Model Categories¶
-
class
h2o.model.
ModelBase
[source]¶ Bases:
h2o.model.model_base.ModelBase
Base class for all models.
-
property
actual_params
¶ Dictionary of actual parameters of the model.
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aic
(train=False, valid=False, xval=False)[source]¶ Get the AIC (Akaike Information Criterium).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the AIC value for the training data.
valid (bool) – If valid is True, then return the AIC value for the validation data.
xval (bool) – If xval is True, then return the AIC value for the validation data.
- Returns
The AIC.
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auc
(train=False, valid=False, xval=False)[source]¶ Get the AUC (Area Under Curve).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the AUC value for the training data.
valid (bool) – If valid is True, then return the AUC value for the validation data.
xval (bool) – If xval is True, then return the AUC value for the validation data.
- Returns
The AUC.
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aucpr
(train=False, valid=False, xval=False)[source]¶ Get the aucPR (Area Under PRECISION RECALL Curve).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the aucpr value for the training data.
valid (bool) – If valid is True, then return the aucpr value for the validation data.
xval (bool) – If xval is True, then return the aucpr value for the validation data.
- Returns
The aucpr.
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biases
(vector_id=0)[source]¶ Return the frame for the respective bias vector.
- Param
vector_id: an integer, ranging from 0 to number of layers, that specifies the bias vector to return.
- Returns
an H2OFrame which represents the bias vector identified by vector_id
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coef
()[source]¶ Return the coefficients which can be applied to the non-standardized data.
Note: standardize = True by default, if set to False then coef() return the coefficients which are fit directly.
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coef_norm
()[source]¶ Return coefficients fitted on the standardized data (requires standardize = True, which is on by default).
These coefficients can be used to evaluate variable importance.
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cross_validation_fold_assignment
()[source]¶ Obtain the cross-validation fold assignment for all rows in the training data.
- Returns
H2OFrame
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cross_validation_holdout_predictions
()[source]¶ Obtain the (out-of-sample) holdout predictions of all cross-validation models on the training data.
This is equivalent to summing up all H2OFrames returned by cross_validation_predictions.
- Returns
H2OFrame
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cross_validation_metrics_summary
()[source]¶ Retrieve Cross-Validation Metrics Summary.
- Returns
The cross-validation metrics summary as an H2OTwoDimTable
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cross_validation_models
()[source]¶ Obtain a list of cross-validation models.
- Returns
list of H2OModel objects.
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cross_validation_predictions
()[source]¶ Obtain the (out-of-sample) holdout predictions of all cross-validation models on their holdout data.
Note that the predictions are expanded to the full number of rows of the training data, with 0 fill-in.
- Returns
list of H2OFrame objects.
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deepfeatures
(test_data, layer)[source]¶ Return hidden layer details.
- Parameters
test_data – Data to create a feature space on
layer – 0 index hidden layer
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property
default_params
¶ Dictionary of the default parameters of the model.
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download_model
(path='', filename=None)[source]¶ Download an H2O Model object to disk.
- Parameters
path – a path to the directory where the model should be saved.
filename – a filename for the saved model
- Returns
the path of the downloaded model
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download_mojo
(path='.', get_genmodel_jar=False, genmodel_name='')[source]¶ Download the model in MOJO format.
- Parameters
path – the path where MOJO file should be saved.
get_genmodel_jar – if True, then also download h2o-genmodel.jar and store it in folder
path
.genmodel_name – Custom name of genmodel jar
- Returns
name of the MOJO file written.
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download_pojo
(path='', get_genmodel_jar=False, genmodel_name='')[source]¶ Download the POJO for this model to the directory specified by path.
If path is an empty string, then dump the output to screen.
- Parameters
path – An absolute path to the directory where POJO should be saved.
get_genmodel_jar – if True, then also download h2o-genmodel.jar and store it in folder
path
.genmodel_name – Custom name of genmodel jar
- Returns
name of the POJO file written.
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property
end_time
¶ Timestamp (milliseconds since 1970) when the model training was ended.
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explain
(frame, columns=None, top_n_features=5, include_explanations='ALL', exclude_explanations=[], plot_overrides={}, figsize=(16, 9), render=True, qualitative_colormap='Dark2', sequential_colormap='RdYlBu_r')¶ Generate model explanations on frame data set.
The H2O Explainability Interface is a convenient wrapper to a number of explainabilty methods and visualizations in H2O. The function can be applied to a single model or group of models and returns an object containing explanations, such as a partial dependence plot or a variable importance plot. Most of the explanations are visual (plots). These plots can also be created by individual utility functions/methods as well.
- Parameters
models – a list of H2O models, an H2O AutoML instance, or an H2OFrame with a ‘model_id’ column (e.g. H2OAutoML leaderboard)
frame – H2OFrame
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable).
include_explanations – if specified, return only the specified model explanations (Mutually exclusive with exclude_explanations)
exclude_explanations – exclude specified model explanations
plot_overrides – overrides for individual model explanations
figsize – figure size; passed directly to matplotlib
render – if True, render the model explanations; otherwise model explanations are just returned
- Returns
H2OExplanation containing the model explanations including headers and descriptions
- Examples
>>> import h2o >>> from h2o.automl import H2OAutoML >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train an H2OAutoML >>> aml = H2OAutoML(max_models=10) >>> aml.train(y=response, training_frame=train) >>> >>> # Create the H2OAutoML explanation >>> aml.explain(test) >>> >>> # Create the leader model explanation >>> aml.leader.explain(test)
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explain_row
(frame, row_index, columns=None, top_n_features=5, include_explanations='ALL', exclude_explanations=[], plot_overrides={}, qualitative_colormap='Dark2', figsize=(16, 9), render=True)¶ Generate model explanations on frame data set for a given instance.
Explain the behavior of a model or group of models with respect to a single row of data. The function returns an object containing explanations, such as a partial dependence plot or a variable importance plot. Most of the explanations are visual (plots). These plots can also be created by individual utility functions/methods as well.
- Parameters
models – H2OAutoML object, supervised H2O model, or list of supervised H2O models
frame – H2OFrame
row_index – row index of the instance to inspect
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable).
include_explanations – if specified, return only the specified model explanations (Mutually exclusive with exclude_explanations)
exclude_explanations – exclude specified model explanations
plot_overrides – overrides for individual model explanations
qualitative_colormap – a colormap name
figsize – figure size; passed directly to matplotlib
render – if True, render the model explanations; otherwise model explanations are just returned
- Returns
H2OExplanation containing the model explanations including headers and descriptions
- Examples
>>> import h2o >>> from h2o.automl import H2OAutoML >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train an H2OAutoML >>> aml = H2OAutoML(max_models=10) >>> aml.train(y=response, training_frame=train) >>> >>> # Create the H2OAutoML explanation >>> aml.explain_row(test, row_index=0) >>> >>> # Create the leader model explanation >>> aml.leader.explain_row(test, row_index=0)
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feature_frequencies
(test_data)[source]¶ Retrieve the number of occurrences of each feature for given observations on their respective paths in a tree ensemble model. Available for GBM, Random Forest and Isolation Forest models.
- Parameters
test_data (H2OFrame) – Data on which to calculate feature frequencies.
- Returns
A new H2OFrame made of feature contributions.
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feature_interaction
(max_interaction_depth=100, max_tree_depth=100, max_deepening=-1, path=None)[source]¶ Feature interactions and importance, leaf statistics and split value histograms in a tabular form. Available for XGBoost and GBM.
Metrics: Gain - Total gain of each feature or feature interaction. FScore - Amount of possible splits taken on a feature or feature interaction. wFScore - Amount of possible splits taken on a feature or feature interaction weighed by the probability of the splits to take place. Average wFScore - wFScore divided by FScore. Average Gain - Gain divided by FScore. Expected Gain - Total gain of each feature or feature interaction weighed by the probability to gather the gain. Average Tree Index Average Tree Depth
- Parameters
max_interaction_depth – Upper bound for extracted feature interactions depth. Defaults to 100.
max_tree_depth – Upper bound for tree depth. Defaults to 100.
max_deepening – Upper bound for interaction start deepening (zero deepening => interactions starting at root only). Defaults to -1.
path – (Optional) Path where to save the output in .xlsx format (e.g.
/mypath/file.xlsx
). Please note that Pandas and XlsxWriter need to be installed for using this option. Defaults to None.
- Examples
>>> boston = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/gbm_test/BostonHousing.csv") >>> predictors = boston.columns[:-1] >>> response = "medv" >>> boston['chas'] = boston['chas'].asfactor() >>> train, valid = boston.split_frame(ratios=[.8]) >>> boston_xgb = H2OXGBoostEstimator(seed=1234) >>> boston_xgb.train(y=response, x=predictors, training_frame=train) >>> feature_interactions = boston_xgb.feature_interaction()
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property
full_parameters
¶ Dictionary of the full specification of all parameters.
-
get_xval_models
(key=None)[source]¶ Return a Model object.
- Parameters
key – If None, return all cross-validated models; otherwise return the model that key points to.
- Returns
A model or list of models.
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gini
(train=False, valid=False, xval=False)[source]¶ Get the Gini coefficient.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”
- Parameters
train (bool) – If train is True, then return the Gini Coefficient value for the training data.
valid (bool) – If valid is True, then return the Gini Coefficient value for the validation data.
xval (bool) – If xval is True, then return the Gini Coefficient value for the cross validation data.
- Returns
The Gini Coefficient for this binomial model.
-
h
(frame, variables)[source]¶ Calculates Friedman and Popescu’s H statistics, in order to test for the presence of an interaction between specified variables in h2o gbm and xgb models. H varies from 0 to 1. It will have a value of 0 if the model exhibits no interaction between specified variables and a correspondingly larger value for a stronger interaction effect between them. NaN is returned if a computation is spoiled by weak main effects and rounding errors.
See Jerome H. Friedman and Bogdan E. Popescu, 2008, “Predictive learning via rule ensembles”, Ann. Appl. Stat. 2:916-954, http://projecteuclid.org/download/pdfview_1/euclid.aoas/1223908046, s. 8.1.
- Parameters
frame – the frame that current model has been fitted to
variables – variables of the interest
- Returns
H statistic of the variables
- Examples
>>> prostate_train = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/logreg/prostate_train.csv") >>> prostate_train["CAPSULE"] = prostate_train["CAPSULE"].asfactor() >>> gbm_h2o = H2OGradientBoostingEstimator(ntrees=100, learn_rate=0.1, >>> max_depth=5, >>> min_rows=10, >>> distribution="bernoulli") >>> gbm_h2o.train(x=list(range(1,prostate_train.ncol)),y="CAPSULE", training_frame=prostate_train) >>> h = gbm_h2o.h(prostate_train, ['DPROS','DCAPS'])
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property
have_mojo
¶ True, if export to MOJO is possible
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property
have_pojo
¶ True, if export to POJO is possible
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ice_plot
(frame, column, target=None, max_levels=30, figsize=(16, 9), colormap='plasma', save_plot_path=None)¶ Plot Individual Conditional Expectations (ICE) for each decile
Individual conditional expectations (ICE) plot gives a graphical depiction of the marginal effect of a variable on the response. ICE plot is similar to partial dependence plot (PDP), PDP shows the average effect of a feature while ICE plot shows the effect for a single instance. The following plot shows the effect for each decile. In contrast to partial dependence plot, ICE plot can provide more insight especially when there is stronger feature interaction.
- Parameters
model – H2OModel
frame – H2OFrame
column – string containing column name
target – (only for multinomial classification) for what target should the plot be done
max_levels – maximum number of factor levels to show
figsize – figure size; passed directly to matplotlib
colormap – colormap name
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create the individual conditional expectations plot >>> gbm.ice_plot(test, column="alcohol")
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property
key
¶ - Returns
the unique key representing the object on the backend
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learning_curve_plot
(metric='AUTO', cv_ribbon=None, cv_lines=None, figsize=(16, 9), colormap=None, save_plot_path=None)¶ Learning curve
Create learning curve plot for an H2O Model. Learning curves show error metric dependence on learning progress, e.g., RMSE vs number of trees trained so far in GBM. There can be up to 4 curves showing Training, Validation, Training on CV Models, and Cross-validation error.
- Parameters
model – an H2O model
metric – a stopping metric
cv_ribbon – if True, plot the CV mean as a and CV standard deviation as a ribbon around the mean, if None, it will attempt to automatically determine if this is suitable visualisation
cv_lines – if True, plot scoring history for individual CV models, if None, it will attempt to automatically determine if this is suitable visualisation
figsize – figure size; passed directly to matplotlib
colormap – colormap to use
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create the learning curve plot >>> gbm.learning_curve_plot()
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logloss
(train=False, valid=False, xval=False)[source]¶ Get the Log Loss.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the log loss value for the training data.
valid (bool) – If valid is True, then return the log loss value for the validation data.
xval (bool) – If xval is True, then return the log loss value for the cross validation data.
- Returns
The log loss for this regression model.
-
mae
(train=False, valid=False, xval=False)[source]¶ Get the Mean Absolute Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the MAE value for the training data.
valid (bool) – If valid is True, then return the MAE value for the validation data.
xval (bool) – If xval is True, then return the MAE value for the cross validation data.
- Returns
The MAE for this regression model.
-
mean_residual_deviance
(train=False, valid=False, xval=False)[source]¶ Get the Mean Residual Deviances.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the Mean Residual Deviance value for the training data.
valid (bool) – If valid is True, then return the Mean Residual Deviance value for the validation data.
xval (bool) – If xval is True, then return the Mean Residual Deviance value for the cross validation data.
- Returns
The Mean Residual Deviance for this regression model.
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property
model_id
¶ Model identifier.
-
model_performance
(test_data=None, train=False, valid=False, xval=False, auc_type='none')[source]¶ Generate model metrics for this model on test_data.
- Parameters
test_data (H2OFrame) – Data set for which model metrics shall be computed against. All three of train, valid and xval arguments are ignored if test_data is not None.
train (bool) – Report the training metrics for the model.
valid (bool) – Report the validation metrics for the model.
xval (bool) – Report the cross-validation metrics for the model. If train and valid are True, then it defaults to True.
auc_type (String) – Change default AUC type for multinomial classification AUC/AUCPR calculation when test_data is not None. One of:
"auto"
,"none"
,"macro_ovr"
,"weighted_ovr"
,"macro_ovo"
,"weighted_ovo"
(default:"none"
). If type is “auto” or “none” AUC and AUCPR is not calculated.
- Returns
An object of class H2OModelMetrics.
-
mse
(train=False, valid=False, xval=False)[source]¶ Get the Mean Square Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the MSE value for the training data.
valid (bool) – If valid is True, then return the MSE value for the validation data.
xval (bool) – If xval is True, then return the MSE value for the cross validation data.
- Returns
The MSE for this regression model.
-
ntrees_actual
()[source]¶ Returns actual number of trees in a tree model. If early stopping enabled, GBM can reset the ntrees value. In this case, the actual ntrees value is less than the original ntrees value a user set before building the model.
Type:
float
-
null_degrees_of_freedom
(train=False, valid=False, xval=False)[source]¶ Retreive the null degress of freedom if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the null dof for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the null dof for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the null dof, or None if it is not present.
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null_deviance
(train=False, valid=False, xval=False)[source]¶ Retreive the null deviance if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the null deviance for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the null deviance for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the null deviance, or None if it is not present.
-
property
params
¶ Get the parameters and the actual/default values only.
- Returns
A dictionary of parameters used to build this model.
-
partial_plot
(data, cols=None, destination_key=None, nbins=20, weight_column=None, plot=True, plot_stddev=True, figsize=(7, 10), server=False, include_na=False, user_splits=None, col_pairs_2dpdp=None, save_plot_path=None, row_index=None, targets=None)[source]¶ Create partial dependence plot which gives a graphical depiction of the marginal effect of a variable on the response. The effect of a variable is measured in change in the mean response.
