothesis that the mean waiting time is 2 minutes versus the alternative that it exceeds 2 minutes, at the 10% level of significance.

16. A magazine publisher tells potential advertisers that the mean household income of its regular readership is $61,500. An advertising agency wishes to test this claim against the alternative that the mean is smaller. A sample of 40 randomly selected regular readers yields mean income $59,800 with standard deviation $5,850. Perform the relevant test at the 1% level of significance.

17. Authors of a computer algebra system wish to compare the speed of a new computational algorithm to the currently implemented algorithm. They apply the new algorithm to 50 standard problems; it averages 8.16 seconds with standard deviation 0.17 second. The current algorithm averages 8.21 seconds on such problems. Test, at the 1% level of significance, the alternative hypothesis that the new algorithm has a lower average time than the current algorithm.

18. A random sample of the starting salaries of 35 randomly selected graduates with bachelor’s degrees last year gave sample mean and standard deviation $41,202 and $7,621, respectively. Test whether the data provide sufficient evidence, at the 5% level of significance, to conclude that the mean starting salary of all graduates last year is less than the mean of all graduates two years before, $43,589.

Additional Exercises

19. The mean household income in a region served by a chain of clothing stores is $48,750. In a sample of 40 customers taken at various stores the mean income of the customers was $51,505 with standard deviation $6,852.

    1. Test at the 10% level of significance the null hypothesis that the mean household income of customers of the chain is $48,750 against that alternative that it is different from $48,750.
    2. The sample mean is greater than $48,750, suggesting that the actual mean of people who patronize this store is greater than $48,750. Perform this test, also at the 10% level of significance. (The computation of the test statistic done in part (a) still applies here.)

20. The labor charge for repairs at an automobile service center are based on a standard time specified for each type of repair. The time specified for replacement of universal joint in a drive shaft is one hour. The manager reviews a sample of 30 such repairs. The average of the actual repair times is 0.86 hour with standard deviation 0.32 hour.

    1. Test at the 1% level of significance the null hypothesis that the actual mean time for this repair differs from one hour.
    2. The sample mean is less than one hour, suggesting that the mean actual time for this repair is less than one hour. Perform this test, also at the 1% level of significance. (The computation of the test statistic done in part (a) still applies here.)

Large Data Set Exercises

21. Large Data Set 1 records the SAT scores of 1,000 students. Regarding it as a random sample of all high school students, use it to test the hypothesis that the population mean exceeds 1,510, at the 1% level of significance. (The null hypothesis is that μ = 1510.)

    http://www.flatworldknowledge.com/sites/all/files/data1.xls

22. Large Data Set 1 records the GPAs of 1,000 college students. Regarding it as a random sample of all college students, use it to test the hypothesis that the population mean is less than 2.50, at the 10% level of significance. (The null hypothesis is that μ = 2.50.)

    http://www.flatworldknowledge.com/sites/all/files/data1.xls

23. Large Data Set 1 lists the SAT scores of 1,000 students.

    http://www.flatworldknowledge.com/sites/all/files/data1.xls

    1. Regard the data as arising from a census of all students at a high school, in which the SAT score of every student was measured. Compute the population mean μ.
    2. Regard the first 50 students in the data set as a random sample drawn from the population of part (a) and use it to test the hypothesis that the population mean exceeds 1,510, at the 10% level of significance. (The null hypothesis is that μ = 1510.)
    3. Is your conclusion in part (b) in agreement with the true state of nature (which by part (a) you know), or is your decision in error? If your decision is in error, is it a Type I error or a Type II error?

24. Large Data Set 1 lists the GPAs of 1,000 students.

    http://www.flatworldknowledge.com/sites/all/files/data1.xls

    1. Regard the data as arising from a census of all freshman at a small college at the end of their first academic year of college study, in which the GPA of every such person was measured. Compute the population mean μ.
    2. Regard the first 50 students in the data set as a random sample drawn from the population of part (a) and use it to test the hypothesis that the population mean is less than 2.50, at the 10% level of significance. (The null hypothesis is that μ = 2.50.)
    3. Is your conclusion in part (b) in agreement with the true state of nature (which by part (a) you know), or is your decision in error? If your decision is in error, is it a Type I error or a Type II error?

