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The GLM Procedure

Example 39.3 Unbalanced ANOVA for Two-Way Design with Interaction

This example uses data from Kutner (1974, p. 98) to illustrate a two-way analysis of variance. The original data source is Afifi and Azen (1972, p. 166). These statements produce Output 39.3.1 and Output 39.3.2.

   title 'Unbalanced Two-Way Analysis of Variance';
   data a;
      input drug disease @;
      do i=1 to 6;
         input y @;
         output;
      end;
      datalines;
   1 1 42 44 36 13 19 22
   1 2 33  . 26  . 33 21
   1 3 31 -3  . 25 25 24
   2 1 28  . 23 34 42 13
   2 2  . 34 33 31  . 36
   2 3  3 26 28 32  4 16
   3 1  .  .  1 29  . 19
   3 2  . 11  9  7  1 -6
   3 3 21  1  .  9  3  .
   4 1 24  .  9 22 -2 15
   4 2 27 12 12 -5 16 15
   4 3 22  7 25  5 12  .
   ;
   proc glm;
      class drug disease;
      model y=drug disease drug*disease / ss1 ss2 ss3 ss4;
   run;

Output 39.3.1 Classes and Levels for Unbalanced Two-Way Design
Unbalanced Two-Way Analysis of Variance

The GLM Procedure

Class Level Information
Class Levels Values
drug 4 1 2 3 4
disease 3 1 2 3

Number of Observations Read 72
Number of Observations Used 58

Output 39.3.2 Analysis of Variance for Unbalanced Two-Way Design
Unbalanced Two-Way Analysis of Variance

The GLM Procedure
 
Dependent Variable: y

Source DF Sum of Squares Mean Square F Value Pr > F
Model 11 4259.338506 387.212591 3.51 0.0013
Error 46 5080.816667 110.452536    
Corrected Total 57 9340.155172      

R-Square Coeff Var Root MSE y Mean
0.456024 55.66750 10.50964 18.87931

Source DF Type I SS Mean Square F Value Pr > F
drug 3 3133.238506 1044.412835 9.46 <.0001
disease 2 418.833741 209.416870 1.90 0.1617
drug*disease 6 707.266259 117.877710 1.07 0.3958

Source DF Type II SS Mean Square F Value Pr > F
drug 3 3063.432863 1021.144288 9.25 <.0001
disease 2 418.833741 209.416870 1.90 0.1617
drug*disease 6 707.266259 117.877710 1.07 0.3958

Source DF Type III SS Mean Square F Value Pr > F
drug 3 2997.471860 999.157287 9.05 <.0001
disease 2 415.873046 207.936523 1.88 0.1637
drug*disease 6 707.266259 117.877710 1.07 0.3958

Source DF Type IV SS Mean Square F Value Pr > F
drug 3 2997.471860 999.157287 9.05 <.0001
disease 2 415.873046 207.936523 1.88 0.1637
drug*disease 6 707.266259 117.877710 1.07 0.3958

Note the differences among the four types of sums of squares. The Type I sum of squares for drug essentially tests for differences between the expected values of the arithmetic mean response for different drugs, unadjusted for the effect of disease. By contrast, the Type II sum of squares for drug measures the differences between arithmetic means for each drug after adjusting for disease. The Type III sum of squares measures the differences between predicted drug means over a balanced drugdisease population—that is, between the LS-means for drug. Finally, the Type IV sum of squares is the same as the Type III sum of squares in this case, since there are data for every drug-by-disease combination.

No matter which sum of squares you prefer to use, this analysis shows a significant difference among the four drugs, while the disease effect and the drug-by-disease interaction are not significant. As the previous discussion indicates, Type III sums of squares correspond to differences between LS-means, so you can follow up the Type III tests with a multiple-comparison analysis of the drug LS-means. Since the GLM procedure is interactive, you can accomplish this by submitting the following statements after the previous ones that performed the ANOVA.

      lsmeans drug / pdiff=all adjust=tukey;
   run;

Both the LS-means themselves and a matrix of adjusted -values for pairwise differences between them are displayed; see Output 39.3.3 and Output 39.3.4.

Output 39.3.3 LS-Means for Unbalanced ANOVA
Unbalanced Two-Way Analysis of Variance

The GLM Procedure
Least Squares Means
Adjustment for Multiple Comparisons: Tukey-Kramer

drug y LSMEAN LSMEAN Number
1 25.9944444 1
2 26.5555556 2
3 9.7444444 3
4 13.5444444 4

Output 39.3.4 Adjusted -Values for Pairwise LS-Mean Differences
Least Squares Means for effect drug
Pr > |t| for H0: LSMean(i)=LSMean(j)
Dependent Variable: y
i/j 1 2 3 4
1   0.9989 0.0016 0.0107
2 0.9989   0.0011 0.0071
3 0.0016 0.0011   0.7870
4 0.0107 0.0071 0.7870  

The multiple-comparison analysis shows that drugs 1 and 2 have very similar effects, and that drugs 3 and 4 are also insignificantly different from each other. Evidently, the main contribution to the significant drug effect is the difference between the 1/2 pair and the 3/4 pair.

If you enable ODS Graphics for the previous analysis, GLM also displays three additional plots by default:

The following statements reproduce the previous analysis with ODS Graphics enabled. Additionally, the PLOTS=MEANPLOT(CL) option specifies that confidence limits for the LS-means should also be displayed in the mean plot. The graphical results are shown in Output 39.3.5 through Output 39.3.7.

   ods graphics on;
   proc glm plot=meanplot(cl);
      class drug disease;
      model y=drug disease drug*disease;
      lsmeans drug / pdiff=all adjust=tukey;
   run;
   ods graphics off;

Output 39.3.5 Plot of Response by Drug and Disease
Plot of Response by Drug and Disease

Output 39.3.6 Plot of Response LS-Means for Drug
Plot of Response LS-Means for Drug

Output 39.3.7 Plot of Response LS-Mean Differences for Drug
Plot of Response LS-Mean Differences for Drug

The significance of the drug differences is difficult to discern in the original data, as displayed in Output 39.3.5, but the plot of just the LS-means and their individual confidence limits in Output 39.3.6 makes it clearer. Finally, Output 39.3.7 indicates conclusively that the significance of the effect of drug is due to the difference between the two drug pairs (1, 2) and (3, 4).

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