- Parameters
data (H2OFrame) – An H2OFrame object used for scoring and constructing the plot.
cols – Feature(s) for which partial dependence will be calculated.
destination_key – An key reference to the created partial dependence tables in H2O.
nbins – Number of bins used. For categorical columns make sure the number of bins exceed the level count. If you enable add_missing_NA, the returned length will be nbin+1.
weight_column – A string denoting which column of data should be used as the weight column.
plot – A boolean specifying whether to plot partial dependence table.
plot_stddev – A boolean specifying whether to add std err to partial dependence plot.
figsize – Dimension/size of the returning plots, adjust to fit your output cells.
server – Specify whether to activate matplotlib “server” mode. In this case, the plots are saved to a file instead of being rendered.
include_na – A boolean specifying whether missing value should be included in the Feature values.
user_splits – a dictionary containing column names as key and user defined split values as value in a list.
col_pairs_2dpdp – list containing pairs of column names for 2D pdp
save_plot_path – Fully qualified name to an image file the resulting plot should be saved to, e.g. ‘/home/user/pdpplot.png’. The ‘png’ postfix might be omitted. If the file already exists, it will be overridden. Plot is only saved if plot = True.
row_index – Row for which partial dependence will be calculated instead of the whole input frame.
targets – Target classes for multiclass model.
- Returns
Plot and list of calculated mean response tables for each feature requested + the resulting plot (can be accessed using result.figure()).
-
pd_plot
(frame, column, row_index=None, target=None, max_levels=30, figsize=(16, 9), colormap='Dark2', save_plot_path=None)¶ Plot partial dependence plot.
Partial dependence plot (PDP) gives a graphical depiction of the marginal effect of a variable on the response. The effect of a variable is measured in change in the mean response. PDP assumes independence between the feature for which is the PDP computed and the rest.
- Parameters
model – H2O Model object
frame – H2OFrame
column – string containing column name
row_index – if None, do partial dependence, if integer, do individual conditional expectation for the row specified by this integer
target – (only for multinomial classification) for what target should the plot be done
max_levels – maximum number of factor levels to show
figsize – figure size; passed directly to matplotlib
colormap – colormap name; used to get just the first color to keep the api and color scheme similar with pd_multi_plot
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create partial dependence plot >>> gbm.pd_plot(test, column="alcohol")
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permutation_importance
(frame, metric='AUTO', n_samples=10000, n_repeats=1, features=None, seed=-1, use_pandas=False)[source]¶ Get Permutation Variable Importance.
When n_repeats == 1, the result is similar to the one from varimp() method, i.e., it contains the following columns “Relative Importance”, “Scaled Importance”, and “Percentage”.
When n_repeats > 1, the individual columns correspond to the permutation variable importance values from individual runs which corresponds to the “Relative Importance” and also to the distance between the original prediction error and prediction error using a frame with a given feature permuted.
- Parameters
frame – training frame
metric – metric to be used. One of “AUTO”, “AUC”, “MAE”, “MSE”, “RMSE”, “logloss”, “mean_per_class_error”, “PR_AUC”. Defaults to “AUTO”.
n_samples – number of samples to be evaluated. Use -1 to use the whole dataset. Defaults to 10 000.
n_repeats – number of repeated evaluations. Defaults to 1.
features – features to include in the permutation importance. Use None to include all.
seed – seed for the random generator. Use -1 to pick a random seed. Defaults to -1.
use_pandas – set true to return pandas data frame.
- Returns
H2OTwoDimTable or Pandas data frame
-
permutation_importance_plot
(frame, metric='AUTO', n_samples=10000, n_repeats=1, features=None, seed=-1, num_of_features=10, server=False, save_plot_path=None)[source]¶ Plot Permutation Variable Importance. This method plots either a bar plot or if n_repeats > 1 a box plot and returns the variable importance table.
- Parameters
frame – training frame
metric – metric to be used. One of “AUTO”, “AUC”, “MAE”, “MSE”, “RMSE”, “logloss”, “mean_per_class_error”, “PR_AUC”. Defaults to “AUTO”.
n_samples – number of samples to be evaluated. Use -1 to use the whole dataset. Defaults to 10 000.
n_repeats – number of repeated evaluations. Defaults to 1.
features – features to include in the permutation importance. Use None to include all.
seed – seed for the random generator. Use -1 to pick a random seed. Defaults to -1.
num_of_features – number of features to plot. Defaults to 10.
server – if true set server settings to matplotlib and do not show the plot
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains H2OTwoDimTable with variable importance and the resulting figure (can be accessed using result.figure())
-
pr_auc
(train=False, valid=False, xval=False)[source]¶ ModelBase.pr_auc
is deprecated, please useModelBase.aucpr
instead.
-
predict
(test_data, custom_metric=None, custom_metric_func=None)[source]¶ Predict on a dataset.
- Parameters
test_data (H2OFrame) – Data on which to make predictions.
custom_metric – custom evaluation function defined as class reference, the class get uploaded into the cluster
custom_metric_func – custom evaluation function reference, e.g, result of upload_custom_metric
- Returns
A new H2OFrame of predictions.
-
predict_contributions
(test_data, output_format='Original', top_n=None, bottom_n=None, compare_abs=False)[source]¶ Predict feature contributions - SHAP values on an H2O Model (only GBM, XGBoost, DRF models and equivalent imported MOJOs).
Returned H2OFrame has shape (#rows, #features + 1) - there is a feature contribution column for each input feature, the last column is the model bias (same value for each row). The sum of the feature contributions and the bias term is equal to the raw prediction of the model. Raw prediction of tree-based model is the sum of the predictions of the individual trees before the inverse link function is applied to get the actual prediction. For Gaussian distribution the sum of the contributions is equal to the model prediction.
Note: Multinomial classification models are currently not supported.
- Parameters
test_data (H2OFrame) – Data on which to calculate contributions.
output_format (Enum) – Specify how to output feature contributions in XGBoost - XGBoost by default outputs contributions for 1-hot encoded features, specifying a Compact output format will produce a per-feature contribution. One of:
"Original"
,"Compact"
(default:"Original"
).top_n – Return only #top_n highest contributions + bias. If top_n<0 then sort all SHAP values in descending order If top_n<0 && bottom_n<0 then sort all SHAP values in descending order
bottom_n – Return only #bottom_n lowest contributions + bias If top_n and bottom_n are defined together then return array of #top_n + #bottom_n + bias If bottom_n<0 then sort all SHAP values in ascending order If top_n<0 && bottom_n<0 then sort all SHAP values in descending order
compare_abs – True to compare absolute values of contributions
- Returns
A new H2OFrame made of feature contributions.
- Examples
>>> prostate = "http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv" >>> fr = h2o.import_file(prostate) >>> predictors = list(range(2, fr.ncol)) >>> m = H2OGradientBoostingEstimator(ntrees=10, seed=1234) >>> m.train(x=predictors, y=1, training_frame=fr) >>> # Compute SHAP >>> m.predict_contributions(fr) >>> # Compute SHAP and pick the top two highest >>> m.predict_contributions(fr, top_n=2) >>> # Compute SHAP and pick the top two lowest >>> m.predict_contributions(fr, bottom_n=2) >>> # Compute SHAP and pick the top two highest regardless of the sign >>> m.predict_contributions(fr, top_n=2, compare_abs=True) >>> # Compute SHAP and pick top two lowest regardless of the sign >>> m.predict_contributions(fr, bottom_n=2, compare_abs=True) >>> # Compute SHAP values and show them all in descending order >>> m.predict_contributions(fr, top_n=-1) >>> # Compute SHAP and pick the top two highest and top two lowest >>> m.predict_contributions(fr, top_n=2, bottom_n=2)
-
predict_leaf_node_assignment
(test_data, type='Path')[source]¶ Predict on a dataset and return the leaf node assignment (only for tree-based models).
- Parameters
test_data (H2OFrame) – Data on which to make predictions.
type (Enum) – How to identify the leaf node. Nodes can be either identified by a path from to the root node of the tree to the node or by H2O’s internal node id. One of:
"Path"
,"Node_ID"
(default:"Path"
).
- Returns
A new H2OFrame of predictions.
-
r2
(train=False, valid=False, xval=False)[source]¶ Return the R squared for this regression model.
Will return R^2 for GLM Models and will return NaN otherwise.
The R^2 value is defined to be 1 - MSE/var, where var is computed as sigma*sigma.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the R^2 value for the training data.
valid (bool) – If valid is True, then return the R^2 value for the validation data.
xval (bool) – If xval is True, then return the R^2 value for the cross validation data.
- Returns
The R squared for this regression model.
-
residual_degrees_of_freedom
(train=False, valid=False, xval=False)[source]¶ Retreive the residual degress of freedom if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the residual dof for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the residual dof for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the residual dof, or None if it is not present.
-
residual_deviance
(train=False, valid=False, xval=None)[source]¶ Retreive the residual deviance if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the residual deviance for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the residual deviance for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the residual deviance, or None if it is not present.
-
rmse
(train=False, valid=False, xval=False)[source]¶ Get the Root Mean Square Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the RMSE value for the training data.
valid (bool) – If valid is True, then return the RMSE value for the validation data.
xval (bool) – If xval is True, then return the RMSE value for the cross validation data.
- Returns
The RMSE for this regression model.
-
rmsle
(train=False, valid=False, xval=False)[source]¶ Get the Root Mean Squared Logarithmic Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the RMSLE value for the training data.
valid (bool) – If valid is True, then return the RMSLE value for the validation data.
xval (bool) – If xval is True, then return the RMSLE value for the cross validation data.
- Returns
The RMSLE for this regression model.
-
property
run_time
¶ Model training time in milliseconds
-
save_model_details
(path='', force=False, filename=None)[source]¶ Save Model Details of an H2O Model in JSON Format to disk.
- Parameters
path – a path to save the model details at (hdfs, s3, local)
force – if True overwrite destination directory in case it exists, or throw exception if set to False.
filename – a filename for the saved model (file type is always .json)
- Returns str
the path of the saved model details
-
save_mojo
(path='', force=False, filename=None)[source]¶ Save an H2O Model as MOJO (Model Object, Optimized) to disk.
- Parameters
path – a path to save the model at (hdfs, s3, local)
force – if True overwrite destination directory in case it exists, or throw exception if set to False.
filename – a filename for the saved model (file type is always .zip)
- Returns str
the path of the saved model
-
score_history
()[source]¶ DEPRECATED. Use
scoring_history()
instead.
-
scoring_history
()[source]¶ Retrieve Model Score History.
- Returns
The score history as an H2OTwoDimTable or a Pandas DataFrame.
-
shap_explain_row_plot
(frame, row_index, columns=None, top_n_features=10, figsize=(16, 9), plot_type='barplot', contribution_type='both', save_plot_path=None)¶ SHAP local explanation
SHAP explanation shows contribution of features for a given instance. The sum of the feature contributions and the bias term is equal to the raw prediction of the model, i.e., prediction before applying inverse link function. H2O implements TreeSHAP which when the features are correlated, can increase contribution of a feature that had no influence on the prediction.
- Parameters
model – h2o tree model, such as DRF, XRT, GBM, XGBoost
frame – H2OFrame
row_index – row index of the instance to inspect
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable). When plot_type=”barplot”, then top_n_features will be chosen for each contribution_type.
figsize – figure size; passed directly to matplotlib
plot_type – either “barplot” or “breakdown”
contribution_type – One of “positive”, “negative”, or “both”. Used only for plot_type=”barplot”.
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create SHAP row explanation plot >>> gbm.shap_explain_row_plot(test, row_index=0)
-
shap_summary_plot
(frame, columns=None, top_n_features=20, samples=1000, colorize_factors=True, alpha=1, colormap=None, figsize=(12, 12), jitter=0.35, save_plot_path=None)¶ SHAP summary plot
SHAP summary plot shows contribution of features for each instance. The sum of the feature contributions and the bias term is equal to the raw prediction of the model, i.e., prediction before applying inverse link function.
- Parameters
model – h2o tree model, such as DRF, XRT, GBM, XGBoost
frame – H2OFrame
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable).
samples – maximum number of observations to use; if lower than number of rows in the frame, take a random sample
colorize_factors – if True, use colors from the colormap to colorize the factors; otherwise all levels will have same color
alpha – transparency of the points
colormap – colormap to use instead of the default blue to red colormap
figsize – figure size; passed directly to matplotlib
jitter – amount of jitter used to show the point density
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create SHAP summary plot >>> gbm.shap_summary_plot(test)
-
staged_predict_proba
(test_data)[source]¶ Predict class probabilities at each stage of an H2O Model (only GBM models).
The output structure is analogous to the output of function predict_leaf_node_assignment. For each tree t and class c there will be a column Tt.Cc (eg. T3.C1 for tree 3 and class 1). The value will be the corresponding predicted probability of this class by combining the raw contributions of trees T1.Cc,..,TtCc. Binomial models build the trees just for the first class and values in columns Tx.C1 thus correspond to the the probability p0.
- Parameters
test_data (H2OFrame) – Data on which to make predictions.
- Returns
A new H2OFrame of staged predictions.
-
property
start_time
¶ Timestamp (milliseconds since 1970) when the model training was started.
-
std_coef_plot
(num_of_features=None, server=False, save_plot_path=None)[source]¶ Plot a model’s standardized coefficient magnitudes.
- Parameters
num_of_features – the number of features shown in the plot.
server – if true set server settings to matplotlib and show the graph
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
-
property
type
¶ The type of model built:
"classifier"
or"regressor"
or"unsupervised"
-
update_tree_weights
(frame, weights_column)[source]¶ Re-calculates tree-node weights based on provided dataset. Modifying node weights will affect how contribution predictions (Shapley values) are calculated. This can be used to explain the model on a curated sub-population of the training dataset.
- Parameters
frame – frame that will be used to re-populate trees with new observations and to collect per-node weights
weights_column – name of the weight column (can be different from training weights)
-
varimp
(use_pandas=False)[source]¶ Pretty print the variable importances, or return them in a list.
- Parameters
use_pandas (bool) – If True, then the variable importances will be returned as a pandas data frame.
- Returns
A list or Pandas DataFrame.
-
varimp_plot
(num_of_features=None, server=False, save_plot_path=None)[source]¶ Plot the variable importance for a trained model.
- Parameters
num_of_features – the number of features shown in the plot (default is 10 or all if less than 10).
server – if true set server settings to matplotlib and do not show the graph
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
-
weights
(matrix_id=0)[source]¶ Return the frame for the respective weight matrix.
- Parameters
matrix_id – an integer, ranging from 0 to number of layers, that specifies the weight matrix to return.
- Returns
an H2OFrame which represents the weight matrix identified by matrix_id
-
property
xvals
¶ Return a list of the cross-validated models.
- Returns
A list of models.
-
property
-
class
h2o.model.
MetricsBase
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
A parent class to house common metrics available for the various Metrics types.
The methods here are available across different model categories.
-
aic
()[source]¶ The AIC for this set of metrics.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.aic()
-
auc
()[source]¶ The AUC for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.auc()
-
aucpr
()[source]¶ The area under the precision recall curve.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.aucpr()
-
gini
()[source]¶ Gini coefficient.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.gini()
-
logloss
()[source]¶ Log loss.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.logloss()
-
mae
()[source]¶ The MAE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "cylinders" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(distribution = "poisson", ... seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.mae()
-
classmethod
make
(kvs)[source]¶ Factory method to instantiate a MetricsBase object from the list of key-value pairs.
