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Chapter 13 Introduction to Inference Essential Statistics Chapter 13 1 What We’ll Learn? <Part I> Confidence Interval Confidence level Margin of error Critical value Z* <Part II> Null hypothesis H0 Alternative hypothesis Ha Z test statistic P Value Significance level Essential Statistics Chapter 13 2 Statistical Inference Provides methods for drawing conclusions about a population from sample data – Confidence Intervals What is the population mean? – Gives an estimated range of value which is likely to include an unknown population parameter such as population mean µ Essential Statistics Chapter 13 3 Inference about a Mean Simple Conditions ◙ SRS from the population of interest ◙ Variable has a Normal distribution N(m, s) in the population ◙ Although the value of m is unknown, the value of the population standard deviation s is known Essential Statistics Chapter 13 4 Confidence Interval A level C confidence interval has two parts 1. An confidence interval usually has the form: estimate ± margin of error σ xz n 1. The confidence level C, which is the probability that the interval will capture the true parameter value in repeated samples; that is, C is the success rate for the method. Essential Statistics Chapter 13 5 Video references http://www.youtube.com/watch?v=Ohz-PZqaMtk http://www.youtube.com/watch?v=Q6Lj_8yt4Qk <short, brief define Confidence interval> http://www.youtube.com/watch?v=U59Rbpus824 Essential Statistics Chapter 13 6 Case Study NAEP Quantitative Scores (National Assessment of Educational Progress) Rivera-Batiz, F. L., “Quantitative literacy and the likelihood of employment among young adults,” Journal of Human Resources, 27 (1992), pp. 313-328. What is the average score for all young adult males? Essential Statistics Chapter 13 7 Case Study NAEP Quantitative Scores The NAEP survey includes a short test of quantitative skills, covering mainly basic arithmetic and the ability to apply it to realistic problems. Scores on the test range from 0 to 500, with higher scores indicating greater numerical abilities. It is known that NAEP scores have standard deviation s = 60. Essential Statistics Chapter 13 8 Case Study NAEP Quantitative Scores In a recent year, 840 men 21 to 25 years of age were in the NAEP sample. Their mean quantitative score was 272. On the basis of this sample, estimate the mean score m in the population of all 9.5 million young men of these ages. Essential Statistics Chapter 13 9 Case Study NAEP Quantitative Scores 1. 2. 3. To estimate the unknown population mean m, use the sample mean x = 272. The law of large numbers suggests that x will be close to m, but there will be some error in the estimate. distribution of x has the Normal The sampling distribution with mean m and standard deviation s 60 2.1 n 840 Essential Statistics Chapter 13 10 Case Study NAEP Quantitative Scores Essential Statistics Chapter 13 11 Case Study NAEP Quantitative Scores 4. The 68-95-99.7 rule indicates that x and m are within two standard deviations (4.2) of each other in about 95% of all samples. x 4 .2 = 2 7 2 4 .2 = 2 6 7 .8 x + 4 .2 = 2 7 2 + 4 .2 = 2 7 6 .2 Essential Statistics Chapter 13 12 Case Study NAEP Quantitative Scores So, if we estimate that m lies within 4.2 of we’ll be right about 95% of the time. Essential Statistics Chapter 13 x, 13 Confidence Interval Mean of a Normal Population Take an SRS of size n from a Normal population with unknown mean m and known standard deviation s. A level C confidence interval for m is: xz σ n z* is called the critical value, and z* and –z* mark off the Central area C under a standard normal curve (next slide); values of z* for many choices of C can be found at the bottom of Table C in the back of the textbook, and the most common values are on the next slide. Essential Statistics Chapter 13 14 Confidence Interval Mean of a Normal Population Confidence Level C Critical Value z* 90% 1.645 95% 1.960 99% 2.576 Essential Statistics Chapter 13 15 Case Study NAEP Quantitative Scores Using the 68-95-99.7 rule gave an approximate 95% confidence interval. A more precise 95% confidence interval can be found using the appropriate value of z* (1.960) with the previous formula. x (1 .9 6 0 )(2 . 1 ) = 2 7 2 4 .1 1 6 = 2 6 7 .8 8 4 x (1 .9 6 0 )(2 . 1 ) = 2 7 2 4 .1 1 6 = 2 7 6 .1 1 6 We are 95% confident that the average NAEP quantitative score for all adult males is between 267.884 and 276.116. Essential Statistics Chapter 13 16 Express Confidence Interval The confidence level describes the uncertainty associated with a sampling method A 95% confidence level means that we would expect 95% of the interval estimates to include the population parameter To express a confidence interval, you need three pieces of information. ◙ Confidence level ◙ Statistic ◙ Margin of error Essential Statistics Chapter 13 17 Construct A Confidence Interval Identify a sample statistic. Locate the statistic (e.g, mean, standard deviation) Select a confidence level, choose 90%, 95%, or 99% confidence levels or others Find the margin of error: Margin of