GridSearch: Tune Predictive Model Hyper-parameters with Grid Search
In dmolitor/modelselection: Model Selection and Tuning Utilities
GridSearch R Documentation
Tune Predictive Model Hyper-parameters with Grid Search
Description
GridSearch allows the user to specify a Grid Search schema for tuning
predictive model hyper-parameters with complete flexibility in the predictive
model and performance metrics.
Public fields
learnerPredictive modeling function.
scorerList of performance metric functions.
tune_paramsData.frame of full hyper-parameter grid created from
$tune_params
Methods
Public methods
Method fit()
fit tunes user-specified model hyper-parameters via Grid Search.
Usage
GridSearch$fit(
formula = NULL,
data = NULL,
x = NULL,
y = NULL,
progress = FALSE
)
Arguments
formulaAn object of class formula: a symbolic description of
the model to be fitted.
dataAn optional data frame, or other object containing the
variables in the model. If data is not provided, how formula is
handled depends on $learner.
xPredictor data (independent variables), alternative interface to
data with formula.
yResponse vector (dependent variable), alternative interface to
data with formula.
progressLogical; indicating whether to print progress across
cross validation folds.
Details
fit follows standard R modeling convention by surfacing a formula
modeling interface as well as an alternate matrix option. The user should
use whichever interface is supported by the specified $learner
function.
Returns
An object of class FittedGridSearch.
Examples
if (require(rpart) && require(rsample) && require(yardstick)) {
iris_new <- iris[sample(1:nrow(iris), nrow(iris)), ]
iris_new$Species <- factor(iris_new$Species == "virginica")
iris_train <- iris_new[1:100, ]
iris_validate <- iris_new[101:150, ]
### Basic Example
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(accuracy = yardstick::accuracy_vec),
optimize_score = "max",
prediction_args = list(accuracy = list(type = "class"))
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train
)
### Example with multiple metric functions
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(
accuracy = yardstick::accuracy_vec,
auc = yardstick::roc_auc_vec
),
optimize_score = "max",
prediction_args = list(
accuracy = list(type = "class"),
auc = list(type = "prob")
),
convert_predictions = list(
accuracy = NULL,
auc = function(i) i[, "FALSE"]
)
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train,
)
}
Method new()
Create a new GridSearch object.
Usage
GridSearch$new(
learner = NULL,
tune_params = NULL,
evaluation_data = NULL,
scorer = NULL,
optimize_score = c("min", "max"),
learner_args = NULL,
scorer_args = NULL,
prediction_args = NULL,
convert_predictions = NULL
)
Arguments
learnerFunction that estimates a predictive model. It is
essential that this function support either a formula interface with
formula and data arguments, or an alternate matrix interface with
x and y arguments.
tune_paramsA named list specifying the arguments of $learner to
tune.
evaluation_dataA two-element list containing the following
elements: x, the validation data to generate predicted values with;
y, the validation response values to evaluate predictive performance.
scorerA named list of metric functions to evaluate model
performance on evaluation_data. Any provided metric function
must have truth and estimate arguments, for true outcome values and
predicted outcome values respectively, and must return a single numeric
metric value. The last metric function will be the one used to identify
the optimal model from the Grid Search.
optimize_scoreOne of "max" or "min"; Whether to maximize or
minimize the metric defined in scorer to find the optimal Grid Search
parameters.
learner_argsA named list of additional arguments to pass to
learner.
scorer_argsA named list of additional arguments to pass to
scorer. scorer_args must either be length 1 or length(scorer) in
the case where different arguments are being passed to each scoring
function.
prediction_argsA named list of additional arguments to pass to
predict. prediction_args must either be length 1 or
length(scorer) in the case where different arguments are being passed
to each scoring function.
convert_predictionsA list of functions to convert predicted
values prior to being evaluated by the metric functions supplied in
scorer. This list should either be length 1, in which case the same
function will be applied to all predicted values, or length(scorer)
in which case each function in convert_predictions will correspond
with each function in scorer.
Returns
An object of class GridSearch.
Method clone()
The objects of this class are cloneable with this method.
Usage
GridSearch$clone(deep = FALSE)
Arguments
deepWhether to make a deep clone.
Examples
## ------------------------------------------------
## Method `GridSearch$fit`
## ------------------------------------------------
if (require(rpart) && require(rsample) && require(yardstick)) {
iris_new <- iris[sample(1:nrow(iris), nrow(iris)), ]
iris_new$Species <- factor(iris_new$Species == "virginica")
iris_train <- iris_new[1:100, ]
iris_validate <- iris_new[101:150, ]
### Basic Example
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(accuracy = yardstick::accuracy_vec),
optimize_score = "max",
prediction_args = list(accuracy = list(type = "class"))
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train
)
### Example with multiple metric functions
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(
accuracy = yardstick::accuracy_vec,
auc = yardstick::roc_auc_vec
),
optimize_score = "max",
prediction_args = list(
accuracy = list(type = "class"),
auc = list(type = "prob")
),
convert_predictions = list(
accuracy = NULL,
auc = function(i) i[, "FALSE"]
)
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train,
)
}
dmolitor/modelselection documentation built on Jan. 4, 2023, 1:08 p.m.
