Creating network mixing matrices (mixingm()) and data frames (mixingdf()).
mixingm(object, ...)# S3 method for igraph
mixingm(
object,
rattr,
cattr = rattr,
full = FALSE,
directed = is.directed(object),
loops = any(is.loop(object)),
...
)
mixingdf(object, ...)
# S3 method for table
mixingdf(object, ...)
# S3 method for igraph
mixingdf(object, ...)
Function mixingm(), depending on full argument, a two- or
three-dimensional array crossclassifying connected or all dyads in
object. For undirected network and if foldit is TRUE (default), the
matrix is folded onto the upper triangle (entries in lower triangle are 0).
Function mixingdf() returns non-zero entries of a mixing matrix (as
returned by mixingm()), but organized in a data frame with columns:
ego, alter -- group membership of ego an alter
tie -- present only if full=TRUE, with TRUE or FALSE for connected
and disconnected dyads respectively
n -- counts
R object, see Details for available methods
other arguments passed to/from other methods
name of the vertex attribute or an attribute itself as a vector.
If cattr is not NULL, rattr is used for rows of the resulting mixing
matrix.
name of the vertex attribute or an attribute itself as a vector. If supplied, used for columns in the mixing matrix.
logical, whether two- or three-dimensional mixing matrix should be returned.
logical, whether the network is directed. By default,
directedness of the network is determined with igraph::is_directed().
logical, whether loops are allowed. By default it is TRUE
whenever there is at least one loop in object.
Network mixing matrix is, traditionally, a two-dimensional cross-classification of edges depending on the values of a specified vertex attribute for tie sender and tie receiver. It is an important tool for assessing network homophily or segregation.
Let \(G\) be the number of distinct values of the vertex attribute in question. We may say that we have \(G\) mutually exclusive groups in the network. The mixing matrix is a \(G \times G\) matrix such that \(m_{ij}\) is the number of ties send by vertices in group \(i\) to vertices in group \(j\). The diagonal of that matrix is of special interest as, say, \(m_{ii}\) is the number of ties within group \(i\).
A full mixing matrix is a three-dimensional array that cross-classifies all network dyads depending on:
the value of the vertex attribute for tie sender
the value of the vertex attribute for tie receiver
the status of the dyad, i.e. whether it is connected or not
The two-dimensional version is a so-called "contact layer" of the three-dimensional version.
If object is of class "igraph," mixing matrix is created for the
network in object based on vertex attributes supplied in arguments
rattr and optionally cattr.
If only rattr is specified (or, equivalently, rattr and cattr are
identical), the result will be a mixing matrix \(G \times G\) if full
is FALSE or \(G \times G \times 2\) if full is TRUE. Where
\(G\) is the number of categories of vertex attribute specified by
rattr.
If rattr and cattr can be used to specify different vertex attributes
for tie sender and tie receiver.
if(requireNamespace("igraph", quietly = TRUE)) {
# some directed network
net <- igraph::make_graph(c(1,2, 1,3, 2,3, 4,5, 1,4, 1,5, 4,2, 5,3))
igraph::V(net)$type <- c(1,1,1, 2,2)
mixingm(net, "type")
mixingm(net, "type", full=TRUE)
# as undirected
mixingm( igraph::as.undirected(net), "type")
mixingm(net, "type")
mixingm(net, "type", full=TRUE)
}
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