error = Critical value x Standard deviation of statistic xz σ n Confidence interval = sample statistic + margin of error Essential Statistics Chapter 13 18 Exercise 1 Suppose we want to estimate the average weight of an adult male in Dekalb County, GA. We draw a random sample of 1,000 men from a population of 1,000,000 men and weigh them. We find that the average weighs in sample is 180 pounds, and the standard deviation is 30 pounds. What is the 95% confidence interval. (A) 180 + 1.86 (B) 180 + 3.0 (C) 180 + 5.88 (D) 180 + 30 Essential Statistics Chapter 13 19 Hypothesis Test & P Value Hypothesis, H0, Ha Significance Sample P-value Conclusion From sample mean to draw an conclusion about population mean Essential Statistics Chapter 13 20 Stating Hypotheses Null Hypothesis, H0 The statement being tested in a statistical test is called the null hypothesis. Usually the null hypothesis is a statement of “no effect” or “no difference”, or it is a statement of equality. When performing a hypothesis test, we assume that the null hypothesis is true until we have sufficient evidence against it. Essential Statistics Chapter 13 21 Stating Hypotheses Alternative Hypothesis, Ha The statement we are trying to find evidence for is called the alternative hypothesis. Usually the alternative hypothesis is a statement of “there is an effect” or “there is a difference”, or it is a statement of inequality. The alternative hypothesis is what we are trying to prove. Essential Statistics Chapter 13 22 Case Study I Sweetening Colas Diet colas use artificial sweeteners to avoid sugar. These sweeteners gradually lose their sweetness over time. Trained testers sip the cola and assign a “sweetness score” of 1 to 10. The cola is then retested after some time and the two scores are compared to determine the difference in sweetness after storage. Bigger differences indicate bigger loss of sweetness. Essential Statistics Chapter 13 23 Case Study I Sweetening Colas Suppose we know that for any cola, the sweetness loss scores vary from taster to taster according to a Normal distribution with standard deviation s = 1. The mean m for all tasters measures loss of sweetness. The sweetness losses for a new cola, as measured by 10 trained testers, yields an average sweetness loss of x = 1.02. Do the data provide sufficient evidence that the new cola lost sweetness in storage? Essential Statistics Chapter 13 24 Case Study I Sweetening Colas If the claim that m = 0 is true (no loss of sweetness, on average), the sampling distribution of x from 10 tasters is Normal with m = 0 and standard deviation σ 1 0 .3 1 6 n 10 The data yielded x= 1.02, which is more than three standard deviations from m = 0. This is strong evidence that the new cola lost sweetness in storage. If the data yielded x= 0.3, which is less than one standard deviations from m = 0, there would be no that the new cola lost sweetness in storage. evidence Essential Statistics Chapter 13 25 Case Study I Sweetening Colas Essential Statistics Chapter 13 26 The Hypotheses for Means Null: H0: m = m0 One sided alternatives Ha: m >m0 Ha: m <m0 Two sided alternative Ha: m m0 Essential Statistics Chapter 13 27 Case Study I Sweetening Colas The null hypothesis is no average sweetness loss occurs, while the alternative hypothesis (that which we want to show is likely to be true) is that an average sweetness loss does occur. H0: m = 0 Ha: m > 0 This is considered a one-sided test because we are interested only in determining if the cola lost sweetness (gaining sweetness is of no consequence in this study). Essential Statistics Chapter 13 28 Case Study II Studying Job Satisfaction Does the job satisfaction of assembly workers differ when their work is machine-paced rather than self-paced? A matched pairs study was performed on a sample of workers, and each worker’s satisfaction was assessed after working in each setting. The response variable is the difference in satisfaction scores, selfpaced minus machine-paced. Essential Statistics Chapter 13 29 Case Study II Studying Job Satisfaction The null hypothesis is no average difference in scores in the population of assembly workers, while the alternative hypothesis (that which we want to show is likely to be true) is there is an average difference in scores in the population of assembly workers. H0: m = 0 Ha: m ≠ 0 This is considered a two-sided test because we are interested determining if a difference exists (the direction of the difference is not of interest in this study). Essential Statistics Chapter 13 30 Test Statistic Testing the Mean of a Normal Population Take an SRS of size n from a Normal population with unknown mean m and known standard deviation s. The test statistic for hypotheses about the mean (H0: m = m0) of a Normal distribution is the standardized version of x: x μ0 z σ n Essential Statistics Chapter 13 31 Case Study I Sweetening Colas If the null hypothesis of no average sweetness loss is true, the test statistic would be: x μ0 1.02 0 z 3.23 σ 1 10 n Because the sample result is more than 3 standard deviations above the hypothesized mean 0, it