step_pca {recipes} | R Documentation |
PCA signal extraction
Description
step_pca()
creates a specification of a recipe step that will convert
numeric variables into one or more principal components.
Usage
step_pca(
recipe,
...,
role = "predictor",
trained = FALSE,
num_comp = 5,
threshold = NA,
options = list(),
res = NULL,
columns = NULL,
prefix = "PC",
keep_original_cols = FALSE,
skip = FALSE,
id = rand_id("pca")
)
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 |
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. |
num_comp |
The number of components to retain as new predictors.
If |
threshold |
A fraction of the total variance that should be covered by
the components. For example, |
options |
A list of options to the default method for
|
res |
The |
columns |
A character string of the selected variable names. This field
is a placeholder and will be populated once |
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 |
skip |
A logical. Should the step be skipped when the
recipe is baked by |
id |
A character string that is unique to this step to identify it. |
Details
Principal component analysis (PCA) is a transformation of a group of variables that produces a new set of artificial features or components. These components are designed to capture the maximum amount of information (i.e. variance) in the original variables. Also, the components are statistically independent from one another. This means that they can be used to combat large inter-variables correlations in a data set.
It is advisable to standardize the variables prior to running
PCA. Here, each variable will be centered and scaled prior to
the PCA calculation. This can be changed using the
options
argument or by using step_center()
and step_scale()
.
The argument num_comp
controls the number of components that will be retained
(the original variables that are used to derive the components are removed from
the data). The new components will have names that begin with prefix
and a
sequence of numbers. The variable names are padded with zeros. For example, if
num_comp < 10
, their names will be PC1
- PC9
. If num_comp = 101
,
the names would be PC1
- PC101
.
Alternatively, threshold
can be used to determine the
number of components that are required to capture a specified
fraction of the total variance in the variables.
Value
An updated version of recipe
with the new step added to the
sequence of any existing operations.
Tidying
When you tidy()
this step two things can happen depending
the type
argument. If type = "coef"
a tibble returned with 4 columns
terms
, value
, component
, and id
:
- terms
character, the selectors or variables selected
- value
numeric, variable loading
- component
character, principle component
- id
character, id of this step
If type = "variance"
a tibble returned with 4 columns terms
, value
,
component
, and id
:
- terms
character, type of variance
- value
numeric, value of the variance
- component
integer, principle component
- id
character, id of this step
Tuning Parameters
This step has 2 tuning parameters:
-
num_comp
: # Components (type: integer, default: 5) -
threshold
: Threshold (type: double, default: NA)
Case weights
This step performs an unsupervised operation that can utilize case weights.
As a result, case weights are only used with frequency weights. For more
information, see the documentation in case_weights and the examples on
tidymodels.org
.
References
Jolliffe, I. T. (2010). Principal Component Analysis. Springer.
See Also
Other multivariate transformation steps:
step_classdist()
,
step_classdist_shrunken()
,
step_depth()
,
step_geodist()
,
step_ica()
,
step_isomap()
,
step_kpca()
,
step_kpca_poly()
,
step_kpca_rbf()
,
step_mutate_at()
,
step_nnmf()
,
step_nnmf_sparse()
,
step_pls()
,
step_ratio()
,
step_spatialsign()
Examples
rec <- recipe(~., data = USArrests)
pca_trans <- rec %>%
step_normalize(all_numeric()) %>%
step_pca(all_numeric(), num_comp = 3)
pca_estimates <- prep(pca_trans, training = USArrests)
pca_data <- bake(pca_estimates, USArrests)
rng <- extendrange(c(pca_data$PC1, pca_data$PC2))
plot(pca_data$PC1, pca_data$PC2,
xlim = rng, ylim = rng
)
with_thresh <- rec %>%
step_normalize(all_numeric()) %>%
step_pca(all_numeric(), threshold = .99)
with_thresh <- prep(with_thresh, training = USArrests)
bake(with_thresh, USArrests)
tidy(pca_trans, number = 2)
tidy(pca_estimates, number = 2)
tidy(pca_estimates, number = 2, type = "variance")