-
mean_per_class_error
()[source]¶ The mean per class error.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.mean_per_class_error()
-
mean_residual_deviance
()[source]¶ The mean residual deviance for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> airlines= h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/airlines/AirlinesTest.csv.zip") >>> air_gbm = H2OGradientBoostingEstimator() >>> air_gbm.train(x=list(range(9)), ... y=9, ... training_frame=airlines, ... validation_frame=airlines) >>> air_gbm.mean_residual_deviance(train=True,valid=False,xval=False)
-
mse
()[source]¶ The MSE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.mse()
-
nobs
()[source]¶ The number of observations.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> perf = cars_gbm.model_performance() >>> perf.nobs()
-
null_degrees_of_freedom
()[source]¶ The null DoF if the model has residual deviance, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.null_degrees_of_freedom()
-
null_deviance
()[source]¶ The null deviance if the model has residual deviance, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.null_deviance()
-
r2
()[source]¶ The R squared coefficient.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.r2()
-
residual_degrees_of_freedom
()[source]¶ The residual DoF if the model has residual deviance, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.residual_degrees_of_freedom()
-
residual_deviance
()[source]¶ The residual deviance if the model has it, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.residual_deviance()
-
rmse
()[source]¶ The RMSE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.rmse()
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rmsle
()[source]¶ The RMSLE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "cylinders" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(distribution = "poisson", ... seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.rmsle()
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show
()[source]¶ Display a short summary of the metrics.
- Examples
>>> from from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.show()
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-
class
h2o.model.
H2OBinomialModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
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F0point5
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the F0.5 for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the F0.5 value for the training data.
valid (bool) – If True, return the F0.5 value for the validation data.
xval (bool) – If True, return the F0.5 value for each of the cross-validated splits.
- Returns
The F0.5 values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> F0point5 = gbm.F0point5() # <- Default: return training metric value >>> F0point5 = gbm.F0point5(train=True, valid=True, xval=True)
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F1
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the F1 value for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the F1 value for the training data.
valid (bool) – If True, return the F1 value for the validation data.
xval (bool) – If True, return the F1 value for each of the cross-validated splits.
- Returns
The F1 values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.F1()# <- Default: return training metric value >>> gbm.F1(train=True, valid=True, xval=True)
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F2
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the F2 for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the F2 value for the training data.
valid (bool) – If True, return the F2 value for the validation data.
xval (bool) – If True, return the F2 value for each of the cross-validated splits.
- Returns
The F2 values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.F2() # <- Default: return training metric value >>> gbm.F2(train=True, valid=True, xval=True)
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accuracy
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the accuracy for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the accuracy value for the training data.
valid (bool) – If True, return the accuracy value for the validation data.
xval (bool) – If True, return the accuracy value for each of the cross-validated splits.
- Returns
The accuracy values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.accuracy() # <- Default: return training metric value >>> gbm.accuracy(train=True, valid=True, xval=True)
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confusion_matrix
(metrics=None, thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the confusion matrix for the specified metrics/thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”
- Parameters
metrics – A string (or list of strings) among metrics listed in
H2OBinomialModelMetrics.maximizing_metrics
. Defaults to ‘f1’.thresholds – A value (or list of values) between 0 and 1. If None, then the thresholds maximizing each provided metric will be used.
train (bool) – If True, return the confusion matrix value for the training data.
valid (bool) – If True, return the confusion matrix value for the validation data.
xval (bool) – If True, return the confusion matrix value for each of the cross-validated splits.
- Returns
The confusion matrix values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.confusion_matrix() # <- Default: return training metric value >>> gbm.confusion_matrix(train=True, valid=True, xval=True)
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error
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the error for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold minimizing the error will be used.
train (bool) – If True, return the error value for the training data.
valid (bool) – If True, return the error value for the validation data.
xval (bool) – If True, return the error value for each of the cross-validated splits.
- Returns
The error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.error() # <- Default: return training metric >>> gbm.error(train=True, valid=True, xval=True)
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fallout
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the fallout for a set of thresholds (aka False Positive Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the fallout value for the training data.
valid (bool) – If True, return the fallout value for the validation data.
xval (bool) – If True, return the fallout value for each of the cross-validated splits.
- Returns
The fallout values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.fallout() # <- Default: return training metric >>> gbm.fallout(train=True, valid=True, xval=True)
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find_idx_by_threshold
(threshold, train=False, valid=False, xval=False)[source]¶ Retrieve the index in this metric’s threshold list at which the given threshold is located.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
threshold (float) – Threshold value to search for in the threshold list.
train (bool) – If True, return the find idx by threshold value for the training data.
valid (bool) – If True, return the find idx by threshold value for the validation data.
xval (bool) – If True, return the find idx by threshold value for each of the cross-validated splits.
- Returns
The find idx by threshold values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", ... "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> idx_threshold = gbm.find_idx_by_threshold(threshold=0.39438, ... train=True) >>> idx_threshold
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find_threshold_by_max_metric
(metric, train=False, valid=False, xval=False)[source]¶ If all are False (default), then return the training metric value.
If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
metric (str) – A metric among the metrics listed in
H2OBinomialModelMetrics.maximizing_metrics
.train (bool) – If True, return the find threshold by max metric value for the training data.
valid (bool) – If True, return the find threshold by max metric value for the validation data.
xval (bool) – If True, return the find threshold by max metric value for each of the cross-validated splits.
- Returns
The find threshold by max metric values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", ... "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> max_metric = gbm.find_threshold_by_max_metric(metric="f2", ... train=True) >>> max_metric
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fnr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the False Negative Rates for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the FNR value for the training data.
valid (bool) – If True, return the FNR value for the validation data.
xval (bool) – If True, return the FNR value for each of the cross-validated splits.
- Returns
The FNR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.fnr() # <- Default: return training metric >>> gbm.fnr(train=True, valid=True, xval=True)
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fpr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the False Positive Rates for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the FPR value for the training data.
valid (bool) – If True, return the FPR value for the validation data.
xval (bool) – If True, return the FPR value for each of the cross-validated splits.
- Returns
The FPR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.fpr() # <- Default: return training metric >>> gbm.fpr(train=True, valid=True, xval=True)
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gains_lift
(train=False, valid=False, xval=False)[source]¶ Get the Gains/Lift table for the specified metrics.
If all are False (default), then return the training metric Gains/Lift table. If more than one options is set to True, then return a dictionary of metrics where t he keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the gains lift value for the training data.
valid (bool) – If True, return the gains lift value for the validation data.
xval (bool) – If True, return the gains lift value for each of the cross-validated splits.
- Returns
The gains lift values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.gains_lift() # <- Default: return training metric Gain/Lift table >>> gbm.gains_lift(train=True, valid=True, xval=True)
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kolmogorov_smirnov
()[source]¶ Retrieves a Kolmogorov-Smirnov metric for given binomial model. The number returned is in range between 0 and 1. K-S metric represents the degree of separation between the positive (1) and negative (0) cumulative distribution functions. Detailed metrics per each group are to be found in the gains-lift table.
- Returns
Kolmogorov-Smirnov metric, a number between 0 and 1
- Examples
>>> from h2o.estimators import H2OGradientBoostingEstimator >>> airlines = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/testng/airlines_train.csv") >>> model = H2OGradientBoostingEstimator(ntrees=1, ... gainslift_bins=20) >>> model.train(x=["Origin", "Distance"], ... y="IsDepDelayed", ... training_frame=airlines) >>> model.kolmogorov_smirnov()
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max_per_class_error
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the max per class error for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold minimizing the error will be used.
train (bool) – If True, return the max per class error value for the training data.
valid (bool) – If True, return the max per class error value for the validation data.
xval (bool) – If True, return the max per class error value for each of the cross-validated splits.
- Returns
The max per class error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.max_per_class_error() # <- Default: return training metric value >>> gbm.max_per_class_error(train=True, valid=True, xval=True)
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mcc
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the MCC for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the MCC value for the training data.
valid (bool) – If True, return the MCC value for the validation data.
xval (bool) – If True, return the MCC value for each of the cross-validated splits.
- Returns
The MCC values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.mcc() # <- Default: return training metric value >>> gbm.mcc(train=True, valid=True, xval=True)
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mean_per_class_error
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the mean per class error for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold minimizing the error will be used.
train (bool) – If True, return the mean per class error value for the training data.
valid (bool) – If True, return the mean per class error value for the validation data.
xval (bool) – If True, return the mean per class error value for each of the cross-validated splits.
- Returns
The mean per class error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.mean_per_class_error() # <- Default: return training metric >>> gbm.mean_per_class_error(train=True, valid=True, xval=True)
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metric
(metric, thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the metric value for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
metric (str) – name of the metric to retrieve.
thresholds – If None, then the threshold maximizing the metric will be used (or minimizing it if the metric is an error).
train (bool) – If True, return the metric value for the training data.
valid (bool) – If True, return the metric value for the validation data.
xval (bool) – If True, return the metric value for each of the cross-validated splits.
- Returns
The metric values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] # thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]) >>> thresholds = [0.01,0.5,0.99] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) # allowable metrics are absolute_mcc, accuracy, precision, # f0point5, f1, f2, mean_per_class_accuracy, min_per_class_accuracy, # tns, fns, fps, tps, tnr, fnr, fpr, tpr, recall, sensitivity, # missrate, fallout, specificity >>> gbm.metric(metric='tpr', thresholds=thresholds)
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missrate
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the miss rate for a set of thresholds (aka False Negative Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the miss rate value for the training data.
valid (bool) – If True, return the miss rate value for the validation data.
xval (bool) – If True, return the miss rate value for each of the cross-validated splits.
- Returns
The miss rate values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.missrate() # <- Default: return training metric >>> gbm.missrate(train=True, valid=True, xval=True)
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plot
(timestep='AUTO', metric='AUTO', server=False, save_plot_path=None)[source]¶ Plot training set (and validation set if available) scoring history for an H2OBinomialModel.
The timestep and metric arguments are restricted to what is available in its scoring history.
- Parameters
timestep (str) – A unit of measurement for the x-axis.
metric (str) – A unit of measurement for the y-axis.
server (bool) – if True, then generate the image inline (using matplotlib’s “Agg” backend)
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
- Examples
>>> from h2o.estimators import H2OGeneralizedLinearEstimator >>> benign = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/logreg/benign.csv") >>> response = 3 >>> predictors = [0, 1, 2, 4, 5, 6, 7, 8, 9, 10] >>> model = H2OGeneralizedLinearEstimator(family="binomial") >>> model.train(x=predictors, y=response, training_frame=benign) >>> model.plot(timestep="AUTO", metric="objective", server=False)
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precision
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the precision for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the precision value for the training data.
valid (bool) – If True, return the precision value for the validation data.
xval (bool) – If True, return the precision value for each of the cross-validated splits.
- Returns
The precision values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.precision() # <- Default: return training metric value >>> gbm.precision(train=True, valid=True, xval=True)
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recall
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the recall for a set of thresholds (aka True Positive Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the recall value for the training data.
valid (bool) – If True, return the recall value for the validation data.
xval (bool) – If True, return the recall value for each of the cross-validated splits.
- Returns
The recall values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.recall() # <- Default: return training metric >>> gbm.recall(train=True, valid=True, xval=True)
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roc
(train=False, valid=False, xval=False)[source]¶ Return the coordinates of the ROC curve for a given set of data.
The coordinates are two-tuples containing the false positive rates as a list and true positive rates as a list. If all are False (default), then return is the training data. If more than one ROC curve is requested, the data is returned as a dictionary of two-tuples.
- Parameters
train (bool) – If True, return the ROC value for the training data.
valid (bool) – If True, return the ROC value for the validation data.
xval (bool) – If True, return the ROC value for each of the cross-validated splits.
- Returns
The ROC values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.roc() # <- Default: return training data >>> gbm.roc(train=True, valid=True, xval=True)
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sensitivity
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the sensitivity for a set of thresholds (aka True Positive Rate or Recall).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the sensitivity value for the training data.
valid (bool) – If True, return the sensitivity value for the validation data.
xval (bool) – If True, return the sensitivity value for each of the cross-validated splits.
- Returns
The sensitivity values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.sensitivity() # <- Default: return training metric >>> gbm.sensitivity(train=True, valid=True, xval=True)
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specificity
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the specificity for a set of thresholds (aka True Negative Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the specificity value for the training data.
valid (bool) – If True, return the specificity value for the validation data.
xval (bool) – If True, return the specificity value for each of the cross-validated splits.
- Returns
The specificity values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.specificity() # <- Default: return training metric >>> gbm.specificity(train=True, valid=True, xval=True)
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tnr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the True Negative Rate for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the TNR value for the training data.
valid (bool) – If True, return the TNR value for the validation data.
xval (bool) – If True, return the TNR value for each of the cross-validated splits.
- Returns
The TNR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.tnr() # <- Default: return training metric >>> gbm.tnr(train=True, valid=True, xval=True)
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tpr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the True Positive Rate for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the TPR value for the training data.
valid (bool) – If True, return the TPR value for the validation data.
xval (bool) – If True, return the TPR value for each of the cross-validated splits.
- Returns
The TPR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.tpr() # <- Default: return training metric >>> gbm.tpr(train=True, valid=True, xval=True)
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-
class
h2o.model.
H2OMultinomialModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
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confusion_matrix
(data)[source]¶ Returns a confusion matrix based of H2O’s default prediction threshold for a dataset.
- Parameters
data (H2OFrame) – the frame with the prediction results for which the confusion matrix should be extracted.
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> confusion_matrix = gbm.confusion_matrix(train) >>> confusion_matrix
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hit_ratio_table
(train=False, valid=False, xval=False)[source]¶ Retrieve the Hit Ratios.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train – If train is True, then return the hit ratio value for the training data.
valid – If valid is True, then return the hit ratio value for the validation data.
xval – If xval is True, then return the hit ratio value for the cross validation data.
- Returns
The hit ratio for this regression model.
- Example
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> hit_ratio_table = gbm.hit_ratio_table() # <- Default: return training metrics >>> hit_ratio_table >>> hit_ratio_table1 = gbm.hit_ratio_table(train=True, ... valid=True, ... xval=True) >>> hit_ratio_table1
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mean_per_class_error
(train=False, valid=False, xval=False)[source]¶ Retrieve the mean per class error across all classes
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the mean_per_class_error value for the training data.
valid (bool) – If True, return the mean_per_class_error value for the validation data.
xval (bool) – If True, return the mean_per_class_error value for each of the cross-validated splits.
- Returns
The mean_per_class_error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> mean_per_class_error = gbm.mean_per_class_error() # <- Default: return training metric >>> mean_per_class_error >>> mean_per_class_error1 = gbm.mean_per_class_error(train=True, ... valid=True, ... xval=True) >>> mean_per_class_error1
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multinomial_auc_table
(train=False, valid=False, xval=False)[source]¶ Retrieve the multinomial AUC table.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the multinomial_auc_table for the training data.
valid (bool) – If True, return the multinomial_auc_table for the validation data.
xval (bool) – If True, return the multinomial_auc_table for each of the cross-validated splits.
- Returns
The multinomial_auc_table values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> multinomial_auc_table = gbm.multinomial_auc_table() # <- Default: return training metric >>> multinomial_auc_table >>> multinomial_auc_table1 = gbm.multinomial_auc_table(train=True, ... valid=True, ... xval=True) >>> multinomial_auc_table1
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multinomial_aucpr_table
(train=False, valid=False, xval=False)[source]¶ Retrieve the multinomial PR AUC table.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the amultinomial_aucpr_table for the training data.
valid (bool) – If True, return the multinomial_aucpr_table for the validation data.
xval (bool) – If True, return the multinomial_aucpr_table for each of the cross-validated splits.