gives strong evidence that the mean sweetness loss is not 0, but positive. Essential Statistics Chapter 13 32 P-value ■ The p-value is the probability or area marked by the test statistic z (from sample) in the normal distribution curve when assuming that the null hypothesis is true. ■ The smaller the p-value, the more significant is the difference between the null hypothesis and the sample results. ■ The smaller the P-value, the stronger the evidence the data provide against the null hypothesis. Essential Statistics Chapter 13 33 P-value for Testing Means Ha: m> m0 when Ha contains “greater than” symbol, Perform a Right- tailed test P-value is the probability of getting a value as large or larger than the observed test statistic (z) value. Ha: m< m0 when Ha contains “less than” symbol, Perform a Left-tailed test P-value is the probability of getting a value as small or smaller than the observed test statistic (z) value. Ha: mm0 when Ha contains “not equal to” symbol, Perform a Two-tailed test P-value is two times the probability of getting a value as large or larger than the absolute value of the observed test statistic (z) value. Essential Statistics Chapter 13 34 Essential Statistics Chapter 13 35 Case Study I Sweetening Colas For test statistic z = 3.23 and alternative hypothesis Ha: m > 0, the P-value would be: P-value = P(Z ≥ 3.23) = 1 – 0.9994 = 0.0006 If H0 is true, there is only a 0.0006 (0.06%) chance that we would see results at least as extreme as those in the sample; thus, since we saw results that are unlikely if H0 is true, we therefore have evidence against H0 and in favor of Ha. Essential Statistics Chapter 13 36 Case Study I Sweetening Colas Essential Statistics Chapter 13 37 Case Study II Studying Job Satisfaction Suppose job satisfaction scores follow a Normal distribution with standard deviation s = 60. Data from 18 workers gave a sample mean score of 17. If the null hypothesis of no average difference in job satisfaction is true, the test statistic would be: x μ0 17 0 z 1.20 σ 60 n 18 Essential Statistics Chapter 13 38 Case Study II Studying Job Satisfaction For test statistic z = 1.20 and alternative hypothesis Ha: m ≠ 0, the P-value would be: P-value = P(Z < -1.20 or Z > 1.20) = 2 P(Z < -1.20) = 2 P(Z > 1.20) = (2)(0.1151) = 0.2302 If H0 is true, there is a 0.2302 (23.02%) chance that we would see results at least as extreme as those in the sample; thus, since we saw results that are likely if H0 is true, we therefore do not have good evidence against H0 and in favor of Ha. Essential Statistics Chapter 13 39 Case Study II Studying Job Satisfaction Essential Statistics Chapter 13 40 Statistical Significance α If the P-value is as small as or smaller than the significance level a (i.e., P-value ≤ a), then we say that the data give results that are statistically significant at level a. “Rejects the null hypothesis" when the p-value is less than the significance level α If we choose a = 0.05, we are requiring that the data give evidence against H0 so strong that it would occur no more than 5% of the time when H0 is true. If we choose a = 0.01, we are insisting on stronger evidence against H0, evidence so strong that it would occur only 1% of the time when H0 is true. Essential Statistics Chapter 13 41 Tests Procedure for a Population Mean The five steps in carrying out a significance test: 1. State the null and alternative hypotheses. 2. Set the level of significance, usually ɑ = 0.05 3. Take a sample from population and provide the Z test statistic. 4. Locate the P-value from Table A. 5. Using P-value compare with ɑ to reject null hypothesis if P-value < ɑ Essential Statistics Chapter 13 42 Case Study I Sweetening Colas 1. Hypotheses: 2. Test Statistic: H 0: m = 0 H a: m > 0 z x μ0 σ 1.02 0 1 n 3. 4. 3.23 10 P-value: P-value = P(Z > 3.23) = 1 – 0.9994 = 0.0006 Conclusion: Since the P-value is smaller than a = 0.01, there is very strong evidence that the new cola loses sweetness on average during storage at room temperature. Essential Statistics Chapter 13 43 Case Study II Studying Job Satisfaction 1. Hypotheses: 2. Test Statistic: H 0: m = 0 H a: m ≠ 0 z x μ0 σ 17 0 60 n 3. 4. 1.20 18 P-value: P-value = 2P(Z > 1.20) = (2)(1 – 0.8849) = 0.2302 Conclusion: Since the P-value is larger than a = 0.10, there is not sufficient evidence that mean job satisfaction of assembly workers differs when their work is machine-paced rather than self-paced. Essential Statistics Chapter 13 44 Case Study II Studying Job Satisfaction A 90% confidence interval for m is: xz σ n 17 1.645 60 17 23.26 18 6.26 to 40.26 Since m0 = 0 is in this confidence interval, it is plausible that the true value of m is 0; thus, there is not sufficient evidence (at a = 0.10) that the mean job satisfaction of assembly workers differs when their work is machine-paced rather than self-paced. Essential Statistics Chapter 13 45 Interesting Video http://www.youtube.com/watch?v=l9ueYYpYU_s <Tailed test> http://www.youtube.com/watch?v=BX9iMIC6mcg <Five Steps> http://www.youtube.com/watch?v=cW16A7hXbTo <P-Value> Essential Statistics Chapter 13 46