1. Chapter 20 Confidence Intervals and Hypothesis Tests for a Population Mean  ; t distributions t distributions confidence intervals for a population mean  using t distributions hypothesis tests for a population mean  using t distributions

2. The Importance of the Central Limit Theorem n When we select simple random samples of size n, the sample means we find will vary from sample to sample. We can model the distribution of these sample means with a probability model that is

3. Since the sampling model for x is the normal model, when we standardize x we get the standard normal z

4. If  is unknown, we probably don’t know  either. The sample standard deviation s provides an estimate of the population standard deviation  For a sample of size n, the sample standard deviation s is: n − 1 is the “degrees of freedom.” The value s/√n is called the standard error of x, denoted SE(x).

5. Standardize using s for  n Substitute s (sample standard deviation) for  ssss s ss s Note quite correct Not knowing  means using z is no longer correct

6. t-distributions Suppose that a Simple Random Sample of size n is drawn from a population whose distribution can be approximated by a N(µ, σ) model. When  is known, the sampling model for the mean x is N(  /√n). When  is estimated from the sample standard deviation s, the sampling model for the mean x follows a t distribution t( , s/√n) with degrees of freedom n − 1. is the 1-sample t statistic

7. Confidence Interval Estimates n CONFIDENCE INTERVAL for  n where: n t = Critical value from t- distribution with n-1 degrees of freedom n = Sample mean n s = Sample standard deviation n n = Sample size For very small samples ( n < 15), the data should follow a Normal model very closely. For moderate sample sizes ( n between 15 and 40), t methods will work well as long as the data are unimodal and reasonably symmetric. For sample sizes larger than 40, t methods are safe to use unless the data are extremely skewed. If outliers are present, analyses can be performed twice, with the outliers and without.

8. t distributions n Very similar to z~N(0, 1) n Sometimes called Student’s t distribution; Gossett, brewery employee n Properties: i)symmetric around 0 (like z) ii)degrees of freedom

9. -3-20123 Z 0123 -2-3 Student’s t Distribution

10. -3-20123 Z t 0123 -2-3 Student’s t Distribution Figure 11.3, Page 372

11. -3-20123 Z t1t1 0123 -2-3 Student’s t Distribution Figure 11.3, Page 372 Degrees of Freedom

12. -3-20123 Z t1t1 0123 -2-3 t7t7 Student’s t Distribution Figure 11.3, Page 372 Degrees of Freedom

13. 13.07776.31412.70631.82163.657 21.88562.92004.30276.96459.9250............ 101.37221.81252.22812.76383.1693............ 1001.29011.66041.98402.36422.6259 1.2821.64491.96002.32632.5758 0.80 0.90 0.950.980.99 t-Table: text- inside back cover n 90% confidence interval; df = n-1 = 10

14. 0 1.8125 Student’s t Distribution P(t > 1.8125) =.05 -1.8125.05.90 t 10 P(t < -1.8125) =.05

15. Comparing t and z Critical Values Conf. leveln = 30 z = 1.64590%t = 1.6991 z = 1.9695%t = 2.0452 z = 2.3398%t = 2.4620 z = 2.5899%t = 2.7564

16. n Example –An investor is trying to estimate the return on investment in companies that won quality awards last year. –A random sample of 41 such companies is selected, and the return on investment is recorded for each company. The data for the 41 companies have –Construct a 95% confidence interval for the mean return.

18. Example n Because cardiac deaths increase after heavy snowfalls, a study was conducted to measure the cardiac demands of shoveling snow by hand n The maximum heart rates for 10 adult males were recorded while shoveling snow. The sample mean and sample standard deviation were n Find a 90% CI for the population mean max. heart rate for those who shovel snow.

19. Solution

20. EXAMPLE: Consumer Protection Agency n Selected random sample of 16 packages of a product whose packages are marked as weighing 1 pound. n From the 16 packages: n a. find a 95% CI for the mean weight  of the 1-pound packages n b. should the company’s claim that the mean weight  is 1 pound be challenged ?

21. EXAMPLE

22. Chapter 20 Testing Hypotheses about Means 22

23. Sweetness in cola soft drinks Cola manufacturers want to test how much the sweetness of cola drinks is affected by storage. The sweetness loss due to storage was evaluated by 10 professional tasters by comparing the sweetness before and after storage (a positive value indicates a loss of sweetness): Taster Sweetness loss n 1 2.0 n 2 0.4 n 3 0.7 n 4 2.0 n 5 −0.4 n 6 2.2 n 7 −1.3 n 8 1.2 n 9 1.1 n 10 2.3 We want to test if storage results in a loss of sweetness, thus: H 0 :  = 0 versus H A :  > 0 where  is the mean sweetness loss due to storage. We also do not know the population parameter , the standard deviation of the sweetness loss.

