netclu_leadingeigen: Finding communities based on the leading eigenvector of the...
In bioregion: Comparison of Bioregionalisation Methods

netclu_leadingeigen

R Documentation

Finding communities based on the leading eigenvector of the community matrix

Description

This function finds communities in a (un)weighted undirected network based on the leading eigenvector of the community matrix.

Usage

netclu_leadingeigen(
  net,
  weight = TRUE,
  cut_weight = 0,
  index = names(net)[3],
  bipartite = FALSE,
  site_col = 1,
  species_col = 2,
  return_node_type = "both",
  algorithm_in_output = TRUE
)

Arguments

`net`	The output object from `similarity()` or `dissimilarity_to_similarity()`. If a `data.frame` is used, the first two columns represent pairs of sites (or any pair of nodes), and the next column(s) are the similarity indices.
`weight`	A `boolean` indicating if the weights should be considered if there are more than two columns.
`cut_weight`	A minimal weight value. If `weight` is TRUE, the links between sites with a weight strictly lower than this value will not be considered (`0` by default).
`index`	The name or number of the column to use as weight. By default, the third column name of `net` is used.
`bipartite`	A `boolean` indicating if the network is bipartite (see Details).
`site_col`	The name or number for the column of site nodes (i.e., primary nodes).
`species_col`	The name or number for the column of species nodes (i.e., feature nodes).
`return_node_type`	A `character` indicating what types of nodes (`"site"`, `"species"`, or `"both"`) should be returned in the output (`"both"` by default).
`algorithm_in_output`	A `boolean` indicating if the original output of cluster_leading_eigen should be returned in the output (`TRUE` by default, see Value).

Details

This function is based on the leading eigenvector of the community matrix (Newman, 2006) as implemented in the igraph package (cluster_leading_eigen).

Value

A list of class bioregion.clusters with five slots:

name: A character containing the name of the algorithm.
args: A list of input arguments as provided by the user.
inputs: A list of characteristics of the clustering process.
algorithm: A list of all objects associated with the clustering procedure, such as original cluster objects (only if algorithm_in_output = TRUE).
clusters: A data.frame containing the clustering results.

In the algorithm slot, if algorithm_in_output = TRUE, users can find the output of cluster_leading_eigen.

Note

Although this algorithm was not primarily designed to deal with bipartite networks, it is possible to consider the bipartite network as a unipartite network (bipartite = TRUE).

Do not forget to indicate which of the first two columns is dedicated to the site nodes (i.e., primary nodes) and species nodes (i.e. feature nodes) using the arguments site_col and species_col. The type of nodes returned in the output can be chosen with the argument return_node_type equal to "both" to keep both types of nodes, "site" to preserve only the site nodes, and "species" to preserve only the species nodes.

Author(s)

Maxime Lenormand (maxime.lenormand@inrae.fr)
Pierre Denelle (pierre.denelle@gmail.com)
Boris Leroy (leroy.boris@gmail.com)

References

Newman MEJ (2006) Finding community structure in networks using the eigenvectors of matrices. Physical Review E 74, 036104.

Examples

comat <- matrix(sample(1000, 50), 5, 10)
rownames(comat) <- paste0("Site", 1:5)
colnames(comat) <- paste0("Species", 1:10)

net <- similarity(comat, metric = "Simpson")
com <- netclu_leadingeigen(net)

net_bip <- mat_to_net(comat, weight = TRUE)
clust2 <- netclu_leadingeigen(net_bip, bipartite = TRUE)

bioregion documentation built on April 12, 2025, 9:13 a.m.