community.tree: Reconstruction of the Girvan-Newman Community Tree for a CNA...
In bio3d: Biological Structure Analysis
View source: R/community.tree.R
community.tree R Documentation
Reconstruction of the Girvan-Newman Community Tree for a CNA Class Object.
Description
This function reconstructs the community tree of the community
clustering analysis performed by the ‘cna’ function.
It allows the user to explore different network community partitions.
Usage
community.tree(x, rescale=FALSE)
Arguments
x
A protein network graph object as obtained from the
‘cna’ function.
rescale
Logical, indicating whether to rescale the community
names starting from 1. If FALSE, the community names will start from
N+1, where N is the number of nodes.
Details
The input of this function should be a ‘cna’ class object
containing ‘network’ and ‘communities’ attributes.
This function reconstructs the community residue memberships for each
modularity value. The purpose is to facilitate inspection of alternate
community partitioning points, which in practice often corresponds to a value
close to the maximum of the modularity, but not the maximum value itself.
Value
Returns a list object that includes the following components:
modularity
A numeric vector containing the modularity values.
tree
A numeric matrix containing in each row the
community residue memberships corresponding to a modularity
value. The rows are ordered according to the ‘modularity’ object.
num.of.comms
A numeric vector containing the number of
communities per modularity value. The vector elements are ordered according
to the ‘modularity’ object.
Author(s)
Guido Scarabelli
See Also
cna, network.amendment, summary.cna
Examples
# PDB server connection required - testing excluded
if (!requireNamespace("igraph", quietly = TRUE)) {
message('Need igraph installed to run this example')
} else {
try({
###-- Build a CNA object
pdb <- read.pdb("4Q21")
modes <- nma(pdb)
cij <- dccm(modes)
net <- cna(cij, cutoff.cij=0.2)
##-- Reconstruct the community membership vector for each clustering step.
tree <- community.tree(net, rescale=TRUE)
## Plot modularity vs number of communities
plot( tree$num.of.comms, tree$modularity )
## Inspect the maximum modularity value partitioning
max.mod.ind <- which.max(tree$modularity)
## Number of communities (k) at max modularity
tree$num.of.comms[ max.mod.ind ]
## Membership vector at this partition point
tree$tree[max.mod.ind,]
# Should be the same as that contained in the original CNA network object
net$communities$membership == tree$tree[max.mod.ind,]
# Inspect a new membership partitioning (at k=7)
memb.k7 <- tree$tree[ tree$num.of.comms == 7, ]
## Produce a new k=7 community network
net.7 <- network.amendment(net, memb.k7)
plot(net.7, pdb)
#view.cna(net.7, trim.pdb(pdb, atom.select(pdb,"calpha")), launch=TRUE )
}, silent=TRUE)
if(inherits(.Last.value, "try-error")) {
message("Need internet to run the example")
}
}
bio3d documentation built on Oct. 30, 2024, 1:08 a.m.
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View source: R/community.tree.R
| community.tree | R Documentation |
Reconstruction of the Girvan-Newman Community Tree for a CNA Class Object.
Description
This function reconstructs the community tree of the community clustering analysis performed by the ‘cna’ function. It allows the user to explore different network community partitions.
Usage
community.tree(x, rescale=FALSE)
Arguments
x |
A protein network graph object as obtained from the ‘cna’ function. |
rescale |
Logical, indicating whether to rescale the community names starting from 1. If FALSE, the community names will start from N+1, where N is the number of nodes. |
Details
The input of this function should be a ‘cna’ class object containing ‘network’ and ‘communities’ attributes.
This function reconstructs the community residue memberships for each modularity value. The purpose is to facilitate inspection of alternate community partitioning points, which in practice often corresponds to a value close to the maximum of the modularity, but not the maximum value itself.
Value
Returns a list object that includes the following components:
modularity |
A numeric vector containing the modularity values. |
tree |
A numeric matrix containing in each row the community residue memberships corresponding to a modularity value. The rows are ordered according to the ‘modularity’ object. |
num.of.comms |
A numeric vector containing the number of communities per modularity value. The vector elements are ordered according to the ‘modularity’ object. |
Author(s)
Guido Scarabelli
See Also
cna, network.amendment, summary.cna
Examples
# PDB server connection required - testing excluded
if (!requireNamespace("igraph", quietly = TRUE)) {
message('Need igraph installed to run this example')
} else {
try({
###-- Build a CNA object
pdb <- read.pdb("4Q21")
modes <- nma(pdb)
cij <- dccm(modes)
net <- cna(cij, cutoff.cij=0.2)
##-- Reconstruct the community membership vector for each clustering step.
tree <- community.tree(net, rescale=TRUE)
## Plot modularity vs number of communities
plot( tree$num.of.comms, tree$modularity )
## Inspect the maximum modularity value partitioning
max.mod.ind <- which.max(tree$modularity)
## Number of communities (k) at max modularity
tree$num.of.comms[ max.mod.ind ]
## Membership vector at this partition point
tree$tree[max.mod.ind,]
# Should be the same as that contained in the original CNA network object
net$communities$membership == tree$tree[max.mod.ind,]
# Inspect a new membership partitioning (at k=7)
memb.k7 <- tree$tree[ tree$num.of.comms == 7, ]
## Produce a new k=7 community network
net.7 <- network.amendment(net, memb.k7)
plot(net.7, pdb)
#view.cna(net.7, trim.pdb(pdb, atom.select(pdb,"calpha")), launch=TRUE )
}, silent=TRUE)
if(inherits(.Last.value, "try-error")) {
message("Need internet to run the example")
}
}
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Note that we can't provide technical support on individual packages. You should contact the package authors for that.
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