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COURSE: JUST 3900 TIPS FOR APLIA Developed By: Ethan Cooper (Lead Tutor) John Lohman

COURSE: JUST 3900 TIPS FOR APLIA Developed By: Ethan Cooper (Lead Tutor) John Lohman Michael Mattocks Aubrey Urwick. Chapter 8 : Hypothesis Testing. Key Terms: Don’t Forget Notecards. Hypothesis Test (p. 233) Null Hypothesis (p. 236) Alternative Hypothesis (p. 236)

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COURSE: JUST 3900 TIPS FOR APLIA Developed By: Ethan Cooper (Lead Tutor) John Lohman

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  1. COURSE: JUST 3900 TIPS FOR APLIA Developed By: Ethan Cooper (Lead Tutor) John Lohman Michael Mattocks Aubrey Urwick Chapter 8: Hypothesis Testing

  2. Key Terms: Don’t Forget Notecards • Hypothesis Test (p. 233) • Null Hypothesis (p. 236) • Alternative Hypothesis (p. 236) • Alpha Level (level of significance) (pp. 238 & 245) • Critical Region (p. 238) • Type I Error (p. 244) • Type II Error (p. 245) • Statistically Significant (p. 251) • Directional (one-tailed) Hypothesis Test (p. 256) • Effect Size (p. 262) • Power (p. 265)

  3. Formulas • Standard Error of M: • z-Score Formula: • Cohen’s d: • estimated Cohen’s d:

  4. Logic of Hypothesis Testing • Question 1: The city school district is considering increasing class size in the elementary schools. However, some members of the school board are concerned that larger classes may have a negative effect on student learning. In words, what would the null hypothesis say about the effect of class size on student learning?

  5. Logic of Hypothesis Testing • Question 1 Answers: • For a two-tailed test: • The null hypothesis would say that class size has no effect on student learning. • The alternative hypothesis would say that class size does have an effect on student learning. • For a one-tailed test: • The null hypothesis would say that class size does not have anegativeeffect on student learning. • The alternative hypothesis would say that class size has a negativeeffect on student learning.

  6. Alpha Level and the Critical Region • Question 2: If the alpha level is decreased from α = 0.01 to α = 0.001, then the boundaries for the critical region move farther away from the center of the distribution. (True or False?)

  7. Alpha Level and the Critical Region • Question 2 Answer: • True. A smaller alpha level means that the boundaries for the critical region move further away from the center of the distribution.

  8. Possible Outcomes of a Hypothesis Test • Question 3: Define Type 1 and Type II Error.

  9. Possible Outcomes of a Hypothesis Test • Question 3 Answer: • Type I error is rejecting a true null hypothesis – that is, saying that treatment has an effect when, in fact, it doesn’t. • Type I error = false (+) = Alpha (α) = level of significance • Type II error is the failure to reject a null hypothesis. In terms of a research study, a Type II error occurs when a study fails to detect a treatment that really exists. • Type II error = false (-) = beta error = (β) A Type II error is likely to occur when a treatment effect is very small.

  10. Two-Tailed Hypothesis Test • Question 4: After years of teaching driver’s education, an instructor knows that students hit an average of µ = 10.5 orange cones while driving the obstacle course in their final exam. The distribution of run-over cones is approximately normal with a standard deviation of σ = 4.8. To test a theory about text messaging and driving, the instructor recruits a sample of n = 16 student drivers to attempt the obstacle course while sending a text message. The individuals in this sample hit an average of M = 15.9 cones. Do the data indicate that texting has a significant effect on driving? Test with α = 0.01.

  11. Two-Tailed Hypothesis Test • Question 4 Answer: • Step 1: State hypotheses • H0: Texting has no effect on driving. (µ = 10.5) • H1: Texting has an effect on driving. (µ ≠ 10.5) • Step 2: Set Criteria for Decision (α = 0.01) z = ± 2.58 Reject H0 Reject H0 z = - 2.58 z = 2.58

  12. Two-Tailed Hypothesis Test • Question 4 Answer: • Step 3: Compute sample statistic

  13. Two-Tailed Hypothesis Test • Question 4 Answer • Step 4: Make a decision • For a Two-tailed Test: • zsample(4.50) > zcritical (2.58) • Thus, we reject the null and note that texting has a significant effect on driving. • If -2.58 < zsample< 2.58, fail to reject H0 • If zsample ≤ -2.58 or zsample ≥ 2.58, reject H0

  14. Factors that Influence a Hypothesis Test • Question 5: If other factors are held constant, increasing the size of a sample increases the likelihood of rejecting the null hypothesis. (True or False?)

  15. Factors that Influence a Hypothesis Test • Question 5 Answer: • True. A larger sample produces a smaller standard error, which leads to a larger z-score. For, where , as sample size (n) increases, standard error () decreases, which then increases z. Consequently, as z increases so does the probability of rejecting the null hypothesis.

  16. Factors that Influence a Hypothesis Test • Question 6: If other factors remain constant, are you more likely to reject the null hypothesis with a standard deviation of σ = 2 or σ = 10?

  17. Factors that Influence a Hypothesis Test • Question 6 answer: • σ = 2. A smaller standard deviation produces a smaller standard error, which leads to a larger z-score. Thus, increasing the probability of rejecting the null hypothesis.