- Returns
The average_pairwise_auc values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> multinomial_aucpr_table = gbm.multinomial_aucpr_table() # <- Default: return training metric >>> multinomial_aucpr_table >>> multinomial_aucpr_table1 = gbm.multinomial_aucpr_table(train=True, ... valid=True, ... xval=True) >>> multinomial_aucpr_table1
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plot
(timestep='AUTO', metric='AUTO', save_plot_path=None, **kwargs)[source]¶ Plots training set (and validation set if available) scoring history for an H2OMultinomialModel. The timestep and metric arguments are restricted to what is available in its scoring history.
- Parameters
timestep – A unit of measurement for the x-axis. This can be AUTO, duration, or number_of_trees.
metric – A unit of measurement for the y-axis. This can be AUTO, logloss, classification_error, or rmse.
- Returns
Object that contains the resulting scoring history plot (can be accessed using result.figure()).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> gbm.plot(metric="AUTO", timestep="AUTO")
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-
class
h2o.model.
H2ORegressionModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
-
plot
(timestep='AUTO', metric='AUTO', save_plot_path=None, **kwargs)[source]¶ Plots training set (and validation set if available) scoring history for an H2ORegressionModel. The timestep and metric arguments are restricted to what is available in its scoring history.
- Parameters
timestep – A unit of measurement for the x-axis.
metric – A unit of measurement for the y-axis.
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
Object that contains the resulting scoring history plot (can be accessed using result.figure()).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy" >>> distribution = "gaussian" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> gbm.plot(timestep="AUTO", metric="AUTO",)
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residual_analysis_plot
(frame, figsize=(16, 9), save_plot_path=None)¶ Residual Analysis
Do Residual Analysis and plot the fitted values vs residuals on a test dataset. Ideally, residuals should be randomly distributed. Patterns in this plot can indicate potential problems with the model selection, e.g., using simpler model than necessary, not accounting for heteroscedasticity, autocorrelation, etc. If you notice “striped” lines of residuals, that is just an indication that your response variable was integer valued instead of real valued.
- Parameters
model – H2OModel
frame – H2OFrame
figsize – figure size; passed directly to matplotlib
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create the residual analysis plot >>> gbm.residual_analysis_plot(test)
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-
class
h2o.model.
H2OOrdinalModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
-
confusion_matrix
(data)[source]¶ Returns a confusion matrix based of H2O’s default prediction threshold for a dataset.
- Parameters
data (H2OFrame) – the frame with the prediction results for which the confusion matrix should be extracted.
-
hit_ratio_table
(train=False, valid=False, xval=False)[source]¶ Retrieve the Hit Ratios.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train – If train is True, then return the hit ratio value for the training data.
valid – If valid is True, then return the hit ratio value for the validation data.
xval – If xval is True, then return the hit ratio value for the cross validation data.
- Returns
The hit ratio for this regression model.
-
mean_per_class_error
(train=False, valid=False, xval=False)[source]¶ Retrieve the mean per class error across all classes
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the mean_per_class_error value for the training data.
valid (bool) – If True, return the mean_per_class_error value for the validation data.
xval (bool) – If True, return the mean_per_class_error value for each of the cross-validated splits.
- Returns
The mean_per_class_error values for the specified key(s).
-
plot
(timestep='AUTO', metric='AUTO', save_plot_path=None, **kwargs)[source]¶ Plots training set (and validation set if available) scoring history for an H2OOrdinalModel. The timestep and metric arguments are restricted to what is available in its scoring history.
- Parameters
timestep – A unit of measurement for the x-axis.
metric – A unit of measurement for the y-axis.
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
Object that contains the resulting scoring history plot (can be accessed using result.figure()).
-
-
class
h2o.model.
H2OClusteringModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
For examples: from h2o.estimators.kmeans import H2OKMeansEstimator
-
betweenss
(train=False, valid=False, xval=False)[source]¶ Get the between cluster sum of squares.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the between cluster sum of squares value for the training data.
valid (bool) – If True, return the between cluster sum of squares value for the validation data.
xval (bool) – If True, return the between cluster sum of squares value for each of the cross-validated splits.
- Returns
The between cluster sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> betweenss = km.betweenss() # <- Default: return training metrics >>> betweenss >>> betweenss3 = km.betweenss(train=False, ... valid=False, ... xval=True) >>> betweenss3
-
centers
()[source]¶ The centers for the KMeans model.
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.centers()
-
centers_std
()[source]¶ The standardized centers for the kmeans model.
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.centers_std()
-
centroid_stats
(train=False, valid=False, xval=False)[source]¶ Get the centroid statistics for each cluster.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the centroid statistic for the training data.
valid (bool) – If True, return the centroid statistic for the validation data.
xval (bool) – If True, return the centroid statistic for each of the cross-validated splits.
- Returns
The centroid statistics for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> centroid_stats = km.centroid_stats() # <- Default: return training metrics >>> centroid_stats >>> centroid_stats1 = km.centroid_stats(train=True, ... valid=False, ... xval=False) >>> centroid_stats1
-
num_iterations
()[source]¶ Get the number of iterations it took to converge or reach max iterations.
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.num_iterations()
-
size
(train=False, valid=False, xval=False)[source]¶ Get the sizes of each cluster.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the cluster sizes for the training data.
valid (bool) – If True, return the cluster sizes for the validation data.
xval (bool) – If True, return the cluster sizes for each of the cross-validated splits.
- Returns
The cluster sizes for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> size = km.size() # <- Default: return training metrics >>> size >>> size1 = km.size(train=False, ... valid=False, ... xval=True) >>> size1
-
tot_withinss
(train=False, valid=False, xval=False)[source]¶ Get the total within cluster sum of squares.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the total within cluster sum of squares value for the training data.
valid (bool) – If True, return the total within cluster sum of squares value for the validation data.
xval (bool) – If True, return the total within cluster sum of squares value for each of the cross-validated splits.
- Returns
The total within cluster sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> tot_withinss = km.tot_withinss() # <- Default: return training metrics >>> tot_withinss >>> tot_withinss2 = km.tot_withinss(train=True, ... valid=False, ... xval=True) >>> tot_withinss2
-
totss
(train=False, valid=False, xval=False)[source]¶ Get the total sum of squares.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the total sum of squares value for the training data.
valid (bool) – If True, return the total sum of squares value for the validation data.
xval (bool) – If True, return the total sum of squares value for each of the cross-validated splits.
- Returns
The total sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> totss = km.totss() # <- Default: return training metrics >>> totss
-
withinss
(train=False, valid=False, xval=False)[source]¶ Get the within cluster sum of squares for each cluster.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the total sum of squares value for the training data.
valid (bool) – If True, return the total sum of squares value for the validation data.
xval (bool) – If True, return the total sum of squares value for each of the cross-validated splits.
- Returns
The total sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> withinss = km.withinss() # <- Default: return training metrics >>> withinss >>> withinss2 = km.withinss(train=True, ... valid=True, ... xval=True) >>> withinss2
-
-
class
h2o.model.
H2ODimReductionModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
Dimension reduction model, such as PCA or GLRM.
-
num_iterations
()[source]¶ Get the number of iterations that it took to converge or reach max iterations.
-
proj_archetypes
(test_data, reverse_transform=False)[source]¶ Convert archetypes of the model into original feature space.
- Parameters
test_data (H2OFrame) – The dataset upon which the model was trained.
reverse_transform (bool) – Whether the transformation of the training data during model-building should be reversed on the projected archetypes.
- Returns
model archetypes projected back into the original training data’s feature space.
-
reconstruct
(test_data, reverse_transform=False)[source]¶ Reconstruct the training data from the model and impute all missing values.
- Parameters
test_data (H2OFrame) – The dataset upon which the model was trained.
reverse_transform (bool) – Whether the transformation of the training data during model-building should be reversed on the reconstructed frame.
- Returns
the approximate reconstruction of the training data.
-
screeplot
(type='barplot', server=False, save_plot_path=None)[source]¶ Produce the scree plot.
Library
matplotlib
is required for this function.- Parameters
type (str) – either
"barplot"
or"lines"
.server (bool) – if true set server settings to matplotlib and do not show the graph
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
Object that contains the resulting scree plot (can be accessed like result.figure()).
-
-
class
h2o.model.
H2OAutoEncoderModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
-
anomaly
(test_data, per_feature=False)[source]¶ Obtain the reconstruction error for the input test_data.
- Parameters
test_data (H2OFrame) – The dataset upon which the reconstruction error is computed.
per_feature (bool) – Whether to return the square reconstruction error per feature. Otherwise, return the mean square error.
- Returns
the reconstruction error.
- Examples
>>> from h2o.estimators.deeplearning import H2OAutoEncoderEstimator >>> train = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/bigdata/laptop/mnist/train.csv.gz") >>> test = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/bigdata/laptop/mnist/test.csv.gz") >>> predictors = list(range(0,784)) >>> resp = 784 >>> train = train[predictors] >>> test = test[predictors] >>> ae_model = H2OAutoEncoderEstimator(activation="Tanh", ... hidden=[2], ... l1=1e-5, ... ignore_const_cols=False, ... epochs=1) >>> ae_model.train(x=predictors,training_frame=train) >>> test_rec_error = ae_model.anomaly(test) >>> test_rec_error >>> test_rec_error_features = ae_model.anomaly(test, per_feature=True) >>> test_rec_error_features
-
-
class
h2o.model.
ConfusionMatrix
(cm, domains=None, table_header=None)[source]¶ Bases:
object
-
ROUND
= 4¶
-
-
class
h2o.model.
H2OModelFuture
(job, x)[source]¶ Bases:
object
A class representing a future H2O model (a model that may, or may not, be in the process of being built).
-
class
h2o.model.
H2OSegmentModels
(segment_models_id=None)[source]¶ Bases:
h2o.base.Keyed
Collection of H2O Models built for each input segment.
- Parameters
segment_models_id – identifier of this collection of Segment Models
- Example
>>> segment_models = h2o.model.segment_models.H2OSegmentModels(segment_models_id="my_sm_id") >>> segment_models.as_frame()
-
as_frame
()[source]¶ Converts this collection of models to a tabular representation.
- Returns
An H2OFrame, first columns identify the input segments, rest of the columns describe the built models.
-
property
key
¶ - Returns
the unique key representing the object on the backend
ModelBase
¶
-
class
h2o.model.model_base.
ModelBase
[source]¶ Bases:
h2o.model.model_base.ModelBase
Base class for all models.
-
property
actual_params
¶ Dictionary of actual parameters of the model.
-
aic
(train=False, valid=False, xval=False)[source]¶ Get the AIC (Akaike Information Criterium).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the AIC value for the training data.
valid (bool) – If valid is True, then return the AIC value for the validation data.
xval (bool) – If xval is True, then return the AIC value for the validation data.
- Returns
The AIC.
-
auc
(train=False, valid=False, xval=False)[source]¶ Get the AUC (Area Under Curve).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the AUC value for the training data.
valid (bool) – If valid is True, then return the AUC value for the validation data.
xval (bool) – If xval is True, then return the AUC value for the validation data.
- Returns
The AUC.
-
aucpr
(train=False, valid=False, xval=False)[source]¶ Get the aucPR (Area Under PRECISION RECALL Curve).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the aucpr value for the training data.
valid (bool) – If valid is True, then return the aucpr value for the validation data.
xval (bool) – If xval is True, then return the aucpr value for the validation data.
- Returns
The aucpr.
-
biases
(vector_id=0)[source]¶ Return the frame for the respective bias vector.
- Param
vector_id: an integer, ranging from 0 to number of layers, that specifies the bias vector to return.
- Returns
an H2OFrame which represents the bias vector identified by vector_id
-
coef
()[source]¶ Return the coefficients which can be applied to the non-standardized data.
Note: standardize = True by default, if set to False then coef() return the coefficients which are fit directly.
-
coef_norm
()[source]¶ Return coefficients fitted on the standardized data (requires standardize = True, which is on by default).
These coefficients can be used to evaluate variable importance.
-
cross_validation_fold_assignment
()[source]¶ Obtain the cross-validation fold assignment for all rows in the training data.
- Returns
H2OFrame
-
cross_validation_holdout_predictions
()[source]¶ Obtain the (out-of-sample) holdout predictions of all cross-validation models on the training data.
This is equivalent to summing up all H2OFrames returned by cross_validation_predictions.
- Returns
H2OFrame
-
cross_validation_metrics_summary
()[source]¶ Retrieve Cross-Validation Metrics Summary.
- Returns
The cross-validation metrics summary as an H2OTwoDimTable
-
cross_validation_models
()[source]¶ Obtain a list of cross-validation models.
- Returns
list of H2OModel objects.
-
cross_validation_predictions
()[source]¶ Obtain the (out-of-sample) holdout predictions of all cross-validation models on their holdout data.
Note that the predictions are expanded to the full number of rows of the training data, with 0 fill-in.
- Returns
list of H2OFrame objects.
-
deepfeatures
(test_data, layer)[source]¶ Return hidden layer details.
- Parameters
test_data – Data to create a feature space on
layer – 0 index hidden layer
-
property
default_params
¶ Dictionary of the default parameters of the model.
-
download_model
(path='', filename=None)[source]¶ Download an H2O Model object to disk.
- Parameters
path – a path to the directory where the model should be saved.
filename – a filename for the saved model
- Returns
the path of the downloaded model
-
download_mojo
(path='.', get_genmodel_jar=False, genmodel_name='')[source]¶ Download the model in MOJO format.
- Parameters
path – the path where MOJO file should be saved.
get_genmodel_jar – if True, then also download h2o-genmodel.jar and store it in folder
path
.genmodel_name – Custom name of genmodel jar
- Returns
name of the MOJO file written.
-
download_pojo
(path='', get_genmodel_jar=False, genmodel_name='')[source]¶ Download the POJO for this model to the directory specified by path.
If path is an empty string, then dump the output to screen.
- Parameters
path – An absolute path to the directory where POJO should be saved.
get_genmodel_jar – if True, then also download h2o-genmodel.jar and store it in folder
path
.genmodel_name – Custom name of genmodel jar
- Returns
name of the POJO file written.
-
property
end_time
¶ Timestamp (milliseconds since 1970) when the model training was ended.
-
explain
(frame, columns=None, top_n_features=5, include_explanations='ALL', exclude_explanations=[], plot_overrides={}, figsize=(16, 9), render=True, qualitative_colormap='Dark2', sequential_colormap='RdYlBu_r')¶ Generate model explanations on frame data set.
The H2O Explainability Interface is a convenient wrapper to a number of explainabilty methods and visualizations in H2O. The function can be applied to a single model or group of models and returns an object containing explanations, such as a partial dependence plot or a variable importance plot. Most of the explanations are visual (plots). These plots can also be created by individual utility functions/methods as well.
- Parameters
models – a list of H2O models, an H2O AutoML instance, or an H2OFrame with a ‘model_id’ column (e.g. H2OAutoML leaderboard)
frame – H2OFrame
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable).
include_explanations – if specified, return only the specified model explanations (Mutually exclusive with exclude_explanations)
exclude_explanations – exclude specified model explanations
plot_overrides – overrides for individual model explanations
figsize – figure size; passed directly to matplotlib
render – if True, render the model explanations; otherwise model explanations are just returned
- Returns
H2OExplanation containing the model explanations including headers and descriptions
- Examples
>>> import h2o >>> from h2o.automl import H2OAutoML >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train an H2OAutoML >>> aml = H2OAutoML(max_models=10) >>> aml.train(y=response, training_frame=train) >>> >>> # Create the H2OAutoML explanation >>> aml.explain(test) >>> >>> # Create the leader model explanation >>> aml.leader.explain(test)
-
explain_row
(frame, row_index, columns=None, top_n_features=5, include_explanations='ALL', exclude_explanations=[], plot_overrides={}, qualitative_colormap='Dark2', figsize=(16, 9), render=True)¶ Generate model explanations on frame data set for a given instance.