Answers

1. 1. Z≤−1.645
   2. Z≤−1.96 or Z ≥ 1.96
   3. Z ≥ 1.28
   4. Z≤−1.645 or Z ≥ 1.645
3. 1. Z≤−0.84
   2. Z≤−1.645
   3. Z≤−1.96 or Z ≥ 1.96
   4. Z ≥ 3.1
5. 1. Z = 2.235
   2. Z = 2.592
   3. Z=−2.122
   4. Z = 3.002
7. 1. Z=−2.18, −z0.10=−1.28, reject H₀.
   2. Z = 1.61, z0.05=1.645, do not reject H₀.
   3. Z=−4.47, −z0.01=−2.33, reject H₀.

9. Z=−2.86, −z0.01=−2.33, reject H₀.

11. Z=−1.69, −z0.025=−1.96, do not reject H₀.

13. Z = 8.33, z0.05=1.645, reject H₀.

15. Z = 2.02, z0.10=1.28, reject H₀.

17. Z=−2.08, −z0.01=−2.33, do not reject H₀.

19. 1. Z = 2.54, z0.05=1.645, reject H₀;
    2. Z = 2.54, z0.10=1.28, reject H₀.

21. H0:μ=1510 vs. Ha:μ>1510. Test Statistic: Z = 2.7882. Rejection Region: [2.33,∞). Decision: Reject H₀.

23. 1. μ0=1528.74
    2. H0:μ=1510 vs. Ha:μ>1510. Test Statistic: Z=−1.41. Rejection Region: [1.28,∞). Decision: Fail to reject H₀.
    3. No, it is a Type II error.

Exercises

Basic

1. Find the rejection region (for the standardized test statistic) for each hypothesis test based on the information given. The population is normally distributed.

   1. $H_0:\mathit{\mu }=27$ vs. $H_a:\mathit{\mu }<27$ @ $\alpha =0.05$, n = 12, σ = 2.2.
   2. $H_0:\mathit{\mu }=52$ vs. $H_a:\mathit{\mu }\ne 52$ @ $\alpha =0.05$, n = 6, σ unknown.
   3. $H_0:\mathit{\mu }=\text{−}105$ vs. $H_a:\mathit{\mu }>\text{−}105$ @ $\alpha =0.10$, n = 24, σ unknown.
   4. $H_0:\mathit{\mu }=78.8$ vs. $H_a:\mathit{\mu }\ne 78.8$ @ $\alpha =0.10$, n = 8, σ = 1.7.

2. Find the rejection region (for the standardized test statistic) for each hypothesis test based on the information given. The population is normally distributed.

   1. $H_0:\mathit{\mu }=17$ vs. $H_a:\mathit{\mu }<17$ @ $\alpha =0.01$, n = 26, σ = 0.94.
   2. $H_0:\mathit{\mu }=880$ vs. $H_a:\mathit{\mu }\ne 880$ @ $\alpha =0.01$, n = 4, σ unknown.
   3. $H_0:\mathit{\mu }=\text{−}12$ vs. $H_a:\mathit{\mu }>\text{−}12$ @ $\alpha =0.05$, n = 18, σ = 1.1.
   4. $H_0:\mathit{\mu }=21.1$ vs. $H_a:\mathit{\mu }\ne 21.1$@ $\alpha =0.05$, n = 23, σ unknown.

3. Find the rejection region (for the standardized test statistic) for each hypothesis test based on the information given. The population is normally distributed. Identify the test as left-tailed, right-tailed, or two-tailed.

