Hypothesis Testing

1. Hypothesis Testing Comparing One Sample to its Population

2. Hypothesis Testing w/ One Sample • If the population mean (μ) and standard deviation (σ) are known: • Testing if our sample mean ( ) is significantly different from our sampling distribution of the mean • Similar to testing if how different an individual score is from other scores in the sample • What is this test called?

3. Hypothesis Testing w/ One Sample • z-score formula [for an individual score (x)] = • z-score formula [for means ( )] =

4. Hypothesis Testing w/ One Sample • Testing score versus standard deviation for an distribution of scores • Testing mean versus standard deviation for distribution of sample means • I.e. standard error

5. Hypothesis Testing w/ One Sample • Two implications of this formula: • 1. Because we are dividing by N (actually √N), with the same data (same sample & population mean and σ), but larger sample size, our p-value will be smaller (i.e. more likely to be significant) • All statistical tests that produce p-values will be sensitive to sample size – i.e. with enough people anything is significant at p < .05

6. Hypothesis Testing w/ One Sample • Two implications of this formula: • 2. If you recall, this formula was derived from the formula for the normal distribution • This means that your data must be normally distributed to use this test validly • However, this test is robust to violations of this assumption – i.e. you can violate it, if you have (a) a large enough sample or (b) your population data is normally distributed • Why?

7. Hypothesis Testing w/ One Sample • The Central Limit Theorem: Given a population with mean μ and variance σ2, the sampling distribution of the mean (the distribution of sample means) will have a mean equal to μ (i.e., μ = μ) and a variance (σ2) equal to σ2/N (and standard deviation, σ = σ/√N). The distribution will approach the normal distribution as N, the sample size, increases.

8. Hypothesis Testing w/ One Sample • Example #1: • You want to test the hypothesis that the current crop of Kent State freshman are more depressed than Kent State undergraduates in general. • What is your sample and what is your population? • What is your Ho and your H1? • Are you using a one- or two-tailed test? • Assuming that for current Kent State freshman, their mean depression score is 15, while the mean for all previous Kent State undergrads (N = 100,000) is 10, and their standard deviation is 5

9. Hypothesis Testing w/ One Sample = 5/.0158 = 316.46 • Look up p associated with z-score in z-table • p < 0.0000 • Since this is less than .05 (or .025 if we were using a two-tailed test), we could conclude that the current batch of freshman are significantly more depressed than previous undergrads • Also notice the effect that our large N had on our p-value

10. Hypothesis Testing w/ One Sample • Most often, however, we don’t know the μ and σ, because this is what we’re trying to estimate with our sample in the first place • The formula for the t statistic accomplishes this by substituting s2 for σ2 in the formula for the z statistic • Because of this substitution, we have a different statistic, which requires that we use a different table than the z-table • Don’t worry too much about why it’s different

11. Hypothesis Testing w/ One Sample • Testing mean versus standard deviation for distribution of sample means • I.e. standard error • Testing mean versus standard deviation for sample

12. Hypothesis Testing w/ One Sample • After computing our t statistic, we need to compare it with the t-table (called the Student’s T-Table) • “Student” is a pseudonym for William Gosset • Gosset worked for the Guiness Brewing Company, but they wouldn’t let him publish under his own name • First, we will need to become familiar with the concept of degrees of freedom or df • df = N – 1 • This represents the number of individual subjects data points that are free to vary, if you know the mean or s already

13. Hypothesis Testing w/ One Sample • For example: • If we already know that a particular set of data has a mean of 5, and 10 scores in total (n = 10) • Once we have nine of those scores, we can calculate the tenth, however, if we have eight scores we do not know what the other two scores could be • We can solve x + 5 = 10, but not x + y = 10, because in the latter we have more than one unknown (x and y) • x and y could be 5 and 5, 8 and 2, 4 and 6, 7 and 3, etc. • Therefore, nine scores are free to vary, then the tenth is fixed

14. Hypothesis Testing w/ One Sample • Factors that influence the z and t statistics: • The difference between the sample mean and population mean – greater differences = greater t and z values • The magnitude of s (or s2) – since we’re dividing by s, smaller values of s result in larger values of t or z [i.e. we want to decrease variability in our sample (error)] • The sample size – the bigger the bigger t and z • The significance level (α) – the smaller the α, the higher the critical t to reject Ho – although raising α also raises our Type I Error, so we probably won’t want to do this without good reason • Whether the test is one- or two-tailed – two-tailed tests split α into two tails of p< .025, instead of one tail at p < .05

15. General Approach to Hypothesis Testing 1. Identify H0 and H1 2. Calculate df and identify the critical test statistic 3. Determine whether to use one- or two-tailed test, determine what value of α to use (usually .05), and identify the rejection region(s) that the critical statistic is the boundary of 4. Calculate your obtained test statistic 7. Compare your value of your test statistic to your rejection region to determine whether or not to reject H0

16. Hypothesis Testing w/ One Sample • Example #1: • You’ve administered a therapy for people with anorexia that will supposedly assist them in gaining weight. The following data are amount of weight gained in pounds over your 16 session therapy for 29 participants. Does this represent a significantly increased degree of weight gain compared to the average weight gained without treatment (-.45 lbs.)? • What are Ho and H1? • Will you be using a one- or two-tailed test? Why? • Based on this, what is your df?

17. Hypothesis Testing w/ One Sample • Example #1:

18. Hypothesis Testing w/ One Sample • Example #1: • Sample Mean = 87.2/29 = 3.0069 s2 = (1757.8 – [(87.2)2/29])/ 28 = 53.41 s = 7.3085 t = (3.0069 - -.45)/(7.3085/√29) = 2.5472, p < .05 • t > Critical t and in our rejection region, which is above the population mean (since we’re only interested in people gaining weight), therefore we reject Ho and conclude that our treatment is more effective than no treatment at all

19. Hypothesis Testing w/ One Sample • Often, if we’re reporting the results of our experiments to the public, or the results of an assessment (psychological or otherwise) to a client, we want to emphasize to them that our measurements are made with error, or that our samples include sampling error • We can do this by including intervals around the scores we report, indicating that the “true” score measured without error lies in this interval

20. Hypothesis Testing w/ One Sample • This is what is known as a Confidence Interval • In keeping with the p < .05 tradition, we are often looking for the 95% confidence interval, or the scores that 95% of our distribution lie, but we can do this for any interval • They are calculated just like for z-scores, where we plug the t values into the formula and work backwards

21. Hypothesis Testing w/ One Sample • For a 95% CI: • Given your df (we’ll assume df = 9 for this example) and type of test (assume a two-tailed test for now), look up your critical values of t from a t-table (t = ± 2.262) • Plug into your formula with your Sample Mean and s (which we’ll assume are 1.463 and .341, respectively), and solve for μ

22. Hypothesis Testing w/ One Sample • For a 95% CI: ± 2.262 = (1.463 – μ)/(.341/√10) μ = ±2.262(.108) + 1.463 = ±.244 + 1.462 .244 + 1.463 = 1.707 -.244 + 1.463 = 1.219 • CI.95 = 1.219 ≤ μ ≤ 1.707