Explain the behavior of a model or group of models with respect to a single row of data. The function returns an object containing explanations, such as a partial dependence plot or a variable importance plot. Most of the explanations are visual (plots). These plots can also be created by individual utility functions/methods as well.
- Parameters
models – H2OAutoML object, supervised H2O model, or list of supervised H2O models
frame – H2OFrame
row_index – row index of the instance to inspect
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable).
include_explanations – if specified, return only the specified model explanations (Mutually exclusive with exclude_explanations)
exclude_explanations – exclude specified model explanations
plot_overrides – overrides for individual model explanations
qualitative_colormap – a colormap name
figsize – figure size; passed directly to matplotlib
render – if True, render the model explanations; otherwise model explanations are just returned
- Returns
H2OExplanation containing the model explanations including headers and descriptions
- Examples
>>> import h2o >>> from h2o.automl import H2OAutoML >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train an H2OAutoML >>> aml = H2OAutoML(max_models=10) >>> aml.train(y=response, training_frame=train) >>> >>> # Create the H2OAutoML explanation >>> aml.explain_row(test, row_index=0) >>> >>> # Create the leader model explanation >>> aml.leader.explain_row(test, row_index=0)
-
feature_frequencies
(test_data)[source]¶ Retrieve the number of occurrences of each feature for given observations on their respective paths in a tree ensemble model. Available for GBM, Random Forest and Isolation Forest models.
- Parameters
test_data (H2OFrame) – Data on which to calculate feature frequencies.
- Returns
A new H2OFrame made of feature contributions.
-
feature_interaction
(max_interaction_depth=100, max_tree_depth=100, max_deepening=-1, path=None)[source]¶ Feature interactions and importance, leaf statistics and split value histograms in a tabular form. Available for XGBoost and GBM.
Metrics: Gain - Total gain of each feature or feature interaction. FScore - Amount of possible splits taken on a feature or feature interaction. wFScore - Amount of possible splits taken on a feature or feature interaction weighed by the probability of the splits to take place. Average wFScore - wFScore divided by FScore. Average Gain - Gain divided by FScore. Expected Gain - Total gain of each feature or feature interaction weighed by the probability to gather the gain. Average Tree Index Average Tree Depth
- Parameters
max_interaction_depth – Upper bound for extracted feature interactions depth. Defaults to 100.
max_tree_depth – Upper bound for tree depth. Defaults to 100.
max_deepening – Upper bound for interaction start deepening (zero deepening => interactions starting at root only). Defaults to -1.
path – (Optional) Path where to save the output in .xlsx format (e.g.
/mypath/file.xlsx
). Please note that Pandas and XlsxWriter need to be installed for using this option. Defaults to None.
- Examples
>>> boston = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/gbm_test/BostonHousing.csv") >>> predictors = boston.columns[:-1] >>> response = "medv" >>> boston['chas'] = boston['chas'].asfactor() >>> train, valid = boston.split_frame(ratios=[.8]) >>> boston_xgb = H2OXGBoostEstimator(seed=1234) >>> boston_xgb.train(y=response, x=predictors, training_frame=train) >>> feature_interactions = boston_xgb.feature_interaction()
-
property
full_parameters
¶ Dictionary of the full specification of all parameters.
-
get_xval_models
(key=None)[source]¶ Return a Model object.
- Parameters
key – If None, return all cross-validated models; otherwise return the model that key points to.
- Returns
A model or list of models.
-
gini
(train=False, valid=False, xval=False)[source]¶ Get the Gini coefficient.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”
- Parameters
train (bool) – If train is True, then return the Gini Coefficient value for the training data.
valid (bool) – If valid is True, then return the Gini Coefficient value for the validation data.
xval (bool) – If xval is True, then return the Gini Coefficient value for the cross validation data.
- Returns
The Gini Coefficient for this binomial model.
-
h
(frame, variables)[source]¶ Calculates Friedman and Popescu’s H statistics, in order to test for the presence of an interaction between specified variables in h2o gbm and xgb models. H varies from 0 to 1. It will have a value of 0 if the model exhibits no interaction between specified variables and a correspondingly larger value for a stronger interaction effect between them. NaN is returned if a computation is spoiled by weak main effects and rounding errors.
See Jerome H. Friedman and Bogdan E. Popescu, 2008, “Predictive learning via rule ensembles”, Ann. Appl. Stat. 2:916-954, http://projecteuclid.org/download/pdfview_1/euclid.aoas/1223908046, s. 8.1.
- Parameters
frame – the frame that current model has been fitted to
variables – variables of the interest
- Returns
H statistic of the variables
- Examples
>>> prostate_train = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/logreg/prostate_train.csv") >>> prostate_train["CAPSULE"] = prostate_train["CAPSULE"].asfactor() >>> gbm_h2o = H2OGradientBoostingEstimator(ntrees=100, learn_rate=0.1, >>> max_depth=5, >>> min_rows=10, >>> distribution="bernoulli") >>> gbm_h2o.train(x=list(range(1,prostate_train.ncol)),y="CAPSULE", training_frame=prostate_train) >>> h = gbm_h2o.h(prostate_train, ['DPROS','DCAPS'])
-
property
have_mojo
¶ True, if export to MOJO is possible
-
property
have_pojo
¶ True, if export to POJO is possible
-
ice_plot
(frame, column, target=None, max_levels=30, figsize=(16, 9), colormap='plasma', save_plot_path=None)¶ Plot Individual Conditional Expectations (ICE) for each decile
Individual conditional expectations (ICE) plot gives a graphical depiction of the marginal effect of a variable on the response. ICE plot is similar to partial dependence plot (PDP), PDP shows the average effect of a feature while ICE plot shows the effect for a single instance. The following plot shows the effect for each decile. In contrast to partial dependence plot, ICE plot can provide more insight especially when there is stronger feature interaction.
- Parameters
model – H2OModel
frame – H2OFrame
column – string containing column name
target – (only for multinomial classification) for what target should the plot be done
max_levels – maximum number of factor levels to show
figsize – figure size; passed directly to matplotlib
colormap – colormap name
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create the individual conditional expectations plot >>> gbm.ice_plot(test, column="alcohol")
-
property
key
¶ - Returns
the unique key representing the object on the backend
-
learning_curve_plot
(metric='AUTO', cv_ribbon=None, cv_lines=None, figsize=(16, 9), colormap=None, save_plot_path=None)¶ Learning curve
Create learning curve plot for an H2O Model. Learning curves show error metric dependence on learning progress, e.g., RMSE vs number of trees trained so far in GBM. There can be up to 4 curves showing Training, Validation, Training on CV Models, and Cross-validation error.
- Parameters
model – an H2O model
metric – a stopping metric
cv_ribbon – if True, plot the CV mean as a and CV standard deviation as a ribbon around the mean, if None, it will attempt to automatically determine if this is suitable visualisation
cv_lines – if True, plot scoring history for individual CV models, if None, it will attempt to automatically determine if this is suitable visualisation
figsize – figure size; passed directly to matplotlib
colormap – colormap to use
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create the learning curve plot >>> gbm.learning_curve_plot()
-
logloss
(train=False, valid=False, xval=False)[source]¶ Get the Log Loss.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the log loss value for the training data.
valid (bool) – If valid is True, then return the log loss value for the validation data.
xval (bool) – If xval is True, then return the log loss value for the cross validation data.
- Returns
The log loss for this regression model.
-
mae
(train=False, valid=False, xval=False)[source]¶ Get the Mean Absolute Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the MAE value for the training data.
valid (bool) – If valid is True, then return the MAE value for the validation data.
xval (bool) – If xval is True, then return the MAE value for the cross validation data.
- Returns
The MAE for this regression model.
-
mean_residual_deviance
(train=False, valid=False, xval=False)[source]¶ Get the Mean Residual Deviances.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the Mean Residual Deviance value for the training data.
valid (bool) – If valid is True, then return the Mean Residual Deviance value for the validation data.
xval (bool) – If xval is True, then return the Mean Residual Deviance value for the cross validation data.
- Returns
The Mean Residual Deviance for this regression model.
-
property
model_id
¶ Model identifier.
-
model_performance
(test_data=None, train=False, valid=False, xval=False, auc_type='none')[source]¶ Generate model metrics for this model on test_data.
- Parameters
test_data (H2OFrame) – Data set for which model metrics shall be computed against. All three of train, valid and xval arguments are ignored if test_data is not None.
train (bool) – Report the training metrics for the model.
valid (bool) – Report the validation metrics for the model.
xval (bool) – Report the cross-validation metrics for the model. If train and valid are True, then it defaults to True.
auc_type (String) – Change default AUC type for multinomial classification AUC/AUCPR calculation when test_data is not None. One of:
"auto"
,"none"
,"macro_ovr"
,"weighted_ovr"
,"macro_ovo"
,"weighted_ovo"
(default:"none"
). If type is “auto” or “none” AUC and AUCPR is not calculated.
- Returns
An object of class H2OModelMetrics.
-
mse
(train=False, valid=False, xval=False)[source]¶ Get the Mean Square Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the MSE value for the training data.
valid (bool) – If valid is True, then return the MSE value for the validation data.
xval (bool) – If xval is True, then return the MSE value for the cross validation data.
- Returns
The MSE for this regression model.
-
ntrees_actual
()[source]¶ Returns actual number of trees in a tree model. If early stopping enabled, GBM can reset the ntrees value. In this case, the actual ntrees value is less than the original ntrees value a user set before building the model.
Type:
float
-
null_degrees_of_freedom
(train=False, valid=False, xval=False)[source]¶ Retreive the null degress of freedom if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the null dof for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the null dof for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the null dof, or None if it is not present.
-
null_deviance
(train=False, valid=False, xval=False)[source]¶ Retreive the null deviance if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the null deviance for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the null deviance for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the null deviance, or None if it is not present.
-
property
params
¶ Get the parameters and the actual/default values only.
- Returns
A dictionary of parameters used to build this model.
-
partial_plot
(data, cols=None, destination_key=None, nbins=20, weight_column=None, plot=True, plot_stddev=True, figsize=(7, 10), server=False, include_na=False, user_splits=None, col_pairs_2dpdp=None, save_plot_path=None, row_index=None, targets=None)[source]¶ Create partial dependence plot which gives a graphical depiction of the marginal effect of a variable on the response. The effect of a variable is measured in change in the mean response.
- Parameters
data (H2OFrame) – An H2OFrame object used for scoring and constructing the plot.
cols – Feature(s) for which partial dependence will be calculated.
destination_key – An key reference to the created partial dependence tables in H2O.
nbins – Number of bins used. For categorical columns make sure the number of bins exceed the level count. If you enable add_missing_NA, the returned length will be nbin+1.
weight_column – A string denoting which column of data should be used as the weight column.
plot – A boolean specifying whether to plot partial dependence table.
plot_stddev – A boolean specifying whether to add std err to partial dependence plot.
figsize – Dimension/size of the returning plots, adjust to fit your output cells.
server – Specify whether to activate matplotlib “server” mode. In this case, the plots are saved to a file instead of being rendered.
include_na – A boolean specifying whether missing value should be included in the Feature values.
user_splits – a dictionary containing column names as key and user defined split values as value in a list.
col_pairs_2dpdp – list containing pairs of column names for 2D pdp
save_plot_path – Fully qualified name to an image file the resulting plot should be saved to, e.g. ‘/home/user/pdpplot.png’. The ‘png’ postfix might be omitted. If the file already exists, it will be overridden. Plot is only saved if plot = True.
row_index – Row for which partial dependence will be calculated instead of the whole input frame.
targets – Target classes for multiclass model.
- Returns
Plot and list of calculated mean response tables for each feature requested + the resulting plot (can be accessed using result.figure()).
-
pd_plot
(frame, column, row_index=None, target=None, max_levels=30, figsize=(16, 9), colormap='Dark2', save_plot_path=None)¶ Plot partial dependence plot.
Partial dependence plot (PDP) gives a graphical depiction of the marginal effect of a variable on the response. The effect of a variable is measured in change in the mean response. PDP assumes independence between the feature for which is the PDP computed and the rest.
- Parameters
model – H2O Model object
frame – H2OFrame
column – string containing column name
row_index – if None, do partial dependence, if integer, do individual conditional expectation for the row specified by this integer
target – (only for multinomial classification) for what target should the plot be done
max_levels – maximum number of factor levels to show
figsize – figure size; passed directly to matplotlib
colormap – colormap name; used to get just the first color to keep the api and color scheme similar with pd_multi_plot
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create partial dependence plot >>> gbm.pd_plot(test, column="alcohol")
-
permutation_importance
(frame, metric='AUTO', n_samples=10000, n_repeats=1, features=None, seed=-1, use_pandas=False)[source]¶ Get Permutation Variable Importance.
When n_repeats == 1, the result is similar to the one from varimp() method, i.e., it contains the following columns “Relative Importance”, “Scaled Importance”, and “Percentage”.
When n_repeats > 1, the individual columns correspond to the permutation variable importance values from individual runs which corresponds to the “Relative Importance” and also to the distance between the original prediction error and prediction error using a frame with a given feature permuted.
- Parameters
frame – training frame
metric – metric to be used. One of “AUTO”, “AUC”, “MAE”, “MSE”, “RMSE”, “logloss”, “mean_per_class_error”, “PR_AUC”. Defaults to “AUTO”.
n_samples – number of samples to be evaluated. Use -1 to use the whole dataset. Defaults to 10 000.
n_repeats – number of repeated evaluations. Defaults to 1.
features – features to include in the permutation importance. Use None to include all.
seed – seed for the random generator. Use -1 to pick a random seed. Defaults to -1.
use_pandas – set true to return pandas data frame.
- Returns
H2OTwoDimTable or Pandas data frame
-
permutation_importance_plot
(frame, metric='AUTO', n_samples=10000, n_repeats=1, features=None, seed=-1, num_of_features=10, server=False, save_plot_path=None)[source]¶ Plot Permutation Variable Importance. This method plots either a bar plot or if n_repeats > 1 a box plot and returns the variable importance table.
- Parameters
frame – training frame
metric – metric to be used. One of “AUTO”, “AUC”, “MAE”, “MSE”, “RMSE”, “logloss”, “mean_per_class_error”, “PR_AUC”. Defaults to “AUTO”.
n_samples – number of samples to be evaluated. Use -1 to use the whole dataset. Defaults to 10 000.
n_repeats – number of repeated evaluations. Defaults to 1.
features – features to include in the permutation importance. Use None to include all.
seed – seed for the random generator. Use -1 to pick a random seed. Defaults to -1.
num_of_features – number of features to plot. Defaults to 10.
server – if true set server settings to matplotlib and do not show the plot
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains H2OTwoDimTable with variable importance and the resulting figure (can be accessed using result.figure())
-
pr_auc
(train=False, valid=False, xval=False)[source]¶ ModelBase.pr_auc
is deprecated, please useModelBase.aucpr
instead.
-
predict
(test_data, custom_metric=None, custom_metric_func=None)[source]¶ Predict on a dataset.
- Parameters
test_data (H2OFrame) – Data on which to make predictions.
custom_metric – custom evaluation function defined as class reference, the class get uploaded into the cluster
custom_metric_func – custom evaluation function reference, e.g, result of upload_custom_metric
- Returns
A new H2OFrame of predictions.
-
predict_contributions
(test_data, output_format='Original', top_n=None, bottom_n=None, compare_abs=False)[source]¶ Predict feature contributions - SHAP values on an H2O Model (only GBM, XGBoost, DRF models and equivalent imported MOJOs).
Returned H2OFrame has shape (#rows, #features + 1) - there is a feature contribution column for each input feature, the last column is the model bias (same value for each row). The sum of the feature contributions and the bias term is equal to the raw prediction of the model. Raw prediction of tree-based model is the sum of the predictions of the individual trees before the inverse link function is applied to get the actual prediction. For Gaussian distribution the sum of the contributions is equal to the model prediction.
