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Dr. McKirnan, Psychology 242

Revised 4/10/ 10. ( M group 1 - M group 2 ) - 0. t =. Dr. McKirnan, Psychology 242. Introduction to statistics # 2: Calculate t. Click anywhere to proceed. If this does not open as a running show, please go to “ S lide S how” and click “run show”. Statistical Hypothesis Testing.

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Dr. McKirnan, Psychology 242

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  1. Revised 4/10/10 (Mgroup1 - Mgroup2) - 0 t = Dr. McKirnan, Psychology 242 Introduction to statistics # 2: Calculate t Click anywhere to proceed. If this does not open as a running show, please go to “Slide Show” and click “run show”

  2. Statistical Hypothesis Testing • We use the t test (or any statistic) to test our hypothesis. • Part of the operational definition of our variables is the numbers we use to represent them. • What is our (statistical) hypothesis? • That the mean score (M) for the experimental group is greater than (or less than…) the M for the control group,and • …the difference is more than we might expect by chance alone. • What is the “null” hypothesis? • Any difference between the M for the experimental group and the M for the control group is by chance alone. • Mexperimental– Mcontrol = 0, except for chance (error variance) The research question (in statistical terms): • In our study, is the difference between the group Means (Mexp – Mcontrol)greater than (or less than…)0 by more than we would expect by chance alone?

  3. Statistical Hypothesis Testing The concept underlying the t test is the critical ratio: How strongly did the independent variable affect the outcome? How much error variance [“uncertainty”, “noise”] is there in the data For a t-test: The experimental effect is the difference between the Ms of the experimental & control groups The error variance is the square root of the summed variances of the groups, similar to a two-group standard deviation. (Mexp- Mcontrol) - 0 =t =

  4. (Mgroup1 - Mgroup2) - 0 t = (Mgroup1 - Mgroup2) - 0 t = t-test (Mgroup1 - Mgroup2) - 0 t = Difference between groups standard error of M = • How strong is the experimental effect? • How much error variance is there

  5. (Mgroup1 - Mgroup2) - 0 t = t-test (Mgroup1 - Mgroup2) - 0 t = Difference between groups standard error of M = • Standard error: • Calculate the variance for for group 1 • Sum of squares • Divided by degrees of freedom (n-1) • Divide by n for group 1 • Repeat for group 2 • Add them together • Take the square root

  6. (Mgroup1 - Mgroup2) - 0 t = (Mgroup1 - Mgroup2) - 0 t = t-test (Mgroup1 - Mgroup2) - 0 t = Difference between groups standard error of M = The expanded version…

  7. (Mgroup1 - Mgroup2) - 0 t = Compute a t score • Compute the Experimental Effect: • Calculate the Mean for each group, subtract group2M from group1M. • Compute the Standard Error • Calculate the variance for each group

  8. Calculate the Variance using the box method: 1. Enter the Scores. X 7 6 2 1 4 1 7 4 2 6 M4 4 4 4 4 4 4 4 4 4 X - M 3 2 -2 -3 0 -3 3 0 -2 2 Σ = 0 (X - M)2 9 4 4 9 0 9 9 0 4 4 Σ = 52 2. Calculate the Mean. 3. CalculateDeviation scores:  Simple deviations: Σ(X – M) = 0  Square the deviations to create + values: ΣSquares = Σ(X - M)2 = 52 4. Degrees of freedom: df = [n – 1] = [10 – 1] = 9 5. Apply the Varianceformula: n= 10 Σ= 40 M = 40/10 = 4

  9. (Mgroup1 - Mgroup2) - 0 t = Compute a t score effect error • Compute the Experimental Effect: • Calculate the Mean for each group, subtract group2M from group1M. • Compute the Standard Error • Calculate the variance for each group • Divide each variance by n for the group • Add those computations • Take the square root of that total • Compute t • Divide the Experimental Effect by the Standard Error

  10. The effect of error variance on t Critical ratio: any effect – e.g., the difference between group Ms – is attenuated when there is more error variance… This is reflected in different values of t. M = 2.5 M = 4 M1 – M2 = 4 – 2.5 = 1.5 Standard error = .75 = = 2 t = M1 – M2 = 4 – 2.5 = 1.5 Standarderror = 1.75 1.5 .75 1.5 1.75 t = = = .86 M = 2.5 M = 4

  11. Clicker! • Why does this have a t value = 2? • The difference between the group means is large relative to the variance within each group • The variance within each group is large relative to the difference between the group means. • The M of the larger group = 4 and there are 2 groups • t is a random number M = 2.5 M = 4

  12. Clicker! • Why does this have a t value = 2? • The difference between the group means is large relative to the variance within each group • The variance within each group is large relative to the difference between the group means. • The M of the larger group = 4 and there are 2 groups • t is a random number M = 2.5 M = 4 Between group variance is large compared to … …relatively small variance within groups

  13. Clicker, 2 • Why does this have a t value = .86? • The difference between the group means is large relative to the variance within each group • The variance within each group is large relative to the difference between the group means. • The M of the larger group = 4 and there are 2 groups • t is a random number M = 2.5 M = 4

  14. Clicker, 2 • Why does this have a t value = .86? • The difference between the group means is large relative to the variance within each group • The variance within each group is large relative to the difference between the group means. • The M of the larger group = 4 and there are 2 groups • t is a random number M = 2.5 M = 4 The variance between groups is the same, but … …it is small compared to the variance within each group

  15. Sampling distribution & statistical significance • Any 2 group Ms differ at least slightly by chance. • Any t score is therefore > 0 or < 0 by chance alone. • We assume that a t score with less than 5% probability of occurring [p < .05] is not by chance alone • We calculate the probability of a t score by comparing it to a sampling distribution • Look in your lecture notes for a discussion of sampling distributions

  16. What is a sampling distribution? -3 -2 -1 0 +1 +2 +3 Z or t Scores (standard deviation units) We can segment the population into standard deviation unitsfrom the mean. These are denoted as Z or t M = 0, 34.13% of scores from t = 0 to t = +1 and From t = 0 to t = -1 each standard deviation represents Z or t = 1 13.59% of scores + 13.59% of scores Each segment takes up a fixed % of cases (or “area under the curve”). 2.25% of scores + 2.25% of scores

  17. Sampling distributions and evaluating t scores To see how likely a given t score would be to occur by chance we compare it to this distribution A t score of 0 is 100% likely to occur by chance A t of +1 is greater than 84% of t scores, so will occur by chance 16% of the time. A t of +2 is greater than 98% of t scores, so will occur by chance only about 2% of the time.

  18. t scores and statistical significance, 1 t = = = 2 t = 2.0 Comparing t to a sampling distribution: About 98% of t values are lower than 2.0 M1 – M2 = 4 – 2.5 Standard error About 98% of t scores 1.5 .75 Sampling distribution of t scores

  19. t scores and statistical significance, 1 1.5 1.75 M1 – M2 = 4 – 2.5 Standarderror = = t = .86 t = .88 About 81% of the distribution of t scores are below .88. (area under the curve = .81) About 81% of scores Sampling distribution of t scores

  20. Between v. within group variance: t-test logic The difference between Ms is the same in the two data sets. t = .86 t = 2.0 Since the variances differ… • We get different t values • We make differ judgments about whether these t scores occurred by chance. About 98% of t scores; p < .05 About 81% of scores Sampling distribution of t scores

  21. Next You now have the t value for your experiment. Now go to the slide set on the central limit theorem to learn how to statistically test your t value. For the link go back to your assignment, or copy & paste the URL into your browser: http://www.uic.edu/classes/psych/psych242/Central limit theorum.ppsx

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