No, it is not. However, this should be no problem as different priors are available in `bnlearn`

and, unless you have some very specific reason to use Laplace smoothing, which is one particular prior, these should do.

Once you have a structure, you learn parameters with the `bn.fit()`

function. Setting `method = "bayes"`

uses Bayesian estimation and the optional argument `iss`

determines the prior. The definition of `iss`

: "the imaginary sample size used by the bayes method to estimate the conditional probability tables (CPTs) associated with discrete nodes".

As an example, consder a binary root node X in some network. `bn.fit()`

returns `(Nx + iss / cptsize) / (N + iss)`

as the probability of `X = x`

, where `N`

is your number of samples, `Nx`

the number of samples with `X = x`

, and `cptsize`

the cardinality of `X`

; in this case `cptsize = 2`

because `X`

is binary. Laplace correction would require that `iss / cptsize`

always be equal to 1. Yet, `bnlearn`

uses the same `iss`

value for all CPTs and, `iss / cptsize`

will only be 1 if all variables have the same cardinality. Thus, for binary variables, you could indeed have Laplace correction by setting `iss = 2`

. In the general case, however, it is not possible.

See bnlearn::bn.fit difference and calculation of methods "mle" and "bayes" for some additional details.