Note: Multinomial classification models are currently not supported.
- Parameters
test_data (H2OFrame) – Data on which to calculate contributions.
output_format (Enum) – Specify how to output feature contributions in XGBoost - XGBoost by default outputs contributions for 1-hot encoded features, specifying a Compact output format will produce a per-feature contribution. One of:
"Original"
,"Compact"
(default:"Original"
).top_n – Return only #top_n highest contributions + bias. If top_n<0 then sort all SHAP values in descending order If top_n<0 && bottom_n<0 then sort all SHAP values in descending order
bottom_n – Return only #bottom_n lowest contributions + bias If top_n and bottom_n are defined together then return array of #top_n + #bottom_n + bias If bottom_n<0 then sort all SHAP values in ascending order If top_n<0 && bottom_n<0 then sort all SHAP values in descending order
compare_abs – True to compare absolute values of contributions
- Returns
A new H2OFrame made of feature contributions.
- Examples
>>> prostate = "http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv" >>> fr = h2o.import_file(prostate) >>> predictors = list(range(2, fr.ncol)) >>> m = H2OGradientBoostingEstimator(ntrees=10, seed=1234) >>> m.train(x=predictors, y=1, training_frame=fr) >>> # Compute SHAP >>> m.predict_contributions(fr) >>> # Compute SHAP and pick the top two highest >>> m.predict_contributions(fr, top_n=2) >>> # Compute SHAP and pick the top two lowest >>> m.predict_contributions(fr, bottom_n=2) >>> # Compute SHAP and pick the top two highest regardless of the sign >>> m.predict_contributions(fr, top_n=2, compare_abs=True) >>> # Compute SHAP and pick top two lowest regardless of the sign >>> m.predict_contributions(fr, bottom_n=2, compare_abs=True) >>> # Compute SHAP values and show them all in descending order >>> m.predict_contributions(fr, top_n=-1) >>> # Compute SHAP and pick the top two highest and top two lowest >>> m.predict_contributions(fr, top_n=2, bottom_n=2)
-
predict_leaf_node_assignment
(test_data, type='Path')[source]¶ Predict on a dataset and return the leaf node assignment (only for tree-based models).
- Parameters
test_data (H2OFrame) – Data on which to make predictions.
type (Enum) – How to identify the leaf node. Nodes can be either identified by a path from to the root node of the tree to the node or by H2O’s internal node id. One of:
"Path"
,"Node_ID"
(default:"Path"
).
- Returns
A new H2OFrame of predictions.
-
r2
(train=False, valid=False, xval=False)[source]¶ Return the R squared for this regression model.
Will return R^2 for GLM Models and will return NaN otherwise.
The R^2 value is defined to be 1 - MSE/var, where var is computed as sigma*sigma.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the R^2 value for the training data.
valid (bool) – If valid is True, then return the R^2 value for the validation data.
xval (bool) – If xval is True, then return the R^2 value for the cross validation data.
- Returns
The R squared for this regression model.
-
residual_degrees_of_freedom
(train=False, valid=False, xval=False)[source]¶ Retreive the residual degress of freedom if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the residual dof for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the residual dof for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the residual dof, or None if it is not present.
-
residual_deviance
(train=False, valid=False, xval=None)[source]¶ Retreive the residual deviance if this model has the attribute, or None otherwise.
- Parameters
train (bool) – Get the residual deviance for the training set. If both train and valid are False, then train is selected by default.
valid (bool) – Get the residual deviance for the validation set. If both train and valid are True, then train is selected by default.
- Returns
Return the residual deviance, or None if it is not present.
-
rmse
(train=False, valid=False, xval=False)[source]¶ Get the Root Mean Square Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the RMSE value for the training data.
valid (bool) – If valid is True, then return the RMSE value for the validation data.
xval (bool) – If xval is True, then return the RMSE value for the cross validation data.
- Returns
The RMSE for this regression model.
-
rmsle
(train=False, valid=False, xval=False)[source]¶ Get the Root Mean Squared Logarithmic Error.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If train is True, then return the RMSLE value for the training data.
valid (bool) – If valid is True, then return the RMSLE value for the validation data.
xval (bool) – If xval is True, then return the RMSLE value for the cross validation data.
- Returns
The RMSLE for this regression model.
-
property
run_time
¶ Model training time in milliseconds
-
save_model_details
(path='', force=False, filename=None)[source]¶ Save Model Details of an H2O Model in JSON Format to disk.
- Parameters
path – a path to save the model details at (hdfs, s3, local)
force – if True overwrite destination directory in case it exists, or throw exception if set to False.
filename – a filename for the saved model (file type is always .json)
- Returns str
the path of the saved model details
-
save_mojo
(path='', force=False, filename=None)[source]¶ Save an H2O Model as MOJO (Model Object, Optimized) to disk.
- Parameters
path – a path to save the model at (hdfs, s3, local)
force – if True overwrite destination directory in case it exists, or throw exception if set to False.
filename – a filename for the saved model (file type is always .zip)
- Returns str
the path of the saved model
-
score_history
()[source]¶ DEPRECATED. Use
scoring_history()
instead.
-
scoring_history
()[source]¶ Retrieve Model Score History.
- Returns
The score history as an H2OTwoDimTable or a Pandas DataFrame.
-
shap_explain_row_plot
(frame, row_index, columns=None, top_n_features=10, figsize=(16, 9), plot_type='barplot', contribution_type='both', save_plot_path=None)¶ SHAP local explanation
SHAP explanation shows contribution of features for a given instance. The sum of the feature contributions and the bias term is equal to the raw prediction of the model, i.e., prediction before applying inverse link function. H2O implements TreeSHAP which when the features are correlated, can increase contribution of a feature that had no influence on the prediction.
- Parameters
model – h2o tree model, such as DRF, XRT, GBM, XGBoost
frame – H2OFrame
row_index – row index of the instance to inspect
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable). When plot_type=”barplot”, then top_n_features will be chosen for each contribution_type.
figsize – figure size; passed directly to matplotlib
plot_type – either “barplot” or “breakdown”
contribution_type – One of “positive”, “negative”, or “both”. Used only for plot_type=”barplot”.
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create SHAP row explanation plot >>> gbm.shap_explain_row_plot(test, row_index=0)
-
shap_summary_plot
(frame, columns=None, top_n_features=20, samples=1000, colorize_factors=True, alpha=1, colormap=None, figsize=(12, 12), jitter=0.35, save_plot_path=None)¶ SHAP summary plot
SHAP summary plot shows contribution of features for each instance. The sum of the feature contributions and the bias term is equal to the raw prediction of the model, i.e., prediction before applying inverse link function.
- Parameters
model – h2o tree model, such as DRF, XRT, GBM, XGBoost
frame – H2OFrame
columns – either a list of columns or column indices to show. If specified parameter top_n_features will be ignored.
top_n_features – a number of columns to pick using variable importance (where applicable).
samples – maximum number of observations to use; if lower than number of rows in the frame, take a random sample
colorize_factors – if True, use colors from the colormap to colorize the factors; otherwise all levels will have same color
alpha – transparency of the points
colormap – colormap to use instead of the default blue to red colormap
figsize – figure size; passed directly to matplotlib
jitter – amount of jitter used to show the point density
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create SHAP summary plot >>> gbm.shap_summary_plot(test)
-
staged_predict_proba
(test_data)[source]¶ Predict class probabilities at each stage of an H2O Model (only GBM models).
The output structure is analogous to the output of function predict_leaf_node_assignment. For each tree t and class c there will be a column Tt.Cc (eg. T3.C1 for tree 3 and class 1). The value will be the corresponding predicted probability of this class by combining the raw contributions of trees T1.Cc,..,TtCc. Binomial models build the trees just for the first class and values in columns Tx.C1 thus correspond to the the probability p0.
- Parameters
test_data (H2OFrame) – Data on which to make predictions.
- Returns
A new H2OFrame of staged predictions.
-
property
start_time
¶ Timestamp (milliseconds since 1970) when the model training was started.
-
std_coef_plot
(num_of_features=None, server=False, save_plot_path=None)[source]¶ Plot a model’s standardized coefficient magnitudes.
- Parameters
num_of_features – the number of features shown in the plot.
server – if true set server settings to matplotlib and show the graph
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
-
property
type
¶ The type of model built:
"classifier"
or"regressor"
or"unsupervised"
-
update_tree_weights
(frame, weights_column)[source]¶ Re-calculates tree-node weights based on provided dataset. Modifying node weights will affect how contribution predictions (Shapley values) are calculated. This can be used to explain the model on a curated sub-population of the training dataset.
- Parameters
frame – frame that will be used to re-populate trees with new observations and to collect per-node weights
weights_column – name of the weight column (can be different from training weights)
-
varimp
(use_pandas=False)[source]¶ Pretty print the variable importances, or return them in a list.
- Parameters
use_pandas (bool) – If True, then the variable importances will be returned as a pandas data frame.
- Returns
A list or Pandas DataFrame.
-
varimp_plot
(num_of_features=None, server=False, save_plot_path=None)[source]¶ Plot the variable importance for a trained model.
- Parameters
num_of_features – the number of features shown in the plot (default is 10 or all if less than 10).
server – if true set server settings to matplotlib and do not show the graph
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
-
weights
(matrix_id=0)[source]¶ Return the frame for the respective weight matrix.
- Parameters
matrix_id – an integer, ranging from 0 to number of layers, that specifies the weight matrix to return.
- Returns
an H2OFrame which represents the weight matrix identified by matrix_id
-
property
xvals
¶ Return a list of the cross-validated models.
- Returns
A list of models.
-
property
MetricsBase
¶
Regression model.
- copyright
2016 H2O.ai
- license
Apache License Version 2.0 (see LICENSE for details)
-
class
h2o.model.metrics_base.
H2OAnomalyDetectionModelMetrics
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
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mean_normalized_score
()[source]¶ Mean Normalized Anomaly Score. For Isolation Forest - normalized average path length.
- Examples
>>> from h2o.estimators.isolation_forest import H2OIsolationForestEstimator >>> train = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/anomaly/ecg_discord_train.csv") >>> test = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/anomaly/ecg_discord_test.csv") >>> isofor_model = H2OIsolationForestEstimator(sample_size=5, ntrees=7) >>> isofor_model.train(training_frame = train) >>> perf = isofor_model.model_performance() >>> perf.mean_normalized_score()
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mean_score
()[source]¶ Mean Anomaly Score. For Isolation Forest represents the average of all tree-path lengths.
- Examples
>>> from h2o.estimators.isolation_forest import H2OIsolationForestEstimator >>> train = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/anomaly/ecg_discord_train.csv") >>> test = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/anomaly/ecg_discord_test.csv") >>> isofor_model = H2OIsolationForestEstimator(sample_size=5, ntrees=7) >>> isofor_model.train(training_frame = train) >>> perf = isofor_model.model_performance() >>> perf.mean_score()
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class
h2o.model.metrics_base.
H2OAutoEncoderModelMetrics
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
- Examples
>>> from h2o.estimators.deeplearning import H2OAutoEncoderEstimator >>> train_ecg = h2o.import_file("http://h2o-public-test-data.s3.amazonaws.com/smalldata/anomaly/ecg_discord_train.csv") >>> test_ecg = h2o.import_file("http://h2o-public-test-data.s3.amazonaws.com/smalldata/anomaly/ecg_discord_test.csv") >>> anomaly_model = H2OAutoEncoderEstimator(activation="Tanh", ... hidden=[50,50,50], ... sparse=True, l1=1e-4, ... epochs=100) >>> anomaly_model.train(x=train_ecg.names, training_frame=train_ecg) >>> anomaly_model.mse()
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class
h2o.model.metrics_base.
H2OBinomialModelMetrics
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
This class is essentially an API for the AUC object. This class contains methods for inspecting the AUC for different criteria. To input the different criteria, use the static variable criteria.
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F0point5
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The F0.5 for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.F0point5()
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F1
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The F1 for the given set of thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.F1()
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F2
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The F2 for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.F2()
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accuracy
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The accuracy for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.accuracy()
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confusion_matrix
(metrics=None, thresholds=None)[source]¶ Get the confusion matrix for the specified metric
- Parameters
metrics – A string (or list of strings) among metrics listed in
maximizing_metrics
. Defaults to ‘f1’.thresholds – A value (or list of values) between 0 and 1. If None, then the thresholds maximizing each provided metric will be used.
- Returns
a list of ConfusionMatrix objects (if there are more than one to return), a single ConfusionMatrix (if there is only one) or None if thresholds are metrics scores are missing.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.confusion_matrix(train)
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error
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold minimizing the error will be used.
- Returns
The error for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.error()
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fallout
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The fallout (same as False Positive Rate) for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.fallout()
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find_idx_by_threshold
(threshold)[source]¶ Retrieve the index in this metric’s threshold list at which the given threshold is located.
- Parameters
threshold – Find the index of this input threshold.
- Returns
the index
- Raises
ValueError – if no such index can be found.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> local_data = [[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'], ... [1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'], ... [0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'], ... [0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'],[0, 'b']] >>> h2o_data = h2o.H2OFrame(local_data) >>> h2o_data.set_names(['response', 'predictor']) >>> h2o_data["response"] = h2o_data["response"].asfactor() >>> gbm = H2OGradientBoostingEstimator(ntrees=1, ... distribution="bernoulli") >>> gbm.train(x=list(range(1,h2o_data.ncol)), ... y="response", ... training_frame=h2o_data) >>> perf = gbm.model_performance() >>> perf.find_idx_by_threshold(0.45)
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find_threshold_by_max_metric
(metric)[source]¶ - Parameters
metrics – A string among the metrics listed in
maximizing_metrics
.- Returns
the threshold at which the given metric is maximal.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> local_data = [[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'], ... [1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'], ... [0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'], ... [0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'],[0, 'b']] >>> h2o_data = h2o.H2OFrame(local_data) >>> h2o_data.set_names(['response', 'predictor']) >>> h2o_data["response"] = h2o_data["response"].asfactor() >>> gbm = H2OGradientBoostingEstimator(ntrees=1, ... distribution="bernoulli") >>> gbm.train(x=list(range(1,h2o_data.ncol)), ... y="response", ... training_frame=h2o_data) >>> perf = gbm.model_performance() >>> perf.find_threshold_by_max_metric("f1")
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fnr
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The False Negative Rate.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.fnr()
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fpr
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The False Positive Rate.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.fpr()
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property
fprs
¶ Return all false positive rates for all threshold values.
- Returns
a list of false positive rates.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution, fold_assignment="Random") >>> gbm.train(y=response_col, x=predictors, validation_frame=valid, training_frame=train) >>> (fprs, tprs) = gbm.roc(train=True, valid=False, xval=False) >>> fprs
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gains_lift
()[source]¶ Retrieve the Gains/Lift table.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.gains_lift()
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max_per_class_error
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold minimizing the error will be used.
- Returns
Return 1 - min(per class accuracy).
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.max_per_class_error()
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maximizing_metrics
= ('absolute_mcc', 'accuracy', 'precision', 'f0point5', 'f1', 'f2', 'mean_per_class_accuracy', 'min_per_class_accuracy', 'tns', 'fns', 'fps', 'tps', 'tnr', 'fnr', 'fpr', 'tpr', 'fallout', 'missrate', 'recall', 'sensitivity', 'specificity')¶ metrics names allowed for confusion matrix
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mcc
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The absolute MCC (a value between 0 and 1, 0 being totally dissimilar, 1 being identical).
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.mcc()
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mean_per_class_error
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold minimizing the error will be used.
- Returns
mean per class error.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.mean_per_class_error()
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metric
(metric, thresholds=None)[source]¶ - Parameters
metric (str) – A metric among
maximizing_metrics
.thresholds – thresholds parameter must be a number or a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used. If ‘all’, then all stored thresholds are used and returned with the matching metric.