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| GridSearch | R Documentation |
Tune Predictive Model Hyper-parameters with Grid Search
Description
GridSearch allows the user to specify a Grid Search schema for tuning
predictive model hyper-parameters with complete flexibility in the predictive
model and performance metrics.
Public fields
learnerPredictive modeling function.
scorerList of performance metric functions.
tune_paramsData.frame of full hyper-parameter grid created from
$tune_params
Methods
Public methods
Method fit()
fit tunes user-specified model hyper-parameters via Grid Search.
Usage
GridSearch$fit( formula = NULL, data = NULL, x = NULL, y = NULL, progress = FALSE )
Arguments
formulaAn object of class formula: a symbolic description of the model to be fitted.
dataAn optional data frame, or other object containing the variables in the model. If
datais not provided, howformulais handled depends on$learner.xPredictor data (independent variables), alternative interface to data with formula.
yResponse vector (dependent variable), alternative interface to data with formula.
progressLogical; indicating whether to print progress across cross validation folds.
Details
fit follows standard R modeling convention by surfacing a formula
modeling interface as well as an alternate matrix option. The user should
use whichever interface is supported by the specified $learner
function.
Returns
An object of class FittedGridSearch.
Examples
if (require(rpart) && require(rsample) && require(yardstick)) {
iris_new <- iris[sample(1:nrow(iris), nrow(iris)), ]
iris_new$Species <- factor(iris_new$Species == "virginica")
iris_train <- iris_new[1:100, ]
iris_validate <- iris_new[101:150, ]
### Basic Example
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(accuracy = yardstick::accuracy_vec),
optimize_score = "max",
prediction_args = list(accuracy = list(type = "class"))
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train
)
### Example with multiple metric functions
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(
accuracy = yardstick::accuracy_vec,
auc = yardstick::roc_auc_vec
),
optimize_score = "max",
prediction_args = list(
accuracy = list(type = "class"),
auc = list(type = "prob")
),
convert_predictions = list(
accuracy = NULL,
auc = function(i) i[, "FALSE"]
)
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train,
)
}
Method new()
Create a new GridSearch object.
Usage
GridSearch$new(
learner = NULL,
tune_params = NULL,
evaluation_data = NULL,
scorer = NULL,
optimize_score = c("min", "max"),
learner_args = NULL,
scorer_args = NULL,
prediction_args = NULL,
convert_predictions = NULL
)Arguments
learnerFunction that estimates a predictive model. It is essential that this function support either a formula interface with
formulaanddataarguments, or an alternate matrix interface withxandyarguments.tune_paramsA named list specifying the arguments of
$learnerto tune.evaluation_dataA two-element list containing the following elements:
x, the validation data to generate predicted values with;y, the validation response values to evaluate predictive performance.scorerA named list of metric functions to evaluate model performance on
evaluation_data. Any provided metric function must havetruthandestimatearguments, for true outcome values and predicted outcome values respectively, and must return a single numeric metric value. The last metric function will be the one used to identify the optimal model from the Grid Search.optimize_scoreOne of "max" or "min"; Whether to maximize or minimize the metric defined in
scorerto find the optimal Grid Search parameters.learner_argsA named list of additional arguments to pass to
learner.scorer_argsA named list of additional arguments to pass to
scorer.scorer_argsmust either be length 1 orlength(scorer)in the case where different arguments are being passed to each scoring function.prediction_argsA named list of additional arguments to pass to
predict.prediction_argsmust either be length 1 orlength(scorer)in the case where different arguments are being passed to each scoring function.convert_predictionsA list of functions to convert predicted values prior to being evaluated by the metric functions supplied in
scorer. This list should either be length 1, in which case the same function will be applied to all predicted values, orlength(scorer)in which case each function inconvert_predictionswill correspond with each function inscorer.
Returns
An object of class GridSearch.
Method clone()
The objects of this class are cloneable with this method.
Usage
GridSearch$clone(deep = FALSE)
Arguments
deepWhether to make a deep clone.
Examples
## ------------------------------------------------
## Method `GridSearch$fit`
## ------------------------------------------------
if (require(rpart) && require(rsample) && require(yardstick)) {
iris_new <- iris[sample(1:nrow(iris), nrow(iris)), ]
iris_new$Species <- factor(iris_new$Species == "virginica")
iris_train <- iris_new[1:100, ]
iris_validate <- iris_new[101:150, ]
### Basic Example
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(accuracy = yardstick::accuracy_vec),
optimize_score = "max",
prediction_args = list(accuracy = list(type = "class"))
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train
)
### Example with multiple metric functions
iris_grid <- GridSearch$new(
learner = rpart::rpart,
learner_args = list(method = "class"),
tune_params = list(
minsplit = seq(10, 30, by = 5),
maxdepth = seq(20, 30, by = 2)
),
evaluation_data = list(x = iris_validate, y = iris_validate$Species),
scorer = list(
accuracy = yardstick::accuracy_vec,
auc = yardstick::roc_auc_vec
),
optimize_score = "max",
prediction_args = list(
accuracy = list(type = "class"),
auc = list(type = "prob")
),
convert_predictions = list(
accuracy = NULL,
auc = function(i) i[, "FALSE"]
)
)
iris_grid_fitted <- iris_grid$fit(
formula = Species ~ .,
data = iris_train,
)
}
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