The HPPANEL Procedure

Linear Hypothesis Testing

For a linear hypothesis of the form R ${\beta }=\mb{r}$ , where $\mb{R}$ is ${J{\times }K }$ and $\mb{r}$ is ${J {\times }\mr{1}}$ , the F-statistic with ${J, M-K}$ degrees of freedom is computed as

$(\mb{R} {\beta }-\mb{r} )^{'} [\mb{R} \hat{\mb{V} } {\mb{R} ’}]^{-1}(\mb{R} {\beta }-\mb{r} )$

However, it is also possible to write the F statistic as

$F = \frac{(\hat{\mb{u}}^{'}_{*}\hat{\mb{u}}_{*}- \hat{\mb{u}}^{'}\hat{\mb{u}} )/J}{\hat{\mb{u}}^{'}\hat{\mb{u}}/(M - K)}$

where

$\hat{\mb{u}}_{*}$ is the residual vector from the restricted regression
$\hat{\mb{u}}$ is the residual vector from the unrestricted regression
J is the number of restrictions
$M - K$ are the degrees of freedom, M is the number of observations, and K is the number of parameters in the model

The Wald, likelihood ratio (LR), and LaGrange multiplier (LM) tests are all related to the F test. You use this relationship of the F test to the likelihood ratio and LaGrange multiplier tests. The Wald test is calculated from its definition.

The Wald test statistic is

$W=(\mb{R} {\beta }-\mb{r} )^{'}[\mb{R} \hat{\mb{V} }{\mb{R} ’}]^{-1}(\mb{R} {\beta }-\mb{r} )$

The likelihood ratio is

$\mr{LR} = \mi{M} \ln {\left[1 + \frac{1}{\mi{M - K}}JF\right]}$

The LaGrange multiplier test statistic is

$\mr{LM} = \mi{M}\left[\frac{\mi{JF}}{\mi{M - K + JF}}\right]$

where $JF$ represents the number of restrictions multiplied by the result of the F test.

The distribution of these test statistics is the $\chi ^{2}$ distribution whose degrees of freedom equal the number of restrictions imposed (J). The three tests are asymptotically equivalent, but they have differing small-sample properties. Greene (2000, p. 392) and Davidson and MacKinnon (1993, pp. 456–458) discuss the small-sample properties of these statistics.