The hardware and bandwidth for this mirror is donated by METANET, the Webhosting and Full Service-Cloud Provider.
If you wish to report a bug, or if you are interested in having us mirror your free-software or open-source project, please feel free to contact us at mirror[@]metanet.ch.
This vignette describes the concept of neighborhood-inclusion, its
connection with network centrality and gives some example use cases with
the netrankr
package. The partial ranking induced by
neighborhood-inclusion can be used to assess partial centrality or compute probabilistic centrality.
In an undirected graph \(G=(V,E)\), the neighborhood of a node \(u \in V\) is defined as \[N(u)=\lbrace w : \lbrace u,w \rbrace \in E \rbrace\] and its closed neighborhood as \(N[v]=N(v) \cup \lbrace v \rbrace\). If the neighborhood of a node \(u\) is a subset of the closed neighborhood of a node \(v\), \(N(u)\subseteq N[v]\), we speak of neighborhood inclusion. This concept defines a dominance relation among nodes in a network. We say that \(u\) is dominated by \(v\) if \(N(u)\subseteq N[v]\). Neighborhood-inclusion induces a partial ranking on the vertices of a network. That is, (usually) some (if not most!) pairs of vertices are incomparable, such that neither \(N(u)\subseteq N[v]\) nor \(N(v)\subseteq N[u]\) holds. There is, however, a special graph class where all pairs are comparable (found in this vignette).
The importance of neighborhood-inclusion is given by the following result:
\[ N(u)\subseteq N[v] \implies c(u)\leq c(v), \] where \(c\) is a centrality index defined on special path algebras. These include many of the well known measures like closeness (and variants), betweenness (and variants) as well as many walk-based indices (eigenvector and subgraph centrality, total communicability,…).
Very informally, if \(u\) is dominated by \(v\), then u is less central than \(v\) no matter which centrality index is used, that fulfill the requirement. While this is the key result, this short description leaves out many theoretical considerations. These and more can be found in
Schoch, David & Brandes, Ulrik. (2016). Re-conceptualizing centrality in social networks. European Journal of Appplied Mathematics, 27(6), 971–985. (link)
netrankr
Packagelibrary(netrankr)
library(igraph)
set.seed(1886) #for reproducibility
We work with the following simple graph.
data("dbces11")
<- dbces11
g
plot(g,
vertex.color="black",vertex.label.color="white", vertex.size=16,vertex.label.cex=0.75,
edge.color="black",
margin=0,asp=0.5)
We can compare neighborhoods manually with the
neighborhood
function of the igraph
package.
Note the mindist
parameter to distinguish between open and
closed neighborhood.
<- 3
u <- 5
v <- neighborhood(g,order=1,nodes=u,mindist = 1)[[1]] #N(u)
Nu <- neighborhood(g,order=1,nodes=v,mindist = 0)[[1]] #N[v]
Nv
Nu
## + 2/11 vertices, named, from 013399c:
## [1] E K
Nv
## + 4/11 vertices, named, from 013399c:
## [1] E C I K
Although it is obvious that Nu
is a subset of
Nv
, we can verify it as follows.
all(Nu%in%Nv)
## [1] TRUE
Checking all pairs of nodes can efficiently be done with the
neighborhood_inclusion()
function from the
netrankr
package.
<- neighborhood_inclusion(g, sparse = FALSE)
P P
## A B C D E F G H I J K
## A 0 0 1 0 1 1 1 0 0 0 1
## B 0 0 0 1 0 0 0 1 0 0 0
## C 0 0 0 0 1 0 0 0 0 0 1
## D 0 0 0 0 0 0 0 0 0 0 0
## E 0 0 0 0 0 0 0 0 0 0 0
## F 0 0 0 0 0 0 0 0 0 0 0
## G 0 0 0 0 0 0 0 0 0 0 0
## H 0 0 0 0 0 0 0 0 0 0 0
## I 0 0 0 0 0 0 0 0 0 0 0
## J 0 0 0 0 0 0 0 0 0 0 0
## K 0 0 0 0 0 0 0 0 0 0 0
If an entry P[u,v]
is equal to one, we have \(N(u)\subseteq N[v]\).
The function dominance_graph()
can alternatively be used
to visualize the neighborhood inclusion as a directed graph.
<- dominance_graph(P)
g.dom
plot(g.dom,
vertex.color="black",vertex.label.color="white", vertex.size=16, vertex.label.cex=0.75,
edge.color="black", edge.arrow.size=0.5,margin=0,asp=0.5)
We start by calculating some standard measures of centrality found in
the ìgraph
package for our example network. Note that the
netrankr
package also implements a great variety of
indices, but they need further specifications described in this vignette.
<- data.frame(
cent.df vertex=1:11,
degree=degree(g),
betweenness=betweenness(g),
closeness=closeness(g),
eigenvector=eigen_centrality(g)$vector,
subgraph=subgraph_centrality(g)
)
#rounding for better readability
<- round(cent.df,4)
cent.df.rounded cent.df.rounded
## vertex degree betweenness closeness eigenvector subgraph
## A 1 1 0.0000 0.0370 0.2260 1.8251
## B 2 1 0.0000 0.0294 0.0646 1.5954
## C 3 2 0.0000 0.0400 0.3786 3.1486
## D 4 2 9.0000 0.0400 0.2415 2.4231
## E 5 3 3.8333 0.0500 0.5709 4.3871
## F 6 4 9.8333 0.0588 0.9847 7.8073
## G 7 4 2.6667 0.0526 1.0000 7.9394
## H 8 4 16.3333 0.0556 0.8386 6.6728
## I 9 4 7.3333 0.0556 0.9114 7.0327
## J 10 4 1.3333 0.0526 0.9986 8.2421
## K 11 5 14.6667 0.0556 0.8450 7.3896
Notice how for each centrality index, different vertices are
considered to be the most central node. The most central from degree to
subgraph centrality are \(11\), \(8\), \(6\), \(7\)
and \(10\). Note that only
undominated vertices can achieve the highest score for any
reasonable index. As soon as a vertex is dominated by at least one
other, it will always be ranked below the dominator. We can check for
undominated vertices simply by forming the row Sums in
P
.
which(rowSums(P)==0)
## D E F G H I J K
## 4 5 6 7 8 9 10 11
8 nodes are undominated in the graph. It is thus entirely possible to find indices that would also rank \(4, 5\) and \(9\) on top.
Besides the top ranked nodes, we can check if the entire partial
ranking P
is preserved in each centrality ranking. If there
exists a pair \(u\) and \(v\) and index \(c()\) such that \(N(u)\subseteq N[v]\) but \(c(v)>c(u)\), we do not consider \(c\) to be a valid index.
In our example, we considered vertex \(3\) and \(5\), where \(3\) was dominated by \(5\). It is easy to verify that all
centrality scores of \(5\) are in fact
greater than the ones of \(3\) by
inspecting the respective rows in the table. To check all pairs, we use
the function is_preserved
. The function takes a partial
ranking, as induced by neighborhood inclusion, and a score vector of a
centrality index and checks if
P[i,j]==1 & scores[i]>scores[j]
is
FALSE
for all pairs i
and j
.
apply(cent.df[,2:6],2,function(x) is_preserved(P,x))
## degree betweenness closeness eigenvector subgraph
## TRUE TRUE TRUE TRUE TRUE
All considered indices preserve the neighborhood inclusion preorder on the example network.
NOTE: Preserving neighborhood inclusion on one network does not guarantee that an index preserves it on all networks. For more details refer to the paper cited in the first section.
These binaries (installable software) and packages are in development.
They may not be fully stable and should be used with caution. We make no claims about them.