Conducts a Yeo-Johnson transformation on numeric features. It therefore estimates
the optimal value of lambda for the transformation.
See bestNormalize::yeojohnson() for details.
R6Class object inheriting from PipeOpTaskPreproc/PipeOp.
PipeOpYeoJohnson$new(id = "yeojohnson", param_vals = list())
id :: character(1)
Identifier of resulting object, default "yeojohnson".
param_vals :: named list
List of hyperparameter settings, overwriting the hyperparameter settings that would otherwise be set during construction. Default list().
Input and output channels are inherited from PipeOpTaskPreproc.
The output is the input Task with all affected numeric features replaced by their transformed versions.
The $state is a named list with the $state elements inherited from PipeOpTaskPreproc,
as well as a list of class yeojohnson for each column, which is transformed.
The parameters are the parameters inherited from PipeOpTaskPreproc, as well as:
eps :: numeric(1)
Tolerance parameter to identify the lambda parameter as zero.
For details see yeojohnson().
standardize :: logical
Whether to center and scale the transformed values to attempt a standard
normal distribution. For details see yeojohnson().
lower :: numeric(1)
Lower value for estimation of lambda parameter.
For details see yeojohnson().
upper :: numeric(1)
Upper value for estimation of lambda parameter.
For details see yeojohnson().
Uses the bestNormalize::yeojohnson function.
Only methods inherited from PipeOpTaskPreproc/PipeOp.
Other PipeOps:
PipeOpEnsemble,
PipeOpImpute,
PipeOpTargetTrafo,
PipeOpTaskPreprocSimple,
PipeOpTaskPreproc,
PipeOp,
mlr_pipeops_boxcox,
mlr_pipeops_branch,
mlr_pipeops_chunk,
mlr_pipeops_classbalancing,
mlr_pipeops_classifavg,
mlr_pipeops_classweights,
mlr_pipeops_colapply,
mlr_pipeops_collapsefactors,
mlr_pipeops_colroles,
mlr_pipeops_copy,
mlr_pipeops_datefeatures,
mlr_pipeops_encodeimpact,
mlr_pipeops_encodelmer,
mlr_pipeops_encode,
mlr_pipeops_featureunion,
mlr_pipeops_filter,
mlr_pipeops_fixfactors,
mlr_pipeops_histbin,
mlr_pipeops_ica,
mlr_pipeops_imputeconstant,
mlr_pipeops_imputehist,
mlr_pipeops_imputelearner,
mlr_pipeops_imputemean,
mlr_pipeops_imputemedian,
mlr_pipeops_imputemode,
mlr_pipeops_imputeoor,
mlr_pipeops_imputesample,
mlr_pipeops_kernelpca,
mlr_pipeops_learner,
mlr_pipeops_missind,
mlr_pipeops_modelmatrix,
mlr_pipeops_multiplicityexply,
mlr_pipeops_multiplicityimply,
mlr_pipeops_mutate,
mlr_pipeops_nmf,
mlr_pipeops_nop,
mlr_pipeops_ovrsplit,
mlr_pipeops_ovrunite,
mlr_pipeops_pca,
mlr_pipeops_proxy,
mlr_pipeops_quantilebin,
mlr_pipeops_randomprojection,
mlr_pipeops_randomresponse,
mlr_pipeops_regravg,
mlr_pipeops_removeconstants,
mlr_pipeops_renamecolumns,
mlr_pipeops_replicate,
mlr_pipeops_scalemaxabs,
mlr_pipeops_scalerange,
mlr_pipeops_scale,
mlr_pipeops_select,
mlr_pipeops_smote,
mlr_pipeops_spatialsign,
mlr_pipeops_subsample,
mlr_pipeops_targetinvert,
mlr_pipeops_targetmutate,
mlr_pipeops_targettrafoscalerange,
mlr_pipeops_textvectorizer,
mlr_pipeops_threshold,
mlr_pipeops_tunethreshold,
mlr_pipeops_unbranch,
mlr_pipeops_updatetarget,
mlr_pipeops_vtreat,
mlr_pipeops
# NOT RUN {
library("mlr3")
task = tsk("iris")
pop = po("yeojohnson")
task$data()
pop$train(list(task))[[1]]$data()
pop$state
# }
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