- Returns
The set of metrics for the list of thresholds. The returned list has a ‘value’ property holding only the metric value (if no threshold provided or if provided as a number), or all the metric values (if thresholds provided as a list)
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> local_data = [[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'], ... [1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'],[1, 'a'], ... [0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'], ... [0, 'b'],[0, 'b'],[0, 'b'],[0, 'b'],[0, 'b']] >>> h2o_data = h2o.H2OFrame(local_data) >>> h2o_data.set_names(['response', 'predictor']) >>> h2o_data["response"] = h2o_data["response"].asfactor() >>> gbm = H2OGradientBoostingEstimator(ntrees=1, ... distribution="bernoulli") >>> gbm.train(x=list(range(1,h2o_data.ncol)), ... y="response", ... training_frame=h2o_data) >>> perf = gbm.model_performance() >>> perf.metric("tps", [perf.find_threshold_by_max_metric("f1")])[0][1]
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metrics_aliases
= {'fallout': 'fpr', 'missrate': 'fnr', 'recall': 'tpr', 'sensitivity': 'tpr', 'specificity': 'tnr'}¶
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missrate
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The miss rate (same as False Negative Rate).
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.missrate()
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plot
(type='roc', server=False, save_plot_path=None, plot=True, **kwargs)[source]¶ Produce the desired metric plot.
- Parameters
type – the type of metric plot (currently, only ROC curve (‘roc’) and Precision Recall curve (‘pr’) are supported).
server – if True, generate plot inline using matplotlib’s “Agg” backend.
:param save_plot_path filename to save the plot to :param plot True to plot curve, False to get a tuple of values at axis x and y of the plot
(tprs and fprs for AUC, recall and precision for PR)
- Returns
None or values of x and y axis of the plot + the resulting plot (can be accessed using result.figure())
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.plot(type="roc") >>> cars_gbm.plot(type="pr")
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precision
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The precision for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.precision()
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recall
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
Recall for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.recall()
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roc
()[source]¶ Return the coordinates of the ROC curve as a tuple containing the false positive rates as a list and true positive rates as a list. :returns: The ROC values.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(x=predictors, ... y=response_col, ... validation_frame=valid, ... training_frame=train) >>> gbm.roc(train=True, valid=False, xval=False)
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sensitivity
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
Sensitivity or True Positive Rate for this set of metrics and thresholds.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.sensitivity()
-
specificity
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The specificity (same as True Negative Rate).
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.specificity()
-
tnr
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The True Negative Rate.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.tnr()
-
tpr
(thresholds=None)[source]¶ - Parameters
thresholds – thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]). If None, then the threshold maximizing the metric will be used.
- Returns
The True Postive Rate.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.tpr()
-
property
tprs
¶ Return all true positive rates for all threshold values.
- Returns
a list of true positive rates.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution, fold_assignment="Random") >>> gbm.train(y=response_col, x=predictors, validation_frame=valid, training_frame=train) >>> (fprs, tprs) = gbm.roc(train=True, valid=False, xval=False) >>> tprs
-
-
class
h2o.model.metrics_base.
H2OClusteringModelMetrics
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
-
betweenss
()[source]¶ The Between Cluster Sum-of-Square Error, or None if not present.
- Examples
>>> from h2o.estimators.kmeans import H2OKMeansEstimator >>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.betweenss()
-
tot_withinss
()[source]¶ The Total Within Cluster Sum-of-Square Error, or None if not present.
- Examples
>>> from h2o.estimators.kmeans import H2OKMeansEstimator >>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.tot_withinss()
-
totss
()[source]¶ The Total Sum-of-Square Error to Grand Mean, or None if not present.
- Examples
>>> from h2o.estimators.kmeans import H2OKMeansEstimator >>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.totss()
-
-
class
h2o.model.metrics_base.
H2ODimReductionModelMetrics
(metric_json, on=None, algo='')[source]¶
-
class
h2o.model.metrics_base.
H2OHGLMModelMetrics
(metric_json, on=None, algo='HGLM Gaussian Gaussian')[source]¶
-
class
h2o.model.metrics_base.
H2OModelMetricsRegressionCoxPH
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
- Examples
>>> from h2o.estimators.coxph import H2OCoxProportionalHazardsEstimator >>> heart = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/coxph_test/heart.csv") >>> coxph = H2OCoxProportionalHazardsEstimator(start_column="start", ... stop_column="stop", ... ties="breslow") >>> coxph.train(x="age", y="event", training_frame=heart) >>> coxph
-
class
h2o.model.metrics_base.
H2OMultinomialModelMetrics
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
-
confusion_matrix
()[source]¶ Returns a confusion matrix based of H2O’s default prediction threshold for a dataset.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution = distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.confusion_matrix(train)
-
hit_ratio_table
()[source]¶ Retrieve the Hit Ratios.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution = distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.hit_ratio_table()
-
multinomial_auc_table
()[source]¶ Retrieve the multinomial AUC values.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution = distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.multinomial_auc_table()
-
multinomial_aucpr_table
()[source]¶ Retrieve the multinomial PR AUC values.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution = distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.multinomial_aucpr_table()
-
-
class
h2o.model.metrics_base.
H2OOrdinalModelMetrics
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
-
confusion_matrix
()[source]¶ Returns a confusion matrix based of H2O’s default prediction threshold for a dataset.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution = distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.confusion_matrix(train)
-
hit_ratio_table
()[source]¶ Retrieve the Hit Ratios.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> train, valid = cars.split_frame(ratios=[.8], seed=1234) >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution = distribution) >>> gbm.train(x=predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> gbm.hit_ratio_table()
-
-
class
h2o.model.metrics_base.
H2ORegressionModelMetrics
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
This class provides an API for inspecting the metrics returned by a regression model.
It is possible to retrieve the R^2 (1 - MSE/variance) and MSE.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "cylinders" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_glm = H2OGeneralizedLinearEstimator() >>> cars_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_glm.mse()
-
class
h2o.model.metrics_base.
MetricsBase
(metric_json, on=None, algo='')[source]¶ Bases:
h2o.model.metrics_base.MetricsBase
A parent class to house common metrics available for the various Metrics types.
The methods here are available across different model categories.
-
aic
()[source]¶ The AIC for this set of metrics.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.aic()
-
auc
()[source]¶ The AUC for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.auc()
-
aucpr
()[source]¶ The area under the precision recall curve.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.aucpr()
-
gini
()[source]¶ Gini coefficient.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.gini()
-
logloss
()[source]¶ Log loss.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.logloss()
-
mae
()[source]¶ The MAE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "cylinders" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(distribution = "poisson", ... seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.mae()
-
classmethod
make
(kvs)[source]¶ Factory method to instantiate a MetricsBase object from the list of key-value pairs.
-
mean_per_class_error
()[source]¶ The mean per class error.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.mean_per_class_error()
-
mean_residual_deviance
()[source]¶ The mean residual deviance for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> airlines= h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/airlines/AirlinesTest.csv.zip") >>> air_gbm = H2OGradientBoostingEstimator() >>> air_gbm.train(x=list(range(9)), ... y=9, ... training_frame=airlines, ... validation_frame=airlines) >>> air_gbm.mean_residual_deviance(train=True,valid=False,xval=False)
-
mse
()[source]¶ The MSE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.mse()
-
nobs
()[source]¶ The number of observations.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> perf = cars_gbm.model_performance() >>> perf.nobs()
-
null_degrees_of_freedom
()[source]¶ The null DoF if the model has residual deviance, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.null_degrees_of_freedom()
-
null_deviance
()[source]¶ The null deviance if the model has residual deviance, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.null_deviance()
-
r2
()[source]¶ The R squared coefficient.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.r2()
-
residual_degrees_of_freedom
()[source]¶ The residual DoF if the model has residual deviance, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.residual_degrees_of_freedom()
-
residual_deviance
()[source]¶ The residual deviance if the model has it, otherwise None.
- Examples
>>> from h2o.estimators.glm import H2OGeneralizedLinearEstimator >>> prostate = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/prostate/prostate.csv.zip") >>> prostate[2] = prostate[2].asfactor() >>> prostate[4] = prostate[4].asfactor() >>> prostate[5] = prostate[5].asfactor() >>> prostate[8] = prostate[8].asfactor() >>> predictors = ["AGE","RACE","DPROS","DCAPS","PSA","VOL","GLEASON"] >>> response = "CAPSULE" >>> train, valid = prostate.split_frame(ratios=[.8],seed=1234) >>> pros_glm = H2OGeneralizedLinearEstimator(family="binomial") >>> pros_glm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> pros_glm.residual_deviance()
-
rmse
()[source]¶ The RMSE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.rmse()
-
rmsle
()[source]¶ The RMSLE for this set of metrics.
- Examples
>>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "cylinders" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(distribution = "poisson", ... seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.rmsle()
-
show
()[source]¶ Display a short summary of the metrics.
- Examples
>>> from from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> predictors = ["displacement","power","weight","acceleration","year"] >>> response = "economy_20mpg" >>> train, valid = cars.split_frame(ratios = [.8], seed = 1234) >>> cars_gbm = H2OGradientBoostingEstimator(seed = 1234) >>> cars_gbm.train(x = predictors, ... y = response, ... training_frame = train, ... validation_frame = valid) >>> cars_gbm.show()
-
Binomial Classification
¶
-
class
h2o.model.binomial.
H2OBinomialModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
-
F0point5
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the F0.5 for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the F0.5 value for the training data.
valid (bool) – If True, return the F0.5 value for the validation data.
xval (bool) – If True, return the F0.5 value for each of the cross-validated splits.
- Returns
The F0.5 values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> F0point5 = gbm.F0point5() # <- Default: return training metric value >>> F0point5 = gbm.F0point5(train=True, valid=True, xval=True)
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F1
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the F1 value for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the F1 value for the training data.
valid (bool) – If True, return the F1 value for the validation data.
xval (bool) – If True, return the F1 value for each of the cross-validated splits.
- Returns
The F1 values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.F1()# <- Default: return training metric value >>> gbm.F1(train=True, valid=True, xval=True)
-
F2
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the F2 for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the F2 value for the training data.
valid (bool) – If True, return the F2 value for the validation data.
xval (bool) – If True, return the F2 value for each of the cross-validated splits.
- Returns
The F2 values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.F2() # <- Default: return training metric value >>> gbm.F2(train=True, valid=True, xval=True)
-
accuracy
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the accuracy for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the accuracy value for the training data.
valid (bool) – If True, return the accuracy value for the validation data.
xval (bool) – If True, return the accuracy value for each of the cross-validated splits.
- Returns
The accuracy values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.accuracy() # <- Default: return training metric value >>> gbm.accuracy(train=True, valid=True, xval=True)
-
confusion_matrix
(metrics=None, thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the confusion matrix for the specified metrics/thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”
- Parameters
metrics – A string (or list of strings) among metrics listed in
H2OBinomialModelMetrics.maximizing_metrics
. Defaults to ‘f1’.thresholds – A value (or list of values) between 0 and 1. If None, then the thresholds maximizing each provided metric will be used.
train (bool) – If True, return the confusion matrix value for the training data.
valid (bool) – If True, return the confusion matrix value for the validation data.
xval (bool) – If True, return the confusion matrix value for each of the cross-validated splits.
- Returns
The confusion matrix values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.confusion_matrix() # <- Default: return training metric value >>> gbm.confusion_matrix(train=True, valid=True, xval=True)
-
error
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the error for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold minimizing the error will be used.
train (bool) – If True, return the error value for the training data.
valid (bool) – If True, return the error value for the validation data.
xval (bool) – If True, return the error value for each of the cross-validated splits.
- Returns
The error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.error() # <- Default: return training metric >>> gbm.error(train=True, valid=True, xval=True)
-
fallout
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the fallout for a set of thresholds (aka False Positive Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the fallout value for the training data.
valid (bool) – If True, return the fallout value for the validation data.
xval (bool) – If True, return the fallout value for each of the cross-validated splits.
- Returns
The fallout values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.fallout() # <- Default: return training metric >>> gbm.fallout(train=True, valid=True, xval=True)
-
find_idx_by_threshold
(threshold, train=False, valid=False, xval=False)[source]¶ Retrieve the index in this metric’s threshold list at which the given threshold is located.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
threshold (float) – Threshold value to search for in the threshold list.
train (bool) – If True, return the find idx by threshold value for the training data.
valid (bool) – If True, return the find idx by threshold value for the validation data.
xval (bool) – If True, return the find idx by threshold value for each of the cross-validated splits.
- Returns
The find idx by threshold values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", ... "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> idx_threshold = gbm.find_idx_by_threshold(threshold=0.39438, ... train=True) >>> idx_threshold
-
find_threshold_by_max_metric
(metric, train=False, valid=False, xval=False)[source]¶ If all are False (default), then return the training metric value.
If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
metric (str) – A metric among the metrics listed in
H2OBinomialModelMetrics.maximizing_metrics
.train (bool) – If True, return the find threshold by max metric value for the training data.
valid (bool) – If True, return the find threshold by max metric value for the validation data.
xval (bool) – If True, return the find threshold by max metric value for each of the cross-validated splits.
- Returns
The find threshold by max metric values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", ... "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> max_metric = gbm.find_threshold_by_max_metric(metric="f2", ... train=True) >>> max_metric
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fnr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the False Negative Rates for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the FNR value for the training data.
valid (bool) – If True, return the FNR value for the validation data.
xval (bool) – If True, return the FNR value for each of the cross-validated splits.
- Returns
The FNR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.fnr() # <- Default: return training metric >>> gbm.fnr(train=True, valid=True, xval=True)
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fpr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the False Positive Rates for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the FPR value for the training data.
valid (bool) – If True, return the FPR value for the validation data.
xval (bool) – If True, return the FPR value for each of the cross-validated splits.
- Returns
The FPR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.fpr() # <- Default: return training metric >>> gbm.fpr(train=True, valid=True, xval=True)
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gains_lift
(train=False, valid=False, xval=False)[source]¶ Get the Gains/Lift table for the specified metrics.
If all are False (default), then return the training metric Gains/Lift table. If more than one options is set to True, then return a dictionary of metrics where t he keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the gains lift value for the training data.
valid (bool) – If True, return the gains lift value for the validation data.
xval (bool) – If True, return the gains lift value for each of the cross-validated splits.
- Returns
The gains lift values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.gains_lift() # <- Default: return training metric Gain/Lift table >>> gbm.gains_lift(train=True, valid=True, xval=True)
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kolmogorov_smirnov
()[source]¶ Retrieves a Kolmogorov-Smirnov metric for given binomial model. The number returned is in range between 0 and 1. K-S metric represents the degree of separation between the positive (1) and negative (0) cumulative distribution functions. Detailed metrics per each group are to be found in the gains-lift table.
- Returns
Kolmogorov-Smirnov metric, a number between 0 and 1
- Examples
>>> from h2o.estimators import H2OGradientBoostingEstimator >>> airlines = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/testng/airlines_train.csv") >>> model = H2OGradientBoostingEstimator(ntrees=1, ... gainslift_bins=20) >>> model.train(x=["Origin", "Distance"], ... y="IsDepDelayed", ... training_frame=airlines) >>> model.kolmogorov_smirnov()
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max_per_class_error
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the max per class error for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold minimizing the error will be used.
train (bool) – If True, return the max per class error value for the training data.
valid (bool) – If True, return the max per class error value for the validation data.
xval (bool) – If True, return the max per class error value for each of the cross-validated splits.
