highlyConnSG: Compute highly connected subgraphs for an undirected graph
In RBGL: An interface to the BOOST graph library
Description
Usage
Arguments
Details
Value
Author(s)
References
See Also
Examples
Description
Compute highly connected subgraphs for an undirected graph
Usage
1
highlyConnSG(g, sat=3, ldv=c(3,2,1))
Arguments
g
an instance of the graph class with edgemode
“undirected”
sat
singleton adoption threshold, positive integer
ldv
heuristics to remove lower degree vertice, a decreasing sequence of positive integer
Details
A graph G with n vertices is highly connected if its connectivity k(G) > n/2. The HCS algorithm partitions a given graph into a set of highly connected subgraphs, by using minimum-cut algorithm recursively. To improve performance, the approach is refined by adopting singletons, removing low degree vertices and merging clusters.
On singleton adoption:
after each round of partition, some highly connected subgraphs could be
singletons (i.e., a subgraph contains only one node).
To reduce the number of singletons, therefore reduce number of clusters,
we try to get "normal" subgraphs to "adopt" them. If a singleton, s, has n
neighbours in a highly connected subgraph c, and n > sat, we add s to c.
To adapt to the modified subgraphs, this adoption process is repeated until
no further such adoption.
On lower degree vertices: when the graph has low degree vertices, minimum-cut
algorithm will just repeatedly separate these vertices from the rest.
To reduce such expensive and non-informative computation, we "remove" these
low degree vertices first before applying minimum-cut algorithm.
Given ldv = (d1, d2, ..., dp), (d[i] > d[i+1] > 0), we repeat the following
(i from 1 to p): remove all the highly-connected-subgraph found so far;
remove vertices with degrees < di; find highly-connected-subgraphs;
perform singleton adoptions.
The Boost implementation does not support self-loops, therefore we
signal an error and suggest that users remove self-loops using the
function removeSelfLoops function. This change does affect
degree, but the original article makes no specific reference to self-loops.
Value
A list of clusters, each is given as vertices in the graph.
Author(s)
Li Long <li.long@isb-sib.ch>
References
A Clustering Algorithm based on Graph Connectivity by E. Hartuv, R. Shamir, 1999.
See Also
edgeConnectivity, minCut, removeSelfLoops
Examples
1
2
3
4
5
con <- file(system.file("XML/hcs.gxl",package="RBGL"))
coex <- fromGXL(con)
close(con)
highlyConnSG(coex)
RBGL documentation built on Nov. 8, 2020, 5 p.m.
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Description Usage Arguments Details Value Author(s) References See Also Examples
Description
Compute highly connected subgraphs for an undirected graph
Usage
1 | highlyConnSG(g, sat=3, ldv=c(3,2,1))
|
Arguments
g |
an instance of the |
sat |
singleton adoption threshold, positive integer |
ldv |
heuristics to remove lower degree vertice, a decreasing sequence of positive integer |
Details
A graph G with n vertices is highly connected if its connectivity k(G) > n/2. The HCS algorithm partitions a given graph into a set of highly connected subgraphs, by using minimum-cut algorithm recursively. To improve performance, the approach is refined by adopting singletons, removing low degree vertices and merging clusters.
On singleton adoption: after each round of partition, some highly connected subgraphs could be singletons (i.e., a subgraph contains only one node). To reduce the number of singletons, therefore reduce number of clusters, we try to get "normal" subgraphs to "adopt" them. If a singleton, s, has n neighbours in a highly connected subgraph c, and n > sat, we add s to c. To adapt to the modified subgraphs, this adoption process is repeated until no further such adoption.
On lower degree vertices: when the graph has low degree vertices, minimum-cut algorithm will just repeatedly separate these vertices from the rest. To reduce such expensive and non-informative computation, we "remove" these low degree vertices first before applying minimum-cut algorithm. Given ldv = (d1, d2, ..., dp), (d[i] > d[i+1] > 0), we repeat the following (i from 1 to p): remove all the highly-connected-subgraph found so far; remove vertices with degrees < di; find highly-connected-subgraphs; perform singleton adoptions.
The Boost implementation does not support self-loops, therefore we
signal an error and suggest that users remove self-loops using the
function removeSelfLoops function. This change does affect
degree, but the original article makes no specific reference to self-loops.
Value
A list of clusters, each is given as vertices in the graph.
Author(s)
Li Long <li.long@isb-sib.ch>
References
A Clustering Algorithm based on Graph Connectivity by E. Hartuv, R. Shamir, 1999.
See Also
edgeConnectivity, minCut, removeSelfLoops
Examples
1 2 3 4 5 | con <- file(system.file("XML/hcs.gxl",package="RBGL"))
coex <- fromGXL(con)
close(con)
highlyConnSG(coex)
|
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