Now, let’s see how you can use caugi in your own R
package. We will work through an example to illustrate how you could
approach this.
Imagine that you want to build a causal discovery function that
utilizes caugi for graph representation and manipulation.
While seemingly not a very good idea, let’s pretend your algorithmic
idea is to measure the correlation between variables and then draw
causal conclusions based on this1.
#' @title Correlation implies causation!
#'
#' @param df A `data.frame` with numeric columns
#'
#' @returns A `caugi` representing the causal graph that is totally true!
correlation_implies_causation <- function(df) {
NULL # not developed yet!
}Let’s assume we have a named data frame:
# create correlated data using MASS
df <- MASS::mvrnorm(
n = 100,
mu = c(0, 0, 0),
Sigma = matrix(c(
1, 0.8, 0.3,
0.8, 1, 0.4,
0.3, 0.4, 1
), nrow = 3)
) |> as.data.frame()
head(df)
#> V1 V2 V3
#> 1 -2.2248040 -0.8720414 0.00560844
#> 2 0.2526361 0.2097850 1.18506791
#> 3 0.3619044 -0.5104396 -0.95743426
#> 4 -0.5733562 -1.6093245 1.16043547
#> 5 -0.5471823 0.1960346 -0.83809176
#> 6 -0.2835526 0.4438799 0.09421533Now, we know that the caugi should include all
variables in the df. We don’t know if the graph is a
DAG, PDAG, or something else, so we will
create a graph of the UNKNOWN class. We can begin with
that, as a start:
We can now compute the correlation matrix and add edges based on some arbitrary threshold:
#' @title Correlation implies causation!
#'
#' @param df A `data.frame` with numeric columns
#'
#' @returns A `caugi` representing the causal graph that is totally true!
correlation_implies_causation <- function(df) {
cg <- caugi::caugi(nodes = names(df))
cor_matrix <- cor(df)
# Add edges for correlations above 0.5
for (i in seq_len(ncol(cor_matrix))) {
for (j in 1:i) {
if (i != j && abs(cor_matrix[i, j]) > 0.5) {
from <- names(df)[j]
to <- names(df)[i]
cg <- caugi::add_edges(cg, from = from, edge = "-->", to = to) # add edge to caugi
}
}
}
return(cg)
}Now, when you call correlation_implies_causation(df), it
will return a caugi graph with edges based on the
correlation threshold.
Let’s try it out!
cg <- correlation_implies_causation(df)
cg
#> <caugi object; 3 nodes, 1 edges; simple: TRUE; session=0x5565430772f0>
#> graph_class: UNKNOWN
#> nodes: V1, V2, V3
#> edges: V1-->V2The graph is ready to use!
Now, you might want to specify the class of the output graph. Let’s say that if possible the output should be a DAG (which is advantageous for several reasons), but you don’t want to enforce acyclicity in the algorithm, as that could sometimes cause your function to throw an error. You would rather have it return a graph in any case, but if it is a DAG, then we return a DAG.
#' @title Correlation implies causation!
#'
#' @param df A `data.frame` with numeric columns
#'
#' @returns A `caugi` representing the causal graph that is totally true!
correlation_implies_causation <- function(df) {
cg <- caugi::caugi(nodes = names(df))
cor_matrix <- cor(df)
# Add edges for correlations above 0.5
cg <- caugi::caugi(nodes = names(df))
cor_matrix <- cor(df)
# Add edges for correlations above 0.5
for (i in seq_len(ncol(cor_matrix))) {
for (j in 1:i) {
if (i != j && abs(cor_matrix[i, j]) > 0.5) {
from <- names(df)[j]
to <- names(df)[i]
cg <- caugi::add_edges(cg, from = from, edge = "-->", to = to) # add edge to caugi
}
}
}
if (caugi::is_dag(cg)) cg <- caugi::mutate_caugi(cg, class = "DAG")
return(cg)
}Now, when you call correlation_implies_causation(df), it
will return a caugi graph that is a DAG if possible,
otherwise an "UNKNOWN" graph.
You have now successfully integrated caugi into your own
R package function! Good luck and happy coding!
Note that correlation does not imply causation!↩︎