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Construct, coerce to, test for and print network objects.
is.network(x)as.network(x, ...)
network(
x,
vertex.attr = NULL,
vertex.attrnames = NULL,
directed = TRUE,
hyper = FALSE,
loops = FALSE,
multiple = FALSE,
bipartite = FALSE,
...
)
network.copy(x)
# S3 method for data.frame
as.network(
x,
directed = TRUE,
vertices = NULL,
hyper = FALSE,
loops = FALSE,
multiple = FALSE,
bipartite = FALSE,
bipartite_col = "is_actor",
...
)
# S3 method for network
print(
x,
matrix.type = which.matrix.type(x),
mixingmatrices = FALSE,
na.omit = TRUE,
print.adj = FALSE,
...
)
# S3 method for network
summary(object, na.omit = TRUE, mixingmatrices = FALSE, print.adj = TRUE, ...)
network, as.network, and print.network all
return a network class object; is.network returns TRUE or FALSE.
for network, a matrix giving the network structure in
adjacency, incidence, or edgelist form; otherwise, an object of class
network.
additional arguments.
optionally, a list containing vertex attributes.
optionally, a list containing vertex attribute names.
logical; should edges be interpreted as directed?
logical; are hyperedges allowed?
logical; should loops be allowed?
logical; are multiplex edges allowed?
count; should the network be interpreted as bipartite? If present (i.e., non-NULL, non-FALSE) it is the count of the number of actors in the bipartite network. In this case, the number of nodes is equal to the number of actors plus the number of events (with all actors preceeding all events). The edges are then interpreted as nondirected. Values of bipartite==0 are permited, indicating a bipartite network with zero-sized first partition.
If x is a data.frame, vertices is an optional
data.frame containing the vertex attributes. The first column is assigned
to the "vertex.names" and additional columns are used to set vertex attributes
using their column names. If bipartite is TRUE, a logical column
named "is_actor" (or the name of a column specified using the
bipartite_col parameter) can be provided indicating which vertices
should be considered as actors. If not provided, vertices referenced in the
first column of x are assumed to be the network's actors. If your
network has isolates (i.e. there are vertices referenced in vertices
that are not referenced in x), the "is_actor" column is required.
character(1L), default: "is_actor".
The name of the logical column indicating which vertices should be
considered as actors in bipartite networks.
one of "adjacency", "edgelist",
"incidence". See edgeset.constructors for details and
optional additional arguments
logical; print the mixing matrices for the discrete attributes?
logical; omit summarization of missing attributes in
network?
logical; print the network adjacency structure?
an object of class network.
Carter T. Butts buttsc@uci.edu and David Hunter dhunter@stat.psu.edu
network constructs a network class object from a matrix
representation. If the matrix.type parameter is not specified, it
will make a guess as to the intended edgeset.constructors function to
call based on the format of these input matrices. If the class of x
is not a matrix, network construction can be dispatched to other methods.
For example, If the ergm package is loaded, network() can
function as a shorthand for as.network.numeric with
x as an integer specifying the number of nodes to be created in the
random graph.
If the ergm package is loaded, network can function as a
shorthand for as.network.numeric if x is an integer specifying
the number of nodes. See the help page for
as.network.numeric in ergm package for details.
network.copy creates a new network object which duplicates its
supplied argument. (Direct assignment with <- should be used rather
than network.copy in most cases.)
as.network tries to coerce its argument to a network, using the
as.network.matrix functions if x is a matrix. (If the argument
is already a network object, it is returned as-is and all other arguments
are ignored.)
is.network tests whether its argument is a network (in the sense that
it has class network).
print.network prints a network object in one of several possible
formats. It also prints the list of global attributes of the network.
summary.network provides similar information.
