Multivariate analysis of variance (James test): Multivariate analysis of variance (James test)

A vector with the next 4 elements:

test

The test statistic.

correction

The value of the correction factor.

corr.critical

The corrected critical value of the chi-square distribution.

p-value

The p-value of the corrected test statistic.

James (1954) also proposed an alternative to MANOVA when the covariance matrices are not assumed equal. The test statistic for \(k\) samples is $$ J=\sum_{i=1}^k\left(\bar{{\bf x}}_i-\bar{{\bf X}}\right)^T{\bf W}_i\left(\bar{{\bf x}}_i-\bar{{\bf X}}\right), $$ where \(\bar{{\bf x}}_i\) and \(n_i\) are the sample mean vector and sample size of the \(i\)-th sample respectively and \({\bf W}_i=\left(\frac{{\bf S}_i}{n_i}\right)^{-1}\), where \({\bf S}_i\) is the covariance matrix of the \(i\)-sample mean vector and \(\bar{{\bf X}}\) is the estimate of the common mean \(\bar{{\bf X}}=\left(\sum_{i=1}^k{\bf W}_i\right)^{-1}\sum_{i=1}^k{\bf W}_i\bar{{\bf x}}_i\).

Normally one would compare the test statistic with a \(\chi^2_{r,1-\alpha}\), where \(r=p\left(k-1\right)\) are the degrees of freedom with \(k\) denoting the number of groups and \(p\) the dimensionality of the data. There are \(r\) constraints (how many univariate means must be equal, so that the null hypothesis, that all the mean vectors are equal, holds true), that is where these degrees of freedom come from. James (1954) compared the test statistic with a corrected \(\chi^2\) distribution instead. Let \(A\) and \(B\) be \(A= 1+\frac{1}{2r}\sum_{i=1}^k\frac{\left[\text{tr}\left({\bf I}_p-{\bf W}^{-1}{\bf W}_i\right)\right]^2}{n_i-1}\) and \(B= \frac{1}{r\left(r+2\right)}\sum_{i=1}^k\left\lbrace\frac{\text{tr}\left[\left({\bf I}_p-{\bf W}^{-1}{\bf W}_i\right)^2\right]}{n_i-1}+\frac{\left[\text{tr}\left({\bf I}_p-{\bf W}^{-1}{\bf W}_i\right)\right]^2}{2\left(n_i-1\right)}\right\rbrace\).

The corrected quantile of the \(\chi^2\) distribution is given as before by \(2h\left(\alpha\right)=\chi^2\left(A+B\chi^2\right)\).