   1. $H_0:\mathit{\mu }=141$ vs. $H_a:\mathit{\mu }<141$ @ $\alpha =0.20$, n = 29, σ unknown.
   2. $H_0:\mathit{\mu }=\text{−}54$ vs. $H_a:\mathit{\mu }<\text{−}54$ @ $\alpha =0.05$, n = 15, σ = 1.9.
   3. $H_0:\mathit{\mu }=98.6$ vs. $H_a:\mathit{\mu }\ne 98.6$ @ $\alpha =0.05$, n = 12, σ unknown.
   4. $H_0:\mathit{\mu }=3.8$ vs. $H_a:\mathit{\mu }>3.8$ @ $\alpha =0.001$, n = 27, σ unknown.

4. Find the rejection region (for the standardized test statistic) for each hypothesis test based on the information given. The population is normally distributed. Identify the test as left-tailed, right-tailed, or two-tailed.

   1. $H_0:\mathit{\mu }=\text{−}62$ vs. $H_a:\mathit{\mu }\ne \text{−}62$ @ $\alpha =0.005$, n = 8, σ unknown.
   2. $H_0:\mathit{\mu }=73$ vs. $H_a:\mathit{\mu }>73$ @ $\alpha =0.001,$ n = 22, σ unknown.
   3. $H_0:\mathit{\mu }=1124$ vs. $H_a:\mathit{\mu }<1124$ @ $\alpha =0.001$, n = 21, σ unknown.
   4. $H_0:\mathit{\mu }=0.12$ vs. $H_a:\mathit{\mu }\ne 0.12$ @ $\alpha =0.001$, n = 14, σ = 0.026.

5. A random sample of size 20 drawn from a normal population yielded the following results: $\stackrel{-}{x}=49.2$, s = 1.33.

   1. Test $H_0:\mathit{\mu }=50$ vs. $H_a:\mathit{\mu }\ne 50$ @ $\alpha =0.01.$
   2. Estimate the observed significance of the test in part (a) and state a decision based on the p-value approach to hypothesis testing.

6. A random sample of size 16 drawn from a normal population yielded the following results: $\stackrel{-}{x}=\text{−}0.96$, s = 1.07.

   1. Test $H_0:\mathit{\mu }=0$ vs. $H_a:\mathit{\mu }<0$ @ $\alpha =0.001.$
   2. Estimate the observed significance of the test in part (a) and state a decision based on the p-value approach to hypothesis testing.

7. A random sample of size 8 drawn from a normal population yielded the following results: $\stackrel{-}{x}=289$, s = 46.

   1. Test $H_0:\mathit{\mu }=250$ vs. $H_a:\mathit{\mu }>250$ @ $\alpha =0.05.$
   2. Estimate the observed significance of the test in part (a) and state a decision based on the p-value approach to hypothesis testing.

8. A random sample of size 12 drawn from a normal population yielded the following results: $\stackrel{-}{x}=86.2$, s = 0.63.

   1. Test $H_0:\mathit{\mu }=85.5$ vs. $H_a:\mathit{\mu }\ne 85.5$ @ $\alpha =0.01.$
   2. Estimate the observed significance of the test in part (a) and state a decision based on the p-value approach to hypothesis testing.

Applications

9. Researchers wish to test the efficacy of a program intended to reduce the length of labor in childbirth. The accepted mean labor time in the birth of a first child is 15.3 hours. The mean length of the labors of 13 first-time mothers in a pilot program was 8.8 hours with standard deviation 3.1 hours. Assuming a normal distribution of times of labor, test at the 10% level of significance test whether the mean labor time for all women following this program is less than 15.3 hours.

10. A dairy farm uses the somatic cell count (SCC) report on the milk it provides to a processor as one way to monitor the health of its herd. The mean SCC from five samples of raw milk was 250,000 cells per milliliter with standard deviation 37,500 cell/ml. Test whether these data provide sufficient evidence, at the 10% level of significance, to conclude that the mean SCC of all milk produced at the dairy exceeds that in the previous report, 210,250 cell/ml. Assume a normal distribution of SCC.

