Rank-Biserial Correlation

The standardized effect size reported for the wilcox_TOST procedure is the rank-biserial correlation. This is a fairly intuitive measure of effect size which has the same interpretation of the common language effect size (Kerby 2014). However, instead of assuming normality and equal variances, the rank-biserial correlation calculates the number of favorable (positive) and unfavorable (negative) pairs based on their respective ranks.

Overall, the correlation is calculated as the proportion of favorable pairs minus the unfavorable pairs.

\[ r_{biserial} = f_{pairs} - u_{pairs} \]

Confidence Intervals

The Fisher approximation is used to calculate the confidence intervals.

For paired samples the standard error is calculated as the following:

\[ SE_r = \sqrt{ \frac {(2 \cdot nd^3 + 3 \cdot nd^2 + nd) / 6} {(nd^2 + nd) / 2} } \]

wherein, nd represents the total count not equal to zero.

For independent samples, the standard error is calculated as the following:

\[ SE_r = \sqrt{\frac {(n1 + n2 + 1)} { (3 \cdot n1 \cdot n2)}} \]

The confidence intervals can then be calculated by transforming the estimate.

\[ r_z = atanh(r_{biserial}) \]

Then the confidence interval can be calculated and back transformed.

\[ r_{CI} = tanh(r_z \pm Z_{(1 - \alpha / 2)} \cdot SE_r) \]

We hope a bootstrapped version of this confidence interval will be added in future updates.

Two Sample Algorithm

1. Form B bootstrap data sets from x* and y* wherein x* is sampled with replacement from \(\tilde x_1,\tilde x_2, ... \tilde x_n\) and y* is sampled with replacement from \(\tilde y_1,\tilde y_2, ... \tilde y_n\)

2. t is then evaluated on each sample, but the mean of each sample (y or x) and the overall average (z) are subtracted from each

\[ t(z^{*b}) = \frac {(\bar x^*-\bar x - \bar z) - (\bar y^*-\bar y - \bar z)}{\sqrt {sd_y^*/n_y + sd_x^*/n_x}} \]

3. An approximate p-value can then be calculated as the number of bootstrapped results greater than the observed t-statistic from the sample.

\[ p_{boot} = \frac {\#t(z^{*b}) \ge t_{sample}}{B} \]

The same process is completed for the one sample case but with the one sample solution for the equation outlined by \(t(z^{*b})\). The paired sample case in this bootstrap procedure is equivalent to the one sample solution because the test is based on the difference scores.

Example

Again, we can use the sleep data to see the bootstrapped results. Notice that the plots show how the resampling via boostrapping indicates the instability of Hedges’ d(z).

data('sleep')

test1 = boot_t_TOST(formula = extra ~ group,
                      data = sleep,
                      paired = TRUE,
                      low_eqbound = -.5,
                      high_eqbound = .5,
                    R = 999)


print(test1)

## 
## Bootstrapped Paired t-test
## Hypothesis Tested: Equivalence
## Equivalence Bounds (raw):-0.500 & 0.500
## Alpha Level:0.05
## The equivalence test was non-significant, t(9) = -2.777, p = 1e+00
## The null hypothesis test was significant, t(9) = -4.062, p = 0e+00
## NHST: reject null significance hypothesis that the effect is equal to zero 
## TOST: don't reject null equivalence hypothesis
## 
## TOST Results 
##                    t        SE df p.value
## t-test     -4.062128 0.3889587  9       0
## TOST Lower -2.776644 0.3889587  9       1
## TOST Upper -5.347611 0.3889587  9       0
## 
## Effect Sizes 
##               estimate        SE  lower.ci   upper.ci conf.level
## Raw          -1.580000 0.3600943 -2.250000 -1.0600000        0.9
## Hedges' g(z) -1.230152 0.7235322 -2.815123 -0.9120299        0.9
## 
## Note: percentile boostrap method utilized.

plot(test1)