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would require a sample size of approximately 126. As R emphasizes, this sample size is per group, so the total sample size required is 126(2) = 252.

r r 2 d
0.10 0.01 0.20
0.20 0.04 0.41
0.30 0.09 0.63
0.40 0.16 0.87
0.50 0.25 1.15
0.60 0.36 1.50
0.70 0.49 1.96
0.80 0.64 2.67
0.90 0.81 4.13
0.99 0.98 14.04
Graph depicts the relationship between Cohen's d and R-squared.

Treatment 1 Treatment 2
Block 1 10 8
Block 2 15 12
Block 3 20 14
Block 4 22 15
Block 5 25 24

      About Table 2.8:

       In each block (1 through 5), participants within blocks are assumed to be more homogeneous on one or more variables than participants between blocks.

       Participants are randomly assigned to condition (i.e., treatment 1 versus treatment 2) within each block.

       Whether the blocks are naturally occurring or our sampling scheme is designed purposely to create the blocks, we can exploit the homogeneity of participants within each block by including this source in our statistical analysis as to potentially reduce the error term of our statistical test.

       The matched‐pairs design is a simpler version of the full‐blown randomized block design in which one can have more than just two levels of the independent variable (e.g., treatment 1 versus treatment 2 versus treatment 3). However, the principle behind the matched-pairs design and that of randomized block designs is the same, that of exploiting the covariance between conditions and removing it from the error term of the test statistic (t in matched‐pairs, F in randomized block designs).

       In more advanced analyses such as repeated measures, longitudinal, and mixed effects modeling, we will say that subjects are nested within block. A nesting structure simply implies that subjects within a block share similarity compared to subjects between blocks. Good statistical analyses will attempt to account for this similarity, remove it from respective error terms for tests, and hence make the statistical test for effects more sensitive (i.e., more powerful).

      When we sample observations in pairs, as was true for the independent samples t‐test, the expectation of the difference between sample means is given by:

equation

      However, because observations are sampled (or “matched”) in pairs, we naturally expect there to be a covariance different from zero between pairs. We can exploit this covariance and remove it from the error term of our statistical test. As given in Hays (1994, p. 339), the variance of the difference becomes

equation equation

      Notice that we have subtracted images from the denominator of our statistic. Assuming the covariance between pairs is unequal to 0, this will serve to lower the standard error of our statistic, and hence, boost statistical power. In practice, this is accomplished by conducting a t‐test on the difference scores between samples. As Hays (1994, p. 339) notes, “the matching and the consequent dependence within the pairs changes the standard error of the difference between the sample means.”

      In the classic between‐subjects design where participants are not matched, the expectation is that covariance between treatments is equal to 0, and hence, we would have:

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