This vignette describes a new feature to BGGM (2.0.0
) that allows for computing custom network statistics (e.g., centrality). The new function is called roll_your_own
and it was suggested by a user of BGGM (see feature request here).
The basic idea is to compute the chosen network statistic for each of the sampled partial correlation matrices, resulting in a distribution. All that is required is to define a function that takes either a partial correlation matrix or a weighted adjacency matrix (the partial correlation matrix with values set to zero) as the first argument. Several examples are provided below.
# need the developmental version
if (!requireNamespace("remotes")) {
install.packages("remotes")
}
# install from github
::install_github("donaldRwilliams/BGGM") remotes
In all examples, a subset of ptsd
data is used. The subset includes two of the “communities” of symptoms (details for these data can be found in Armour et al. 2017). The data are ordinal (5-level Likert).
# need these packages
library(BGGM)
library(ggplot2)
library(assortnet)
library(networktools)
# data
<- ptsd[,1:7] Y
For these data, the GGM is estimated with a semi-parametric copula (Hoff 2007). In BGGM, this implemented with type = mixed
which is kind of a misnomer because the data do not have to be “mixed” (consisting of continuous and discrete variables). Note that the model is fitted only once which highlights that only the posterior samples are needed to compute any network statistic.
library(BGGM)
# copula ggm
<- estimate(Y, type = "mixed", iter = 1000) fit
The first example computes expected influence (Robinaugh, Millner, and McNally 2016). The first step is to define a function
# define function
<- function(x,...){
f ::expectedInf(x,...)$step1
networktools }
Note that x
takes the matrix which is then passed to expectedInf
. The ...
allows for passing additional arguments to the expectedInf
function. An example is provided below. With the function defined, the next step is to compute the network statistic.
# iter = 250 for demonstrative purposes
# (but note even 1000 iters takes less than 1 second)
# compute
<- roll_your_own(object = fit,
net_stat FUN = f,
select = FALSE,
iter = 250)
# print
net_stat
#> BGGM: Bayesian Gaussian Graphical Models
#> ---
#> Network Stats: Roll Your Own
#> Posterior Samples: 250
#> ---
#> Estimates:
#>
#> Node Post.mean Post.sd Cred.lb Cred.ub
#> 1 0.701 0.099 0.508 0.871
#> 2 0.912 0.113 0.722 1.179
#> 3 0.985 0.112 0.742 1.199
#> 4 1.056 0.105 0.851 1.247
#> 5 1.056 0.116 0.862 1.288
#> 6 0.491 0.092 0.329 0.679
#> 7 0.698 0.098 0.521 0.878
#> ---
The option select = FALSE
indicates to compute the statistics from the partial correlation matrices (nothing set to zero). This can be changed with select = TRUE
. Internally, each of the sampled partial correlation matrices is multiplied by the adjacency matrix.
<- roll_your_own(object = fit,
net_stat FUN = f,
select = TRUE,
iter = 250)
# print
net_stat
#> BGGM: Bayesian Gaussian Graphical Models
#> ---
#> Network Stats: Roll Your Own
#> Posterior Samples: 250
#> ---
#> Estimates:
#>
#> Node Post.mean Post.sd Cred.lb Cred.ub
#> 1 0.636 0.136 0.386 0.874
#> 2 0.792 0.113 0.580 0.996
#> 3 0.777 0.122 0.544 1.001
#> 4 0.910 0.121 0.667 1.143
#> 5 0.525 0.104 0.331 0.727
#> 6 0.484 0.110 0.270 0.686
#> 7 0.247 0.081 0.088 0.412
#> ---
The results are then plotted with
plot(net_stat)
The next example computes bridge strength (Jones, Ma, and McNally 2019). This requires the user to define clusters or “communities.”
# clusters
<- substring(colnames(Y), 1, 1)
communities
# function is slow
<- function(x, ...){
f ::bridge(x, ...)$`Bridge Strength`
networktools
}
# compute
<- roll_your_own(object = fit,
net_stat FUN = f,
communities = communities,
iter = 250)
# print
net_stat
#> BGGM: Bayesian Gaussian Graphical Models
#> ---
#> Network Stats: Roll Your Own
#> Posterior Samples: 250
#> ---
#> Estimates:
#>
#> Node Post.mean Post.sd Cred.lb Cred.ub
#> 1 0.162 0.082 0.035 0.347
#> 2 0.250 0.113 0.061 0.501
#> 3 0.180 0.104 0.049 0.480
#> 4 0.280 0.098 0.090 0.480
#> 5 0.375 0.093 0.196 0.558
#> 6 0.617 0.166 0.339 1.002
#> 7 0.628 0.166 0.400 1.025
#> ---
Notice communities
. This is passed to ...
in the function f
, which, in turn, is passed to the function bridge
. Any number of arguments can be passed this way. Here are the results
This can then be plotted and further customized (the returned object is a ggplot
)
plot(net_stat,
fill = "lightblue") +
ggtitle("Bridge Strength") +
xlab("Score")
The next example computes assortment (Newman 2003).
# clusters
<- substring(colnames(Y), 1, 1)
communities
# define function
<- function(x,...){
f ::assortment.discrete(x, ...)$r
assortnet
}
<- roll_your_own(object = fit,
net_stat FUN = f,
types = communities,
weighted = TRUE,
SE = FALSE, M = 1,
iter = 250)
# print
net_stat
#> BGGM: Bayesian Gaussian Graphical Models
#> ---
#> Network Stats: Roll Your Own
#> Posterior Samples: 250
#> ---
#> Estimates:
#>
#> Post.mean Post.sd Cred.lb Cred.ub
#> 0.261 0.124 -0.01 0.469
#> ---
This example demonstrate that ...
can take several arguments. The results are stored in the net_stat
object. They can be accessed with
hist(net_stat$results, main = "Assortment")
The function roll_your_own
is expecting the custom function to return either a single number or a number for each node. This ensures all the printing and plotting functions work. However, you could return anything you want and then access the results to plot, summarize, etc.