simulate.ergm: Draw from the distribution of an Exponential Family Random Graph Model

Description

simulate is used to draw from exponential family random network models in their natural parameterizations. See ergm for more information on these models.

Usage

## S3 method for class 'formula':
simulate(object, nsim=1, seed=NULL,
                           coef, 
                           constraints=~.,
                           monitor=NULL,
                           basis=NULL,
                           statsonly=FALSE,
                           sequential=TRUE,
                           control=control.simulate.formula(),
                           verbose=FALSE, 
                           ...)
## S3 method for class 'ergm':
simulate(object, nsim=1, seed=NULL, 
                        coef=object$coef,
                        constraints=object$constraints,
                        monitor=NULL,
                        statsonly=FALSE,
                        sequential=TRUE,
                        control=control.simulate.ergm(),
                        verbose=FALSE, 
                        ...)

Arguments

object

an Robject. Either a formula or an ergm object. The formula should be of the form y ~

nsim

Number of networks to be randomly drawn from the given distribution on the set of all networks, returned by the Metropolis-Hastings algorithm.

seed

Random number integer seed. See set.seed.

coef

Vector of parameter values for the model from which the sample is to be drawn. If object is of class ergm, the default value is the vector of estimated coefficients.

constraints

A one-sided formula specifying one or more constraints on the support of the distribution of the networks being simulated. See the documentation for a similar argument for ergm for more information

monitor

A one-sided formula specifying one or more terms whose value is to be monitored. These terms are appeneded to the model, along with a coefficient of 0, so their statistics are returned.

basis

An optional network object to start the Markov chain. If omitted, the default is the left-hand-side of the formula. If neither a left-hand-side nor a basis is

statsonly

Logical: If TRUE, return only the network statistics, not the network(s) themselves.

sequential

Logical: If FALSE, each of the nsim simulated Markov chains begins at the initial network. If TRUE, the end of one simulation is used as the start of the next. Irrelevant when nsim=1.

control

A list of control parameters for algorithm tuning. Constructed using control.simulate.ergm or control.simulate.formula

verbose

Logical: If TRUE, extra information is printed as the Markov chain progresses.

...

Further arguments passed to or used by methods.

Value

If nsim==1, simulate.ergm returns an object of class network. If nsim>1, it returns an object of class network.list: a list of networks with the following attr-style attributes on the list:
formulaThe formula used to generate the sample.
statsThe $\code{nsim}\times p$ matrix of network statistics, where $p$ is the number of network statistics specified in the model.
controlControl parameters used to generate the sample.
constraintsConstraints used to generate the sample.
monitorThe monitoring formula.
This object has summary and print methods.

Details

A sample of networks is randomly drawn from the specified model. The model is specified by the first argument of the function. If the first argument is a formula then this defines the model. If the first argument is the output of a call to ergm then the model used for that call is the one fit - and unless coef is specified, the sample is from the MLE of the parameters. If neither of those are given as the first argument then a Bernoulli network is generated with the probability of ties defined by prob or coef.

Note that the first network is sampled after burnin + interval steps, and any subsequent networks are sampled each interval steps after the first.

More information can be found by looking at the documentation of ergm.

Examples

Run this code

#
# Let's draw from a Bernoulli model with 16 nodes
# and density 0.5 (i.e., coef = c(0,0))
#
g.sim <- simulate(network(16) ~ edges + mutual, coef=c(0, 0))
#
# What are the statistics like?
#
summary(g.sim ~ edges + mutual)
#
# Now simulate a network with higher mutuality
#
g.sim <- simulate(network(16) ~ edges + mutual, coef=c(0,2))
#
# How do the statistics look?
#
summary(g.sim ~ edges + mutual)
#
# Let's draw from a Bernoulli model with 16 nodes
# and tie probability 0.1
#
g.use <- network(16,density=0.1,directed=FALSE)
#
# Starting from this network let's draw 3 realizations
# of a edges and 2-star network
#
g.sim <- simulate(~edges+kstar(2), nsim=3, coef=c(-1.8,0.03),
               basis=g.use, control=control.simulate(
                 MCMC.burnin=100000,
                 MCMC.interval=1000))
g.sim
summary(g.sim)
#
# attach the Florentine Marriage data
#
data(florentine)
#
# fit an edges and 2-star model using the ergm function
#
gest <- ergm(flomarriage ~ edges + kstar(2))
summary(gest)
#
# Draw from the fitted model (satatistics only), and observe the number
# of triangles as well.
#
g.sim <- simulate(gest, nsim=100, 
            monitor=~triangles, statsonly=TRUE,
            control=control.simulate(MCMC.burnin=1000, MCMC.interval=1000))
head(g.sim)