  18. One-tailed Hypothesis Test • Question 7: A researcher is testing the hypothesis that consuming a sports drink during exercise improves endurance. A sample of n = 50 male college students is obtained and each student is given a series of three endurance tasks and asked to consume 4 ounces of the drink during each break between tasks. The overall endurance score for this sample is M = 53. For the general population of male college students, without any sports drink, the scores average μ = 50 with a standard deviation of σ = 10. Can the researcher conclude that endurance scores with the sports drink are significantly higher than score without the drink? (Use a one-tailed test, α = 0.05)

  19. One-tailed Hypothesis Test • Question 7 Answer: • Step 1: State hypotheses • H0: Endurance scores are not significantly higher with the sports drink. (µ ≤ 50) • H1: Endurance scores are significantly higher with the sports drink. (µ > 50) • Step 2: Set Criteria for Decision (α = 0.05) z = 1.65 Reject H0 z = 1.65

  20. One-tailed Hypothesis Test • Question 7 Answer: • Step 3: Compute sample statistic

  21. One-tailed Hypothesis Test • Question 7 Answer: • Step 4: Make a decision • For a One-tailed Test: • zsample(2.13) > zcritical(1.65) • Thus, we reject the null and note that the sports drink does raise endurance scores. • If zsample≤ 1.65, fail to reject H0 • If zsample> 1.65, reject H0

  22. Effect Size and Cohen’s d • Question 8: A researcher selects a sample from a population with µ = 40 and σ = 8. A treatment is administered to the sample and, after treatment, the sample mean is found to be M = 47. Compute Cohen’s d to measure the size of the treatment effect.

  23. Effect Size and Cohen’s d • Question 8 Answer: • estimated Cohen’s d: • d= • This is a large effect. Remember: These are thresholds. Any effect less than d = 0.2 is a trivial effect and should be treated as having no effect. Any effect between d = 0.2 and d = 0.5 is a small effect. And between d = 0.5 and d = 0.8 is a medium effect.

  24. Computing Power • Question 9: A researcher is evaluating the influence of a treatment using a sample selected from a normally distributed population with a mean of µ = 100 and a standard deviation of σ = 20. The researcher expects a 10-point treatment effect and plans to use a two-tailed hypothesis test with α = 0.05. Compute the power of the test if the researcher uses a sample of n = 25 individuals.

  25. Computing Power • Question 9 Answer: • Step #1: Calculate standard error for sample • Step #2: Locate Boundary of Critical Region • 1.96 * 4 = 7.84 points • Thus, the critical boundary corresponds to M = 100 + 7.84 = 107.84. • Step #3: Calculate the z-score z = 1.96, for α = 0.05 Any sample mean greater than 107.84 falls in the critical region.

  26. Computing Power • Step #4: Interpret Power of the Hypothesis Test • Find probability associated with a z-score > - 0.54 • Look this probability up as the proportion in the body of the normal distribution (column B in your textbook) • p(z > -0.54) = 0.7054 • Thus, with a sample of 25 people and a 10-point treatment effect, 70.54% of the time the hypothesis test will conclude that there is a significant effect.

  27. Computing Power • Question 10: A researcher is evaluating the influence of a treatment using a sample selected from a normally distributed population with a mean of µ = 80 and a standard deviation of σ = 20. The researcher expects a 12-point treatment effect and plans to use a two-tailed hypothesis test with α = 0.05. Compute the power of the test if the researcher uses a sample of n = 25 individuals.

  28. Computing Power • Question 10 Answer: • Step #1: Calculate standard error for sample • Step #2: Locate Boundary of Critical Region • 1.96 * 4 = 7.84 points • Thus, the critical boundary corresponds to M = 80 + 7.84 = 87.84. • Step #3: Calculate the z-score z = 1.96, for α = 0.05 Any sample mean greater than 87.84 falls in the critical region.

  29. Computing Power • Question 10 Answer: • Step #4: Interpret Power of the Hypothesis Test • Find probability associated with a z-score > - 1.04 • Look this probability up as the proportion in the body of the normal distribution (column B in your textbook) • p(z > -1.04) = 0.8508 • Thus, with a sample of 25 people and a 12-point treatment effect, 85.08% of the time the hypothesis test will conclude that there is a significant effect.

  30. Frequently Asked Questions FAQs • What is power? • Power is the probability that a hypothesis test will reject the null hypothesis, if there is a treatment effect. • There are 4 steps involved in finding power. • Step #1: Calculate the standard error. • Step #2: Locate the boundary of the critical region. • Step #3: Calculate the z-score. • Step #4: Find the probability. • Using the example from the lecture notes, let’s go through each step. β is the probability of a type II error (false negative). Therefore, power is 1 – β.

  31. Frequently Asked Questions FAQs • The previous slide was based upon a study from your book with μ = 80, σ = 10, and a sample (n=25) that is drawn with an 8-point treatment effect (M=88). What is the power of the related statistical test for detecting the difference between the population and sample mean?

  32. Frequently Asked Questions FAQs • Step #1: Calculate standard error for sample • In this step, we work from the population’s standard deviation (σ) and the sample size (n)

  33. Frequently Asked Questions FAQs • Step #2: Locate Boundary of Critical Region • In this step, we find the exact boundary of the critical region • Pick a critical z-score based upon alpha (α =.05)

  34. Frequently Asked Questions FAQs • Step #3: Calculate the z-score for the difference between the treated sample mean (M=83.92) for the critical region boundary and the population mean with an 8-point treatment effect (μ = 88).

  35. Frequently Asked Questions FAQs • Interpret Power of the Hypothesis Test • Find probability associated with a z-score > - 2.04 • Look this probability up as the proportion in the body of the normal distribution (column B in your textbook) • p = .9793 • Thus, with a sample of 25 people and an 8-point treatment effect, 97.93% of the time the hypothesis test will conclude that there is a significant effect.

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