glb.algebraic: Find the greatest lower bound to reliability.

If C is a p * p-covariance matrix, v = diag(C) its diagonal (i. e. the vector of variances \(v_i = c_{ii}\)), \(\tilde { C} = C - Diag(v)\) is the covariance matrix with 0s substituted in the diagonal and x = the vector \(x_1, \dots ,x_n\) the educational testing problem is (see e. g., Al-Homidan 2008)

$$\sum_{i=1}^p x_i \rightarrow \min$$

s.t. $$\tilde{ C} + Diag(x) \geq 0$$(i.e. positive semidefinite) and \(x_i \leq v_i, i=1,\dots,p\). This is the same as minimizing the trace of the symmetric matrix $$\tilde{ C}+diag(x)=\left(\begin{array}{llll} x_1 & c_{12} & \ldots & c_{1p} \\ c_{12} & x_2 & \ldots & c_{2p} \\ \vdots & \vdots & \ddots & \vdots \\ c_{1p} & c_{2p} & \ldots & x_p\\ \end{array}\right)$$

s. t. \(\tilde{ C} + Diag(x)\) is positive semidefinite and \(x_i \leq v_i\).

The greatest lower bound to reliability is $$\frac{\sum_{ij} \bar{c_{ij}} + \sum_i x_i}{\sum_{ij}c_{ij}}$$

Additionally, function glb.algebraic allows the user to change the upper bounds \(x_i \leq v_i\) to \(x_i \leq u_i\) and add lower bounds \(l_i \leq x_i\).

The greatest lower bound to reliability is applicable for tests with non-homogeneous items. It gives a sharp lower bound to the reliability of the total test score.

Caution: Though glb.algebraic gives exact lower bounds for exact covariance matrices, the estimates from empirical matrices may be strongly biased upwards for small and medium sample sizes.

glb.algebraic is wrapper for a call to function csdp of package Rcsdp (see its documentation).

If Cov is the covariance matrix of subtests/items with known lower bounds, rel, to their reliabilities (e. g. Cronbachs \(\alpha\)), LoBounds can be used to improve the lower bound to reliability by setting LoBounds <- rel*diag(Cov).

Changing UpBounds can be used to relax constraints \(x_i \leq v_i\) or to fix \(x_i\)-values by setting LoBounds[i] < -z; UpBounds[i] <- z.