step_depth()
creates a specification of a recipe step that will convert
numeric data into a measurement of data depth. This is done for each value of
a categorical class variable.
Arguments
- recipe
A recipe object. The step will be added to the sequence of operations for this recipe.
- ...
One or more selector functions to choose variables for this step. See
selections()
for more details.- class
A single character string that specifies a single categorical variable to be used as the class.
- role
For model terms created by this step, what analysis role should they be assigned? By default, the new columns created by this step from the original variables will be used as predictors in a model.
- trained
A logical to indicate if the quantities for preprocessing have been estimated.
- metric
A character string specifying the depth metric. Possible values are "potential", "halfspace", "Mahalanobis", "simplicialVolume", "spatial", and "zonoid".
- options
A list of options to pass to the underlying depth functions. See
ddalpha::depth.halfspace()
,ddalpha::depth.Mahalanobis()
,ddalpha::depth.potential()
,ddalpha::depth.projection()
,ddalpha::depth.simplicial()
,ddalpha::depth.simplicialVolume()
,ddalpha::depth.spatial()
,ddalpha::depth.zonoid()
.- data
The training data are stored here once after
prep()
is executed.- prefix
A character string for the prefix of the resulting new variables. See notes below.
- keep_original_cols
A logical to keep the original variables in the output. Defaults to
TRUE
.- skip
A logical. Should the step be skipped when the recipe is baked by
bake()
? While all operations are baked whenprep()
is run, some operations may not be able to be conducted on new data (e.g. processing the outcome variable(s)). Care should be taken when usingskip = TRUE
as it may affect the computations for subsequent operations.- id
A character string that is unique to this step to identify it.
Value
An updated version of recipe
with the new step added to the
sequence of any existing operations.
Details
Data depth metrics attempt to measure how close data a
data point is to the center of its distribution. There are a
number of methods for calculating depth but a simple example is
the inverse of the distance of a data point to the centroid of
the distribution. Generally, small values indicate that a data
point not close to the centroid. step_depth
can compute a
class-specific depth for a new data point based on the proximity
of the new value to the training set distribution.
This step requires the ddalpha package. If not installed, the step will stop with a note about installing the package.
Note that the entire training set is saved to compute future
depth values. The saved data have been trained (i.e. prepared)
and baked (i.e. processed) up to the point before the location
that step_depth
occupies in the recipe. Also, the data
requirements for the different step methods may vary. For
example, using metric = "Mahalanobis"
requires that each
class should have at least as many rows as variables listed in
the terms
argument.
The function will create a new column for every unique value of
the class
variable. The resulting variables will not
replace the original values and by default have the prefix depth_
. The
naming format can be changed using the prefix
argument.
Tidying
When you tidy()
this step, a tibble is returned with
columns terms
, class
, and id
:
- terms
character, the selectors or variables selected
- class
character, name of class variable
- id
character, id of this step
See also
Other multivariate transformation steps:
step_classdist()
,
step_classdist_shrunken()
,
step_geodist()
,
step_ica()
,
step_isomap()
,
step_kpca()
,
step_kpca_poly()
,
step_kpca_rbf()
,
step_mutate_at()
,
step_nnmf()
,
step_nnmf_sparse()
,
step_pca()
,
step_pls()
,
step_ratio()
,
step_spatialsign()
Examples
# halfspace depth is the default
rec <- recipe(Species ~ ., data = iris) %>%
step_depth(all_numeric_predictors(), class = "Species")
# use zonoid metric instead
# also, define naming convention for new columns
rec <- recipe(Species ~ ., data = iris) %>%
step_depth(all_numeric_predictors(),
class = "Species",
metric = "zonoid", prefix = "zonoid_"
)
rec_dists <- prep(rec, training = iris)
dists_to_species <- bake(rec_dists, new_data = iris)
dists_to_species
#> # A tibble: 150 × 8
#> Sepal.Length Sepal.Width Petal.Length Petal.Width Species zonoid_setosa
#> <dbl> <dbl> <dbl> <dbl> <fct> <dbl>
#> 1 5.1 3.5 1.4 0.2 setosa 0.559
#> 2 4.9 3 1.4 0.2 setosa 0.167
#> 3 4.7 3.2 1.3 0.2 setosa 0.299
#> 4 4.6 3.1 1.5 0.2 setosa 0.170
#> 5 5 3.6 1.4 0.2 setosa 0.391
#> 6 5.4 3.9 1.7 0.4 setosa 0.0838
#> 7 4.6 3.4 1.4 0.3 setosa 0.0200
#> 8 5 3.4 1.5 0.2 setosa 0.645
#> 9 4.4 2.9 1.4 0.2 setosa 0.02
#> 10 4.9 3.1 1.5 0.1 setosa 0.0200
#> # ℹ 140 more rows
#> # ℹ 2 more variables: zonoid_versicolor <dbl>, zonoid_virginica <dbl>
tidy(rec, number = 1)
#> # A tibble: 1 × 3
#> terms class id
#> <chr> <chr> <chr>
#> 1 all_numeric_predictors() NA depth_eCCL8
tidy(rec_dists, number = 1)
#> # A tibble: 4 × 3
#> terms class id
#> <chr> <chr> <chr>
#> 1 Sepal.Length Species depth_eCCL8
#> 2 Sepal.Width Species depth_eCCL8
#> 3 Petal.Length Species depth_eCCL8
#> 4 Petal.Width Species depth_eCCL8