Generating missing values
To generate missing values in a dataset with missMethods you can use
one of the delete_ functions. The names of these functions
always starts with delete_ and the next part of the name
shows the used missing data mechanism. There are three basic types of
missing data mechanisms: missing completely at random
(MCAR), missing at random (MAR) and missing
not at random (MNAR). A list of all available functions for
the different mechanisms is given below:
MCAR
MAR
delete_MAR_1_to_x()delete_MAR_censoring()delete_MAR_one_group()delete_MAR_rank()
MNAR
delete_MNAR_1_to_x()delete_MNAR_censoring()delete_MNAR_one_group()delete_MNAR_rank()
All these functions share a common interface. The first argument
ds takes the dataset in which missing values should be
generated. The next argument p specifies the proportion of
missing values to include in every column with missing value. These
columns are specified with the third argument cols_mis. The
further arguments depend on the chosen function and are documented for
every function separately. In most cases, reasonable defaults are set
for these further arguments. Only the MAR functions need
one additional argument with no default: cols_ctrl. The
argument cols_ctrl specifies the columns that control the
generation of missing data in a MAR settings.
One further remark: All MAR functions have a
MNAR twin. These twins behave exactly the same way. The
only difference is the columns that controls the generation of missing
values. In the MAR functions separate
cols_ctrl columns controls the generation of missing values
in the cols_mis columns. In contrast, in the
MNAR functions the generation of missing values in the
cols_mis columns is controlled by the cols_mis
columns themselves.
In the following, different examples for the generation of missing
values will be presented. Furthermore, connections between the functions
from missMethods and the paper by Santos et al.
(2019) will be shown.
Examples for the generation of missing values
The examples below show the use of some delete_
functions in a 2-dimensional dataset. Missing values are always
generated in the variable “X” and 30 % of the values are deleted. At
first, a basic set-up:
library(missMethods)
library(ggplot2)
set.seed(123)
make_simple_MDplot <- function(ds_comp, ds_mis) {
ds_comp$missX <- is.na(ds_mis$X)
ggplot(ds_comp, aes(x = X, y = Y, col = missX)) +
geom_point()
}
# generate complete data frame
ds_comp <- data.frame(X = rnorm(100), Y = rnorm(100))
MCAR
Generate MCAR values:
ds_mcar <- delete_MCAR(ds_comp, 0.3, "X")
make_simple_MDplot(ds_comp, ds_mcar)
MAR
Generate MAR values using a censoring mechanism. This leads to a
missing value in “X”, if the y-value is below the 30 % quantile of
“Y”:
ds_mar <- delete_MAR_censoring(ds_comp, 0.3, "X", cols_ctrl = "Y")
make_simple_MDplot(ds_comp, ds_mar)
The censoring mechanism is a rather strong form of MAR. A function
that allows to control the strength of the MAR mechanism is
delete_MAR_1_to_x. The strength is controlled through the
argument x: the bigger x, the stronger the
simulated MAR mechanism:
# x = 2
ds_mar <- delete_MAR_1_to_x(ds_comp, 0.3, "X", cols_ctrl = "Y", x = 2)
make_simple_MDplot(ds_comp, ds_mar)
# x = 10
ds_mar <- delete_MAR_1_to_x(ds_comp, 0.3, "X", cols_ctrl = "Y", x = 10)
make_simple_MDplot(ds_comp, ds_mar)
MNAR
Generate MAR values using a censoring mechanism. This leads to a
missing value in “X”, if the x-value is below the 30 % quantile of
“X”:
ds_mnar <- delete_MNAR_censoring(ds_comp, 0.3, "X")
make_simple_MDplot(ds_comp, ds_mnar)
Connections between missMethods and Santos et
al. (2019)
The following table shows the connections between the algorithm names
of the missing data creation methods in Santos et
al. (2019) and the functions of missMethods:
| MCAR1univa |
delete_MCAR |
n_mis_stochastic = FALSE |
| MCAR2univa |
delete_MCAR |
all default |
| MCAR3univa |
delete_MCAR |
all default |
| MAR1univa |
delete_MAR_censoring |
sorting = FALSE |
| MAR2univa |
delete_MAR_rank |
all default |
| MAR3univa |
delete_MAR_1_to_x |
x = 1/9 |
| MAR4univa |
delete_MAR_censoring |
where = “upper” |
| MAR5univa |
delete_MAR_censoring |
where = “both” |
| MNAR1univa |
delete_MNAR_censoring |
sorting = FALSE |
| MNAR2univa |
delete_MNAR_censoring |
where = “upper” |
| MCAR1unifo |
delete_MCAR |
n_mis_stochastic = FALSE |
| MCAR2unifo |
delete_MCAR |
p_overall = TRUE |
| MAR1unifo |
delete_MAR_censoring |
all default |
| MAR2unifo |
delete_MAR_censoring |
sorting = FALSE |
| MAR3unifo |
delete_MAR_one_group |
all default |
| MAR4unifo |
delete_MAR_one_group |
all default |
| MNAR1unifo |
delete_MNAR_censoring |
all default |
| MNAR2unifo |
delete_MNAR_censoring |
sorting = FALSE |
| MNAR3unifo |
delete_MAR_one_group |
all default |
| MNAR4unifo |
delete_MAR_one_group |
all default |
Only the argument(s), which default values must be altered, are shown
in the table. Notice that most functions in missMethods are more general
than the described algorithms in Santos et al.
(2019). Therefore, some functions of missMethods are able to
replace different algorithms from Santos et al.
(2019). In contrast to Santos et al.
(2019), the user must always specify the missing column(s).
However, this may change in the future.
References
Santos, M. S., R. C. Pereira, A. F. Costa, J. P. Soares, J. Santos, and
P. H. Abreu. 2019.
“Generating Synthetic Missing Data: A Review by
Missing Mechanism.” IEEE Access 7: 11651–67.
https://doi.org/10.1109/ACCESS.2019.2891360.