`r lifecycle::badge("superseded")`
This function is superseded by the vcalc provided by
the metafor package. Compared to impute_covariance_matrix,
vcalc provides many further features, includes a
data argument, and uses syntax that is consistent with other
functions in metafor.
impute_covariance_matrix calculates a block-diagonal covariance
matrix, given the marginal variances, the block structure, and an assumed
correlation structure. Can be used to create compound-symmetric structures,
AR(1) auto-correlated structures, or combinations thereof.
impute_covariance_matrix(
vi,
cluster,
r,
ti,
ar1,
smooth_vi = FALSE,
subgroup = NULL,
return_list = identical(as.factor(cluster), sort(as.factor(cluster))),
check_PD = TRUE
)If cluster is appropriately sorted, then a list of matrices,
with one entry per cluster, will be returned by default. If cluster
is out of order, then the full variance-covariance matrix will be returned by default. The output structure can be controlled with the optional
return_list argument.
Vector of variances
Vector indicating which effects belong to the same cluster. Effects with the same value of `cluster` will be treated as correlated.
Vector or numeric value of assumed constant correlation(s) between effect size estimates from each study.
Vector of time-points describing temporal spacing of effects, for use with auto-regressive correlation structures.
Vector or numeric value of assumed AR(1) auto-correlation(s)
between effect size estimates from each study. If specified, then ti
argument must be specified.
Logical indicating whether to smooth the marginal variances
by taking the average vi within each cluster. Defaults to
FALSE.
Vector of category labels describing sub-groups of effects. If non-null, effects that share the same category label and the same cluster will be treated as correlated, but effects with different category labels will be treated as uncorrelated, even if they come from the same cluster.
Optional logical indicating whether to return a list of matrices (with one entry per block) or the full variance-covariance matrix.
Optional logical indicating whether to check whether each
covariance matrix is positive definite. If TRUE (the default), the
function will display a warning if any covariance matrix is not positive
definite.
A block-diagonal variance-covariance matrix (possibly represented as
a list of matrices) with a specified structure. The structure depends on
whether the r argument, ar1 argument, or both arguments are
specified. Let \(v_{ij}\) denote the specified variance for effect
\(i\) in cluster \(j\) and \(C_{hij}\) be the covariance
between effects \(h\) and \(i\) in cluster
\(j\).
If only r is specified, each block of the variance-covariance
matrix will have a constant (compound symmetric) correlation, so that
$$C_{hij} = r_j \sqrt{v_{hj} v_{ij},}$$
where \(r_j\) is the specified correlation
for cluster \(j\). If only a single value is given in r, then
it will be used for every cluster.
If only ar1 is specified, each block of the variance-covariance matrix will have an
AR(1) auto-correlation structure, so that
$$C_{hij} = \phi_j^{|t_{hj}- t_{ij}|} \sqrt{v_{hj} v_{ij},}$$
where \(\phi_j\) is the specified auto-correlation
for cluster \(j\) and \(t_{hj}\) and \(t_{ij}\)
are specified time-points corresponding to effects \(h\) and
\(i\) in cluster \(j\). If only a single value is given in
ar1, then it will be used for every cluster.
If both r and ar1 are specified, each block of the variance-covariance matrix will have combination of compound symmetric and an AR(1)
auto-correlation structures, so that
$$C_{hij} = \left[r_j + (1 - r_j)\phi_j^{|t_{hj} - t_{ij}|}\right] \sqrt{v_{hj} v_{ij},}$$
where \(r_j\) is the specified constant correlation for cluster
\(j\), \(\phi_j\) is the specified auto-correlation for
cluster \(j\) and \(t_{hj}\) and \(t_{ij}\) are
specified time-points corresponding to effects \(h\) and
\(i\) in cluster \(j\). If only single values are given in
r or ar1, they will be used for every cluster.
If smooth_vi = TRUE, then all of the variances within cluster
\(j\) will be set equal to the average variance of cluster
\(j\), i.e., $$v'_{ij} = \frac{1}{n_j} \sum_{i=1}^{n_j}
v_{ij}$$ for
\(i=1,...,n_j\) and \(j=1,...,k\).
if (requireNamespace("metafor", quietly = TRUE)) {
library(metafor)
# Constant correlation
data(SATcoaching)
V_list <- impute_covariance_matrix(vi = SATcoaching$V, cluster = SATcoaching$study, r = 0.66)
MVFE <- rma.mv(d ~ 0 + test, V = V_list, data = SATcoaching)
conf_int(MVFE, vcov = "CR2", cluster = SATcoaching$study)
}
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