- Returns
The max per class error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.max_per_class_error() # <- Default: return training metric value >>> gbm.max_per_class_error(train=True, valid=True, xval=True)
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mcc
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the MCC for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the MCC value for the training data.
valid (bool) – If True, return the MCC value for the validation data.
xval (bool) – If True, return the MCC value for each of the cross-validated splits.
- Returns
The MCC values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.mcc() # <- Default: return training metric value >>> gbm.mcc(train=True, valid=True, xval=True)
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mean_per_class_error
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the mean per class error for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold minimizing the error will be used.
train (bool) – If True, return the mean per class error value for the training data.
valid (bool) – If True, return the mean per class error value for the validation data.
xval (bool) – If True, return the mean per class error value for each of the cross-validated splits.
- Returns
The mean per class error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.mean_per_class_error() # <- Default: return training metric >>> gbm.mean_per_class_error(train=True, valid=True, xval=True)
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metric
(metric, thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the metric value for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
metric (str) – name of the metric to retrieve.
thresholds – If None, then the threshold maximizing the metric will be used (or minimizing it if the metric is an error).
train (bool) – If True, return the metric value for the training data.
valid (bool) – If True, return the metric value for the validation data.
xval (bool) – If True, return the metric value for each of the cross-validated splits.
- Returns
The metric values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] # thresholds parameter must be a list (i.e. [0.01, 0.5, 0.99]) >>> thresholds = [0.01,0.5,0.99] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) # allowable metrics are absolute_mcc, accuracy, precision, # f0point5, f1, f2, mean_per_class_accuracy, min_per_class_accuracy, # tns, fns, fps, tps, tnr, fnr, fpr, tpr, recall, sensitivity, # missrate, fallout, specificity >>> gbm.metric(metric='tpr', thresholds=thresholds)
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missrate
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the miss rate for a set of thresholds (aka False Negative Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the miss rate value for the training data.
valid (bool) – If True, return the miss rate value for the validation data.
xval (bool) – If True, return the miss rate value for each of the cross-validated splits.
- Returns
The miss rate values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.missrate() # <- Default: return training metric >>> gbm.missrate(train=True, valid=True, xval=True)
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plot
(timestep='AUTO', metric='AUTO', server=False, save_plot_path=None)[source]¶ Plot training set (and validation set if available) scoring history for an H2OBinomialModel.
The timestep and metric arguments are restricted to what is available in its scoring history.
- Parameters
timestep (str) – A unit of measurement for the x-axis.
metric (str) – A unit of measurement for the y-axis.
server (bool) – if True, then generate the image inline (using matplotlib’s “Agg” backend)
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting figure (can be accessed using result.figure())
- Examples
>>> from h2o.estimators import H2OGeneralizedLinearEstimator >>> benign = h2o.import_file("http://s3.amazonaws.com/h2o-public-test-data/smalldata/logreg/benign.csv") >>> response = 3 >>> predictors = [0, 1, 2, 4, 5, 6, 7, 8, 9, 10] >>> model = H2OGeneralizedLinearEstimator(family="binomial") >>> model.train(x=predictors, y=response, training_frame=benign) >>> model.plot(timestep="AUTO", metric="objective", server=False)
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precision
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the precision for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the precision value for the training data.
valid (bool) – If True, return the precision value for the validation data.
xval (bool) – If True, return the precision value for each of the cross-validated splits.
- Returns
The precision values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.precision() # <- Default: return training metric value >>> gbm.precision(train=True, valid=True, xval=True)
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recall
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the recall for a set of thresholds (aka True Positive Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the recall value for the training data.
valid (bool) – If True, return the recall value for the validation data.
xval (bool) – If True, return the recall value for each of the cross-validated splits.
- Returns
The recall values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.recall() # <- Default: return training metric >>> gbm.recall(train=True, valid=True, xval=True)
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roc
(train=False, valid=False, xval=False)[source]¶ Return the coordinates of the ROC curve for a given set of data.
The coordinates are two-tuples containing the false positive rates as a list and true positive rates as a list. If all are False (default), then return is the training data. If more than one ROC curve is requested, the data is returned as a dictionary of two-tuples.
- Parameters
train (bool) – If True, return the ROC value for the training data.
valid (bool) – If True, return the ROC value for the validation data.
xval (bool) – If True, return the ROC value for each of the cross-validated splits.
- Returns
The ROC values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.roc() # <- Default: return training data >>> gbm.roc(train=True, valid=True, xval=True)
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sensitivity
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the sensitivity for a set of thresholds (aka True Positive Rate or Recall).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the sensitivity value for the training data.
valid (bool) – If True, return the sensitivity value for the validation data.
xval (bool) – If True, return the sensitivity value for each of the cross-validated splits.
- Returns
The sensitivity values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.sensitivity() # <- Default: return training metric >>> gbm.sensitivity(train=True, valid=True, xval=True)
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specificity
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the specificity for a set of thresholds (aka True Negative Rate).
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the specificity value for the training data.
valid (bool) – If True, return the specificity value for the validation data.
xval (bool) – If True, return the specificity value for each of the cross-validated splits.
- Returns
The specificity values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.specificity() # <- Default: return training metric >>> gbm.specificity(train=True, valid=True, xval=True)
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tnr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the True Negative Rate for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the TNR value for the training data.
valid (bool) – If True, return the TNR value for the validation data.
xval (bool) – If True, return the TNR value for each of the cross-validated splits.
- Returns
The TNR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.tnr() # <- Default: return training metric >>> gbm.tnr(train=True, valid=True, xval=True)
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tpr
(thresholds=None, train=False, valid=False, xval=False)[source]¶ Get the True Positive Rate for a set of thresholds.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
thresholds – If None, then the threshold maximizing the metric will be used.
train (bool) – If True, return the TPR value for the training data.
valid (bool) – If True, return the TPR value for the validation data.
xval (bool) – If True, return the TPR value for each of the cross-validated splits.
- Returns
The TPR values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["economy_20mpg"] = cars["economy_20mpg"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <=.2] >>> response_col = "economy_20mpg" >>> distribution = "bernoulli" >>> predictors = ["displacement", "power", "weight", "acceleration", "year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(y=response_col, ... x=predictors, ... validation_frame=valid, ... training_frame=train) >>> gbm.tpr() # <- Default: return training metric >>> gbm.tpr(train=True, valid=True, xval=True)
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Multinomial Classification
¶
-
class
h2o.model.multinomial.
H2OMultinomialModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
-
confusion_matrix
(data)[source]¶ Returns a confusion matrix based of H2O’s default prediction threshold for a dataset.
- Parameters
data (H2OFrame) – the frame with the prediction results for which the confusion matrix should be extracted.
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> confusion_matrix = gbm.confusion_matrix(train) >>> confusion_matrix
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hit_ratio_table
(train=False, valid=False, xval=False)[source]¶ Retrieve the Hit Ratios.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train – If train is True, then return the hit ratio value for the training data.
valid – If valid is True, then return the hit ratio value for the validation data.
xval – If xval is True, then return the hit ratio value for the cross validation data.
- Returns
The hit ratio for this regression model.
- Example
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> distribution = "multinomial" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> hit_ratio_table = gbm.hit_ratio_table() # <- Default: return training metrics >>> hit_ratio_table >>> hit_ratio_table1 = gbm.hit_ratio_table(train=True, ... valid=True, ... xval=True) >>> hit_ratio_table1
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mean_per_class_error
(train=False, valid=False, xval=False)[source]¶ Retrieve the mean per class error across all classes
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the mean_per_class_error value for the training data.
valid (bool) – If True, return the mean_per_class_error value for the validation data.
xval (bool) – If True, return the mean_per_class_error value for each of the cross-validated splits.
- Returns
The mean_per_class_error values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> mean_per_class_error = gbm.mean_per_class_error() # <- Default: return training metric >>> mean_per_class_error >>> mean_per_class_error1 = gbm.mean_per_class_error(train=True, ... valid=True, ... xval=True) >>> mean_per_class_error1
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multinomial_auc_table
(train=False, valid=False, xval=False)[source]¶ Retrieve the multinomial AUC table.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the multinomial_auc_table for the training data.
valid (bool) – If True, return the multinomial_auc_table for the validation data.
xval (bool) – If True, return the multinomial_auc_table for each of the cross-validated splits.
- Returns
The multinomial_auc_table values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> multinomial_auc_table = gbm.multinomial_auc_table() # <- Default: return training metric >>> multinomial_auc_table >>> multinomial_auc_table1 = gbm.multinomial_auc_table(train=True, ... valid=True, ... xval=True) >>> multinomial_auc_table1
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multinomial_aucpr_table
(train=False, valid=False, xval=False)[source]¶ Retrieve the multinomial PR AUC table.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the amultinomial_aucpr_table for the training data.
valid (bool) – If True, return the multinomial_aucpr_table for the validation data.
xval (bool) – If True, return the multinomial_aucpr_table for each of the cross-validated splits.
- Returns
The average_pairwise_auc values for the specified key(s).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> multinomial_aucpr_table = gbm.multinomial_aucpr_table() # <- Default: return training metric >>> multinomial_aucpr_table >>> multinomial_aucpr_table1 = gbm.multinomial_aucpr_table(train=True, ... valid=True, ... xval=True) >>> multinomial_aucpr_table1
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plot
(timestep='AUTO', metric='AUTO', save_plot_path=None, **kwargs)[source]¶ Plots training set (and validation set if available) scoring history for an H2OMultinomialModel. The timestep and metric arguments are restricted to what is available in its scoring history.
- Parameters
timestep – A unit of measurement for the x-axis. This can be AUTO, duration, or number_of_trees.
metric – A unit of measurement for the y-axis. This can be AUTO, logloss, classification_error, or rmse.
- Returns
Object that contains the resulting scoring history plot (can be accessed using result.figure()).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> cars["cylinders"] = cars["cylinders"].asfactor() >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "cylinders" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> from h2o.estimators.gbm import H2OGradientBoostingEstimator >>> distribution = "multinomial" >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution) >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> gbm.plot(metric="AUTO", timestep="AUTO")
-
Regression
¶
-
class
h2o.model.regression.
H2ORegressionModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
-
plot
(timestep='AUTO', metric='AUTO', save_plot_path=None, **kwargs)[source]¶ Plots training set (and validation set if available) scoring history for an H2ORegressionModel. The timestep and metric arguments are restricted to what is available in its scoring history.
- Parameters
timestep – A unit of measurement for the x-axis.
metric – A unit of measurement for the y-axis.
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
Object that contains the resulting scoring history plot (can be accessed using result.figure()).
- Examples
>>> cars = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/junit/cars_20mpg.csv") >>> r = cars[0].runif() >>> train = cars[r > .2] >>> valid = cars[r <= .2] >>> response_col = "economy" >>> distribution = "gaussian" >>> predictors = ["displacement","power","weight","acceleration","year"] >>> gbm = H2OGradientBoostingEstimator(nfolds=3, ... distribution=distribution, ... fold_assignment="Random") >>> gbm.train(x=predictors, ... y=response_col, ... training_frame=train, ... validation_frame=valid) >>> gbm.plot(timestep="AUTO", metric="AUTO",)
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residual_analysis_plot
(frame, figsize=(16, 9), save_plot_path=None)¶ Residual Analysis
Do Residual Analysis and plot the fitted values vs residuals on a test dataset. Ideally, residuals should be randomly distributed. Patterns in this plot can indicate potential problems with the model selection, e.g., using simpler model than necessary, not accounting for heteroscedasticity, autocorrelation, etc. If you notice “striped” lines of residuals, that is just an indication that your response variable was integer valued instead of real valued.
- Parameters
model – H2OModel
frame – H2OFrame
figsize – figure size; passed directly to matplotlib
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
object that contains the resulting matplotlib figure (can be accessed using result.figure())
- Examples
>>> import h2o >>> from h2o.estimators import H2OGradientBoostingEstimator >>> >>> h2o.init() >>> >>> # Import the wine dataset into H2O: >>> f = "https://h2o-public-test-data.s3.amazonaws.com/smalldata/wine/winequality-redwhite-no-BOM.csv" >>> df = h2o.import_file(f) >>> >>> # Set the response >>> response = "quality" >>> >>> # Split the dataset into a train and test set: >>> train, test = df.split_frame([0.8]) >>> >>> # Train a GBM >>> gbm = H2OGradientBoostingEstimator() >>> gbm.train(y=response, training_frame=train) >>> >>> # Create the residual analysis plot >>> gbm.residual_analysis_plot(test)
-
-
h2o.model.regression.
h2o_explained_variance_score
(y_actual, y_predicted, weights=None)[source]¶ Explained variance regression score function.
- Parameters
y_actual – H2OFrame of actual response.
y_predicted – H2OFrame of predicted response.
weights – (Optional) sample weights
- Returns
the explained variance score.
-
h2o.model.regression.
h2o_mean_absolute_error
(y_actual, y_predicted, weights=None)[source]¶ Mean absolute error regression loss.
- Parameters
y_actual – H2OFrame of actual response.
y_predicted – H2OFrame of predicted response.
weights – (Optional) sample weights
- Returns
mean absolute error loss (best is 0.0).
-
h2o.model.regression.
h2o_mean_squared_error
(y_actual, y_predicted, weights=None)[source]¶ Mean squared error regression loss
- Parameters
y_actual – H2OFrame of actual response.
y_predicted – H2OFrame of predicted response.
weights – (Optional) sample weights
- Returns
mean squared error loss (best is 0.0).
-
h2o.model.regression.
h2o_median_absolute_error
(y_actual, y_predicted)[source]¶ Median absolute error regression loss
- Parameters
y_actual – H2OFrame of actual response.
y_predicted – H2OFrame of predicted response.
- Returns
median absolute error loss (best is 0.0)
-
h2o.model.regression.
h2o_r2_score
(y_actual, y_predicted, weights=1.0)[source]¶ R-squared (coefficient of determination) regression score function
- Parameters
y_actual – H2OFrame of actual response.
y_predicted – H2OFrame of predicted response.
weights – (Optional) sample weights
- Returns
R-squared (best is 1.0, lower is worse).
Dimensionality Reduction
¶
-
class
h2o.model.dim_reduction.
H2ODimReductionModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
Dimension reduction model, such as PCA or GLRM.
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num_iterations
()[source]¶ Get the number of iterations that it took to converge or reach max iterations.
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proj_archetypes
(test_data, reverse_transform=False)[source]¶ Convert archetypes of the model into original feature space.
- Parameters
test_data (H2OFrame) – The dataset upon which the model was trained.
reverse_transform (bool) – Whether the transformation of the training data during model-building should be reversed on the projected archetypes.
- Returns
model archetypes projected back into the original training data’s feature space.
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reconstruct
(test_data, reverse_transform=False)[source]¶ Reconstruct the training data from the model and impute all missing values.
- Parameters
test_data (H2OFrame) – The dataset upon which the model was trained.
reverse_transform (bool) – Whether the transformation of the training data during model-building should be reversed on the reconstructed frame.
- Returns
the approximate reconstruction of the training data.
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screeplot
(type='barplot', server=False, save_plot_path=None)[source]¶ Produce the scree plot.
Library
matplotlib
is required for this function.- Parameters
type (str) – either
"barplot"
or"lines"
.server (bool) – if true set server settings to matplotlib and do not show the graph
save_plot_path – a path to save the plot via using mathplotlib function savefig
- Returns
Object that contains the resulting scree plot (can be accessed like result.figure()).
-
Clustering Methods
¶
-
class
h2o.model.clustering.
H2OClusteringModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
For examples: from h2o.estimators.kmeans import H2OKMeansEstimator
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betweenss
(train=False, valid=False, xval=False)[source]¶ Get the between cluster sum of squares.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the between cluster sum of squares value for the training data.
valid (bool) – If True, return the between cluster sum of squares value for the validation data.
xval (bool) – If True, return the between cluster sum of squares value for each of the cross-validated splits.
- