Named after the Dutch mathematician Bartel Leendert van der Waerden, the Van der Waerden test is a statistical test that k population distribution functions are equal. The Van der Waerden test converts the ranks from a standard Kruskal-Wallis test to quantiles of the standard normal distribution (details given below). These are called normal scores and the test is computed from these normal scores.
The k population version of the test is an extension of the test for two populations published by Van der Waerden (1952,1953).
Analysis of Variance (ANOVA) is a data analysis technique for examining the significance of the factors (independent variables) in a multi-factor model. The one factor model can be thought of as a generalization of the two sample t-test. That is, the two sample t-test is a test of the hypothesis that two population means are equal. The one factor ANOVA tests the hypothesis that k population means are equal. The standard ANOVA assumes that the errors (i.e., residuals) are normally distributed. If this normality assumption is not valid, an alternative is to use a non-parametric test.
Let nj (j = 1, 2, ..., k) represent the sample sizes for each of the k groups (i.e., samples) in the data. Let N denote the sample size for all groups. Let Xij represent the ith value in the jth group. The normal scores are computed as
Aij=\Phi-1\left(
R(Xij) | |
N+1 |
\right)
\bar{A}j=
1 | |
nj |
nj | |
\sum | |
i=1 |
Aij j=1,2,\ldots,k
s2=
1 | |
N-1 |
nj | |
\sum | |
i=1 |
2 | |
A | |
ij |
H0: All of the k population distribution functions tend to yield the same observation
Ha: At least one of the populations tends to yield larger observations than at least one of the other populations
The test statistic is
T1=
1 | |
s2 |
kn | |
\sum | |
j\bar{A} |
2 | |
j |
T1>
2 | |
\chi | |
\alpha,k-1 |
\left\vert
\bar{A} | |
j1 |
-
\bar{A} | |
j2 |
\right\vert>st1-\alpha/2\sqrt{
N-1-T1 | |
N-k |
The most common non-parametric test for the one-factor model is the Kruskal-Wallis test. The Kruskal-Wallis test is based on the ranks of the data. The advantage of the Van Der Waerden test is that it provides the high efficiency of the standard ANOVA analysis when the normality assumptions are in fact satisfied, but it also provides the robustness of the Kruskal-Wallis test when the normality assumptions are not satisfied.