11. Six coins of the same type are discovered at an archaeological site. If their weights on average are significantly different from 5.25 grams then it can be assumed that their provenance is not the site itself. The coins are weighed and have mean 4.73 g with sample standard deviation 0.18 g. Perform the relevant test at the 0.1% (1/10th of 1%) level of significance, assuming a normal distribution of weights of all such coins.

12. An economist wishes to determine whether people are driving less than in the past. In one region of the country the number of miles driven per household per year in the past was 18.59 thousand miles. A sample of 15 households produced a sample mean of 16.23 thousand miles for the last year, with sample standard deviation 4.06 thousand miles. Assuming a normal distribution of household driving distances per year, perform the relevant test at the 5% level of significance.

13. The recommended daily allowance of iron for females aged 19–50 is 18 mg/day. A careful measurement of the daily iron intake of 15 women yielded a mean daily intake of 16.2 mg with sample standard deviation 4.7 mg.

    1. Assuming that daily iron intake in women is normally distributed, perform the test that the actual mean daily intake for all women is different from 18 mg/day, at the 10% level of significance.
    2. The sample mean is less than 18, suggesting that the actual population mean is less than 18 mg/day. Perform this test, also at the 10% level of significance. (The computation of the test statistic done in part (a) still applies here.)

14. The target temperature for a hot beverage the moment it is dispensed from a vending machine is 170°F. A sample of ten randomly selected servings from a new machine undergoing a pre-shipment inspection gave mean temperature 173°F with sample standard deviation 6.3°F.

    1. Assuming that temperature is normally distributed, perform the test that the mean temperature of dispensed beverages is different from 170°F, at the 10% level of significance.
    2. The sample mean is greater than 170, suggesting that the actual population mean is greater than 170°F. Perform this test, also at the 10% level of significance. (The computation of the test statistic done in part (a) still applies here.)

15. The average number of days to complete recovery from a particular type of knee operation is 123.7 days. From his experience a physician suspects that use of a topical pain medication might be lengthening the recovery time. He randomly selects the records of seven knee surgery patients who used the topical medication. The times to total recovery were:

    $$\begin{array}{ccccccc}\hfill 128& 135& 121& 142& 126& 151& 123\end{array}$$

    1. Assuming a normal distribution of recovery times, perform the relevant test of hypotheses at the 10% level of significance.
    2. Would the decision be the same at the 5% level of significance? Answer either by constructing a new rejection region (critical value approach) or by estimating the p-value of the test in part (a) and comparing it to $\alpha .$

16. A 24-hour advance prediction of a day’s high temperature is “unbiased” if the long-term average of the error in prediction (true high temperature minus predicted high temperature) is zero. The errors in predictions made by one meteorological station for 20 randomly selected days were:

    $$\begin{array}{ccccc}\hfill 2& \hfill 0& \hfill \text{−}3& \hfill 1& \hfill \text{−}2\\ \hfill 1& \hfill 0& \hfill \text{−}1& \hfill 1& \hfill \text{−}1\\ \hfill \text{−}4& \hfill 1& \hfill 1& \hfill \text{−}4& \hfill 0\\ \hfill \text{−}4& \hfill \text{−}3& \hfill \text{−}4& \hfill 2& \hfill 2\end{array}$$

    1. Assuming a normal distribution of errors, test the null hypothesis that the predictions are unbiased (the mean of the population of all errors is 0) versus the alternative that it is biased (the population mean is not 0), at the 1% level of significance.
    2. Would the decision be the same at the 5% level of significance? The 10% level of significance? Answer either by constructing new rejection regions (critical value approach) or by estimating the p-value of the test in part (a) and comparing it to $\alpha .$

17. Pasteurized milk may not have a standardized plate count (SPC) above 20,000 colony-forming bacteria per milliliter (cfu/ml). The mean SPC for five samples was 21,500 cfu/ml with sample standard deviation 750 cfu/ml. Test the null hypothesis that the mean SPC for this milk is 20,000 versus the alternative that it is greater than 20,000, at the 10% level of significance. Assume that the SPC follows a normal distribution.

