04mi | R Documentation |
The mi
function cannot be run in isolation. It is the most important step of a multi-step process to perform multiple imputation. The data must be specified as a missing_data.frame
before mi
is used to impute missing values for one or more missing_variable
s. An iterative algorithm is used where each missing_variable
is modeled (using fit_model
) as a function of all the other missing_variable
s and their missingness patterns. This documentation outlines the technical uses of the mi
function. For a more general discussion of how to use mi
for multiple imputation, see mi-package
.
mi(y, model, ...) ## Hidden arguments: ## n.iter = 30, n.chains = 4, max.minutes = Inf, seed = NA, verbose = TRUE, ## save_models = FALSE, parallel = .Platform$OS.type != "windows"
y |
Typically an object that inherits from the |
model |
Missing when |
... |
Further arguments, the most important of which are
|
It is important to distinguish the two mi
methods that are most relevant to users from the many mi
methods that are less relevant. The primary mi
method is that where y
inherits from the missing_data.frame-class
and model
is omitted. This method “does” the imputation according to the additional arguments described under ... above and returns an object of class "mi"
. Executing two or more independent chains is important for monitoring the convergence
of each chain, see Rhats
.
If the chains have not converged in the amount of iterations or time specified, the second important mi
method is that where y
is an object of class "mi"
and model
is omitted, which continues a previous run of the iterative imputation algorithm. All the arguments described under ... above remain applicable, except for n.chains
and save_RAM
because these are established by the previous run that is being continued.
The numerous remaining methods are of less importance to users. One mi
method is called when y = "parallel"
and model
is omitted. This method merely sets up the parallel backend so that the chains can be executed in parallel on the local machine. We use the mclapply
function in the parallel package to implement parallel processing on non-Windows machines, and we use the snow package to implement parallel processing on Windows machines; we refer users to the documentation for these packages for more detail about parallel processing. Parallel processing is used by default on machines with multiple processors, but sequential processing can be used instead by using the parallel=FALSE
option. If the user is not using a mulitcore computer, sequential processing is used instead of parallel processing.
The first two mi
methods described above in turn call a mi
method where y
inherits from the missing_data.frame-class
and model
is that which is returned by one of the fit_model-methods
. The methods impute values for the originally missing values of a missing_variable
given a fitted model, according to the imputation_method slot of the missing_variable
in question. Advanced users could define new subclasses of the missing_variable-class
in which case it may be necessary to write such a mi
method for the new class. It will almost certainly be necessary to add to the
fit_model-methods
. The existing mi
and fit-model-methods
should provide a template for doing so.
If model
is missing and n.chains
is positive, then the mi
method will return an object of
class "mi"
, which has the following slots:
the call to mi
a list of missing_data.frame
s, one for each chain
an integer vector that records how many iterations have been performed
There are a few methods for such an object, such as show
, summary
,
dimnames
, nrow
, ncol
, etc.
If mi
is called on a missing_data.frame
with model
missing and a nonpositive
n.chains
, then the missing_data.frame
will be returned after allocating storeage.
If model
is not missing, then the mi
method will impute missing values for the y
argument and return it.
Ben Goodrich and Jonathan Kropko, for this version, based on earlier versions written by Yu-Sung Su, Masanao Yajima, Maria Grazia Pittau, Jennifer Hill, and Andrew Gelman.
missing_data.frame
, fit_model
# STEP 0: Get data data(CHAIN, package = "mi") # STEP 1: Convert to a missing_data.frame mdf <- missing_data.frame(CHAIN) # warnings about missingness patterns show(mdf) # STEP 2: change things mdf <- change(mdf, y = "log_virus", what = "transformation", to = "identity") # STEP 3: look deeper summary(mdf) # STEP 4: impute ## Not run: imputations <- mi(mdf) ## End(Not run)
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