Butts, C. T. (2008). “network: a Package for Managing Relational Data in R.” Journal of Statistical Software, 24(2). tools:::Rd_expr_doi("10.18637/jss.v024.i02")
network.initialize, attribute.methods,
as.network.matrix, as.matrix.network,
deletion.methods, edgeset.constructors,
network.indicators, plot.network
m <- matrix(rbinom(25,1,.4),5,5)
diag(m) <- 0
g <- network(m, directed=FALSE)
summary(g)
h <- network.copy(g) #Note: same as h<-g
summary(h)
# networks from data frames ===========================================================
#* simple networks ====================================================================
simple_edge_df <- data.frame(
from = c("b", "c", "c", "d", "a"),
to = c("a", "b", "a", "a", "b"),
weight = c(1, 1, 2, 2, 3),
stringsAsFactors = FALSE
)
simple_edge_df
as.network(simple_edge_df)
# simple networks with vertices =======================================================
simple_vertex_df <- data.frame(
name = letters[1:5],
residence = c("urban", "rural", "suburban", "suburban", "rural"),
stringsAsFactors = FALSE
)
simple_vertex_df
as.network(simple_edge_df, vertices = simple_vertex_df)
as.network(simple_edge_df,
directed = FALSE, vertices = simple_vertex_df,
multiple = TRUE
)
#* splitting multiplex data frames into multiple networks =============================
simple_edge_df$relationship <- c(rep("friends", 3), rep("colleagues", 2))
simple_edge_df
lapply(split(simple_edge_df, f = simple_edge_df$relationship),
as.network,
vertices = simple_vertex_df
)
#* bipartite networks without isolates ================================================
bip_edge_df <- data.frame(
actor = c("a", "a", "b", "b", "c", "d", "d", "e"),
event = c("e1", "e2", "e1", "e3", "e3", "e2", "e3", "e1"),
actor_enjoyed_event = rep(c(TRUE, FALSE), 4),
stringsAsFactors = FALSE
)
bip_edge_df
bip_node_df <- data.frame(
node_id = c("a", "e1", "b", "e2", "c", "e3", "d", "e"),
node_type = c(
"person", "event", "person", "event", "person",
"event", "person", "person"
),
color = c(
"red", "blue", "red", "blue", "red", "blue",
"red", "red"
),
stringsAsFactors = FALSE
)
bip_node_df
as.network(bip_edge_df, directed = FALSE, bipartite = TRUE)
as.network(bip_edge_df, directed = FALSE, vertices = bip_node_df, bipartite = TRUE)
#* bipartite networks with isolates ===================================================
bip_nodes_with_isolates <- rbind(
bip_node_df,
data.frame(
node_id = c("f", "e4"),
node_type = c("person", "event"),
color = c("red", "blue"),
stringsAsFactors = FALSE
)
)
# indicate which vertices are actors via a column named `"is_actor"`
bip_nodes_with_isolates$is_actor <- bip_nodes_with_isolates$node_type == "person"
bip_nodes_with_isolates
as.network(bip_edge_df,
directed = FALSE, vertices = bip_nodes_with_isolates,
bipartite = TRUE
)
#* hyper networks from data frames ====================================================
hyper_edge_df <- data.frame(
from = c("a/b", "b/c", "c/d/e", "d/e"),
to = c("c/d", "a/b/e/d", "a/b", "d/e"),
time = 1:4,
stringsAsFactors = FALSE
)
tibble::as_tibble(hyper_edge_df)
# split "from" and "to" at `"/"`, coercing them to list columns
hyper_edge_df$from <- strsplit(hyper_edge_df$from, split = "/")
hyper_edge_df$to <- strsplit(hyper_edge_df$to, split = "/")
tibble::as_tibble(hyper_edge_df)
as.network(hyper_edge_df,
directed = FALSE, vertices = simple_vertex_df,
hyper = TRUE, loops = TRUE
)
# convert network objects back to data frames =========================================
simple_g <- as.network(simple_edge_df, vertices = simple_vertex_df)
as.data.frame(simple_g)
as.data.frame(simple_g, unit = "vertices")
bip_g <- as.network(bip_edge_df,
directed = FALSE, vertices = bip_node_df,
bipartite = TRUE
)
as.data.frame(bip_g)
as.data.frame(bip_g, unit = "vertices")
hyper_g <- as.network(hyper_edge_df,
directed = FALSE, vertices = simple_vertex_df,
hyper = TRUE, loops = TRUE
)
as.data.frame(hyper_g)
as.data.frame(hyper_g, unit = "vertices")
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