18. One water quality standard for water that is discharged into a particular type of stream or pond is that the average daily water temperature be at most 18°C. Six samples taken throughout the day gave the data:

    $$\begin{array}{cccccc}\hfill 16.8& 21.5& 19.1& 12.8& 18.0& 20.7\end{array}$$

    The sample mean $\stackrel{-}{x}=18.15$ exceeds 18, but perhaps this is only sampling error. Determine whether the data provide sufficient evidence, at the 10% level of significance, to conclude that the mean temperature for the entire day exceeds 18°C.

Additional Exercises

19. A calculator has a built-in algorithm for generating a random number according to the standard normal distribution. Twenty-five numbers thus generated have mean 0.15 and sample standard deviation 0.94. Test the null hypothesis that the mean of all numbers so generated is 0 versus the alternative that it is different from 0, at the 20% level of significance. Assume that the numbers do follow a normal distribution.

20. At every setting a high-speed packing machine delivers a product in amounts that vary from container to container with a normal distribution of standard deviation 0.12 ounce. To compare the amount delivered at the current setting to the desired amount 64.1 ounce, a quality inspector randomly selects five containers and measures the contents of each, obtaining sample mean 63.9 ounces and sample standard deviation 0.10 ounce. Test whether the data provide sufficient evidence, at the 5% level of significance, to conclude that the mean of all containers at the current setting is less than 64.1 ounces.

21. A manufacturing company receives a shipment of 1,000 bolts of nominal shear strength 4,350 lb. A quality control inspector selects five bolts at random and measures the shear strength of each. The data are:

    $$\begin{array}{ccccc}\hfill \mathrm{4,320}& \mathrm{4,290}& \mathrm{4,360}& \mathrm{4,350}& \mathrm{4,320}\end{array}$$

    1. Assuming a normal distribution of shear strengths, test the null hypothesis that the mean shear strength of all bolts in the shipment is 4,350 lb versus the alternative that it is less than 4,350 lb, at the 10% level of significance.
    2. Estimate the p-value (observed significance) of the test of part (a).
    3. Compare the p-value found in part (b) to $\alpha =0.10$ and make a decision based on the p-value approach. Explain fully.

22. A literary historian examines a newly discovered document possibly written by Oberon Theseus. The mean average sentence length of the surviving undisputed works of Oberon Theseus is 48.72 words. The historian counts words in sentences between five successive 101 periods in the document in question to obtain a mean average sentence length of 39.46 words with standard deviation 7.45 words. (Thus the sample size is five.)

    1. Determine if these data provide sufficient evidence, at the 1% level of significance, to conclude that the mean average sentence length in the document is less than 48.72.
    2. Estimate the p-value of the test.
    3. Based on the answers to parts (a) and (b), state whether or not it is likely that the document was written by Oberon Theseus.

Answers

1. 1. $Z\le \text{−}1.645$
   2. $T\le \text{−}2.571$ or T ≥ 2.571
   3. T ≥ 1.319
   4. $Z\le \text{−}1645$ or Z ≥ 1.645
3. 1. $T\le \text{−}0.855$
   2. $Z\le \text{−}1.645$
   3. $T\le \text{−}2.201$ or T ≥ 2.201
   4. T ≥ 3.435
5. 1. $T=\text{−}2.690$, $df=19$, $\text{−}{t}_{0.005}=\text{−}2.861$, do not reject H₀.
   2. $0.01<p\text{\hspace{0.17em}-value}<0.02$, $\alpha =0.01$, do not reject H₀.
7. 1. T = 2.398, $df=7$, $t_{0.05}=1.895$, reject H₀.
   2. $0.01<p\text{\hspace{0.17em}-value}<0.025$, $\alpha =0.05$, reject H₀.