24. The one-sample t-test As in any hypothesis tests, a hypothesis test for  requires a few steps: 1.State the null and alternative hypotheses (H 0 versus H A ) a) Decide on a one-sided or two-sided test 2.Calculate the test statistic t and determining its degrees of freedom 3.Find the area under the t distribution with the t-table or technology 4.State the P-value (or find bounds on the P-value) and interpret the result

25. The one-sample t-test; hypotheses Step 1: 1.State the null and alternative hypotheses (H 0 versus H A ) a) Decide on a one-sided or two-sided test H 0 :  =   versus H A :  >   (1 –tail test) H 0 :  =   versus H A :  <   (1 –tail test) H 0 :  =   versus H A :  ≠    –tail test)

26. The one-sample t-test; test statistic We perform a hypothesis test with null hypothesis H :  =  0 using the test statistic where the standard error of is. When the null hypothesis is true, the test statistic follows a t distribution with n-1 degrees of freedom. We use that model to obtain a P-value.

27. 27 The one-sample t-test; P-Values Recall: The P-value is the probability, calculated assuming the null hypothesis H 0 is true, of observing a value of the test statistic more extreme than the value we actually observed. The calculation of the P-value depends on whether the hypothesis test is 1-tailed (that is, the alternative hypothesis is H A :   0 ) or 2-tailed (that is, the alternative hypothesis is H A :  ≠  0 ).

28. 28 P-Values If H A :  >  0, then P-value=P(t > t 0 ) Assume the value of the test statistic t is t 0 If H A :  <  0, then P-value=P(t < t 0 ) If H A :  ≠  0, then P-value=2P(t > |t 0 |)

29. Sweetening colas (continued) Is there evidence that storage results in sweetness loss in colas? H 0 :  = 0 versus H a :  > 0 (one-sided test) Taster Sweetness loss 1 2.0 2 0.4 3 0.7 4 2.0 5 -0.4 6 2.2 7 -1.3 8 1.2 9 1.1 10 2.3 ___________________________ Average 1.02 Standard deviation 1.196 Degrees of freedom n − 1 = 9 Conf. Level0.10.30.50.70.80.90.950.980.99 Two Tail0.90.70.50.30.20.10.050.020.01 One Tail0.450.350.250.150.10.050.0250.010.005 dfValues of t 90.12930.39790.70271.09971.38301.83312.26222.82143.2498 2.2622 < t = 2.70 < 2.8214; thus 0.01 < P-value < 0.025. Since P-value <.05, we reject H 0. There is a significant loss of sweetness, on average, following storage.

30. Finding P-values with Excel TDIST(x, degrees_freedom, tails) TDIST = P(t > x) for a random variable t following the t distribution (x positive). Use it in place of t-table to obtain the P-value. –x is the absolute value of the test statistic. –Deg_freedom is an integer indicating the number of degrees of freedom. –Tails specifies the number of distribution tails to return. If tails = 1, TDIST returns the one-tailed P-value. If tails = 2, TDIST returns the two-tailed P-value.

31. Sweetness in cola soft drinks (cont.) 31 2.2622 < t = 2.70 < 2.8214; thus 0.01 < p < 0.025.

32. New York City Hotel Room Costs The NYC Visitors Bureau claims that the average cost of a hotel room is $168 per night. A random sample of 25 hotels resulted in y = $172.50 and s = $15.40. H 0 : μ  = 168 H A : μ  168

33.  n = 25; df = 24 New York City Hotel Room Costs Do not reject H 0 : not sufficient evidence that true mean cost is different than $168.079 0 1. 46 H 0 : μ  = 168 H A : μ  168 -1. 46 t, 24 df Conf. Level0.10.30.50.70.80.90.950.980.99 Two Tail0.90.70.50.30.20.10.050.020.01 One Tail0.450.350.250.150.10.050.0250.010.005 dfValues of t 240.12700.39000.68481.05931.31781.71092.06392.49222.7969 P-value =.158 0.1 ≤ P-value ≤ 0.2

34. Microwave Popcorn A popcorn maker wants a combination of microwave time and power that delivers high-quality popped corn with less than 10% unpopped kernels, on average. After testing, the research department determines that power 9 at 4 minutes is optimum. The company president tests 8 bags in his office microwave and finds the following percentages of unpopped kernels: 7, 13.2, 10, 6, 7.8, 2.8, 2.2, 5.2. Do the data provide evidence that the mean percentage of unpopped kernels is less than 10%? H 0 : μ  = 10 H A : μ  10 where μ is true unknown mean percentage of unpopped kernels

35.  n = 8; df = 7 Microwave Popcorn Reject H 0 : there is sufficient evidence that true mean percentage of unpopped kernels is less than 10%.02 0 H 0 : μ  = 10 H A : μ  10 -2. 51 t, 7 df Exact P-value =.02 Conf. Level0.10.30.50.70.80.90.950.980.99 Two Tail0.90.70.50.30.20.10.050.020.01 One Tail0.450.350.250.150.10.050.0250.010.005 dfValues of t 70.13030.40150.71111.11921.41491.89462.36462.99803.4995