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LECTURE 14 ANALYSIS OF VARIANCE EPSY 640 Texas A&M University.

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1 LECTURE 14 ANALYSIS OF VARIANCE EPSY 640 Texas A&M University

2 Multigroup experimental design PURPOSES: –COMPARE 3 OR MORE GROUPS SIMULTANEOUSLY –TAKE ADVANTAGE OF POWER OF LARGER TOTAL SAMPLE SIZE –CONSTRUCT MORE COMPLEX HYPOTHESES THAT BETTER REPRESENT OUR PREDICTIONS

3 Multigroup experimental design PROCEDURES –DEFINE GROUPS TO BE STUDIES: Experimental Assignment VS Intact or Existing Groups –OPERATIONALIZE NOMINAL, ORDINAL, OR INTERVAL/RATIO MEASUREMENT OF GROUPS eg. Nominal: SPECIAL ED, LD, AND NON- LABELED Ordinal: Warned, Acceptable, Exemplary Schools Interval: 0 years’, 1 years’, 2 years’ experience

4 Multigroup experimental design PATH REPRESENTATION Treat y e R y.T

5 Multigroup experimental design PATH REPRESENTATION Treat y e R y.T = √(493.87/39986) =.111  101.262 = 10.1 = std dev. Of errors

6 Multigroup experimental design VENN DIAGRAM REPRESENTATION SSy Treat SS SStreat SSerror R 2 =SStreat/SSy

7 Multigroup experimental design VENN DIAGRAM REPRESENTATION SSy = 39986 Treat SS SStreat = 493 SSerror = 39492 R 2 =SStreat/SSy =.111

8 Multigroup experimental design dummy coding. Since the values are arbitrary we can use any two numerical values, much as we can name things arbitrarily: 0 or 1 (you are in a group or not) –compares each group to a baseline group) Another nominal assignment of values is 1 and –1, called contrast coding: -1 = control, 1=experimental group Places groups above (+1) or below (-1) the average of all groups (grand mean)

9 Multigroup experimental design dummy coding. Since the values are arbitrary we can use any two numerical values, much as we can name things arbitrarily: 0 or 1 (you are in a group or not) Example: Hispanics=2, African Americans= 3, Whites=5 Recode: H AA W 1 0 0 codes for Hispanics 0 1 0 codes for AA’s 0 0 0 codes for Whites Need only two of the columns to specify a person

10 Multigroup experimental design Another nominal assignment of values is 1,0, and –1, called contrast coding: -1 = control, 1=experimental group Places groups above (+1) or below (-1) the average of all groups (grand mean) HAAW 1 0 0 0 1 0 -1 -1 0 Only two columns needed

11 Multigroup experimental design Another nominal assignment of values is 1,0, and –1, called contrast coding: -1 = control, 1=experimental group Places groups above (+1) or below (-1) the average of all groups (grand mean) HAAW 1 0 0 0 1 0 -1 -1 0 Only two columns needed: EQUIVALENT TO TWO PREDICTORS, THE HISPANIC VS. WHITE DIFFERENCE AND THE AFRICAN-AMERICAN VS. WHITE DIFFERENCE H A Y

12 Multigroup experimental design NOMINAL: If the three are simply different treatments or conditions then there is no preferred labeling, and we can give them values 1, 2, and 3 Forms: –arbitrary (A,B,C) –interval (1,2,3) assumes interval quality to groups such as amount of treatment –Contrast (-2, 1, 1) compares groups –Dummy (1, 0, 0), different for each group

13 Dummy Coding Regression Vars Subject Treatmentx 1 x 2 y 01A1017 02A1019 03B0122 04B0127 05C0033 06C0021

14 Contrast Coding Regression Vars Subject Treatmentx 1 x 2 y 01A1017 02A1019 03B0 122 04B0 127 05C -1 -133 06C -1 -121

15 Hypotheses about Means The usual null hypothesis about three group means is that they are all equal: H 0 :  1 =  2 =  3 while the alternative hypothesis is typically represented as H 1 :  i   j for some i,j.

16 ANOVA TABLE SOURCEdf Sum Mean SquareF of Squares Treatment…k-1Ss treat SS treat / k-1(SS treat / k )/(SS e /k(n-1)) error k(n-1)SseSS e / k(n-1) no test total kn-1SsySS y / (n-1) Table 9.2: Analysis of variance table for Sums of Squares

17 ANOVA concepts 1. Compare Variance(treatment + error) to Variance(error): MS treat /MS error 2. If treatment variance=0, then both estimate sampling variation in the population of individuals; the group means (recall sampling lecture) have a variance equal to error variance/kgroups, so 3. VAR(group means) = Var(error)/n, n=#scores per group and 4. n*Var(group means) = MS treat = Var(error)

18

19 F-DISTRIBUTION Fig. 9.5: Central and noncentral F-distributions alpha Central F-distribution power

20 ANOVA TABLE QUIZ SOURCEDFSSMSF PROB GROUP__10050_____ ERROR_____20 TOTAL20R 2 = ____

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