9. $T=\text{−}7.560$, $df=12$, $\text{−}{t}_{0.10}=\text{−}1.356$, reject H₀.

11. $T=\text{−}7.076$, $df=5$, $\text{−}{t}_{0.0005}=\text{−}6.869$, reject H₀.

13. 1. $T=\text{−}1.483$, $df=14$, $\text{−}{t}_{0.05}=\text{−}1.761$, do not reject H₀;
    2. $T=\text{−}1.483$, $df=14$, $\text{−}{t}_{0.10}=\text{−}1.345$, reject H₀;
15. 1. T = 2.069, $df=6$, $t_{0.10}=1.44$, reject H₀;
    2. T = 2.069, $df=6$, $t_{0.05}=1.943$, reject H₀.

17. T = 4.472, $df=4$, $t_{0.10}=1.533$, reject H₀.

19. T = 0.798, $df=24$, $t_{0.10}=1.318$, do not reject H₀.

21. 1. $T=\text{−}1.773$, $df=4$, $\text{−}{t}_{0.05}=\text{−}2.132$, do not reject H₀.
    2. $0.05<p\text{\hspace{0.17em}-value}<0.10$
    3. $\alpha =0.05$, do not reject H₀

Exercises

Basic

On all exercises for this section you may assume that the sample is sufficiently large for the relevant test to be validly performed.

1. Compute the value of the test statistic for each test using the information given.

   1. Testing H0:p=0.50 vs. Ha:p>0.50, n = 360, p^=0.56.
   2. Testing H0:p=0.50 vs. Ha:p≠0.50, n = 360, p^=0.56.
   3. Testing H0:p=0.37 vs. Ha:p<0.37, n = 1200, p^=0.35.

2. Compute the value of the test statistic for each test using the information given.

   1. Testing H0:p=0.72 vs. Ha:p<0.72, n = 2100, p^=0.71.
   2. Testing H0:p=0.83 vs. Ha:p≠0.83, n = 500, p^=0.86.
   3. Testing H0:p=0.22 vs. Ha:p<0.22, n = 750, p^=0.18.

3. For each part of Exercise 1 construct the rejection region for the test for α=0.05 and make the decision based on your answer to that part of the exercise.

4. For each part of Exercise 2 construct the rejection region for the test for α=0.05 and make the decision based on your answer to that part of the exercise.

5. For each part of Exercise 1 compute the observed significance (p-value) of the test and compare it to α=0.05 in order to make the decision by the p-value approach to hypothesis testing.

6. For each part of Exercise 2 compute the observed significance (p-value) of the test and compare it to α=0.05 in order to make the decision by the p-value approach to hypothesis testing.

7. Perform the indicated test of hypotheses using the critical value approach.

   1. Testing H0:p=0.55 vs. Ha:p>0.55 @ α=0.05, n = 300, p^=0.60.
   2. Testing H0:p=0.47 vs. Ha:p≠0.47 @ α=0.01, n = 9750, p^=0.46.

8. Perform the indicated test of hypotheses using the critical value approach.

   1. Testing H0:p=0.15 vs. Ha:p≠0.15 @ α=0.001, n = 1600, p^=0.18.
   2. Testing H0:p=0.90 vs. Ha:p>0.90 @ α=0.01, n = 1100, p^=0.91.

9. Perform the indicated test of hypotheses using the p-value approach.

   1. Testing H0:p=0.37 vs. Ha:p≠0.37 @ α=0.005, n = 1300, p^=0.40.
   2. Testing H0:p=0.94 vs. Ha:p>0.94 @ α=0.05, n = 1200, p^=0.96.

10. Perform the indicated test of hypotheses using the p-value approach.

    1. Testing H0:p=0.25 vs. Ha:p<0.25 @ α=0.10, n = 850, p^=0.23.
    2. Testing H0:p=0.33 vs. Ha:p≠0.33 @ α=0.05, n = 1100, p^=0.30.