This function tries to find densely connected subgraphs in a graph by calculating the leading non-negative eigenvector of the modularity matrix of the graph.
cluster_leading_eigen(
graph,
steps = -1,
weights = NULL,
start = NULL,
options = arpack_defaults,
callback = NULL,
extra = NULL,
env = parent.frame()
)The input graph. Should be undirected as the method needs a symmetric matrix.
The number of steps to take, this is actually the number of tries to make a step. It is not a particularly useful parameter.
The weights of the edges. It must be a positive numeric vector,
NULL or NA. If it is NULL and the input graph has a
‘weight’ edge attribute, then that attribute will be used. If
NULL and no such attribute is present, then the edges will have equal
weights. Set this to NA if the graph was a ‘weight’ edge
attribute, but you don't want to use it for community detection. A larger
edge weight means a stronger connection for this function.
NULL, or a numeric membership vector, giving the start
configuration of the algorithm.
A named list to override some ARPACK options.
If not NULL, then it must be callback function. This
is called after each iteration, after calculating the leading eigenvector of
the modularity matrix. See details below.
Additional argument to supply to the callback function.
The environment in which the callback function is evaluated.
cluster_leading_eigen returns a named list with the
following members:
The membership vector at the end of the algorithm, when no more splits are possible.
The merges
matrix starting from the state described by the membership member.
This is a two-column matrix and each line describes a merge of two
communities, the first line is the first merge and it creates community
‘N’, N is the number of initial communities in the
graph, the second line creates community N+1, etc.
Information about the underlying ARPACK computation, see
arpack for details.
The callback argument can be used to
supply a function that is called after each eigenvector calculation. The
following arguments are supplied to this function:
The actual membership vector, with zero-based indexing.
The community that the algorithm just tried to split, community numbering starts with zero here.
The eigenvalue belonging to the leading eigenvector the algorithm just found.
The leading eigenvector the algorithm just found.
An R function that can be used to multiple the actual modularity matrix with an arbitrary vector. Supply the vector as an argument to perform this multiplication. This function can be used with ARPACK.
The extra argument that was passed to
cluster_leading_eigen.
The function documented in these section implements the ‘leading eigenvector’ method developed by Mark Newman, see the reference below.
The heart of the method is the definition of the modularity matrix,
B, which is B=A-P, A being the adjacency matrix of the
(undirected) network, and P contains the probability that certain
edges are present according to the ‘configuration model’. In other
words, a P[i,j] element of P is the probability that there is
an edge between vertices i and j in a random network in which
the degrees of all vertices are the same as in the input graph.
The leading eigenvector method works by calculating the eigenvector of the modularity matrix for the largest positive eigenvalue and then separating vertices into two community based on the sign of the corresponding element in the eigenvector. If all elements in the eigenvector are of the same sign that means that the network has no underlying comuunity structure. Check Newman's paper to understand why this is a good method for detecting community structure.
MEJ Newman: Finding community structure using the eigenvectors of matrices, Physical Review E 74 036104, 2006.
modularity, cluster_walktrap,
cluster_edge_betweenness,
cluster_fast_greedy, as.dendrogram
# NOT RUN {
g <- make_full_graph(5) %du% make_full_graph(5) %du% make_full_graph(5)
g <- add_edges(g, c(1,6, 1,11, 6, 11))
lec <- cluster_leading_eigen(g)
lec
cluster_leading_eigen(g, start=membership(lec))
# }
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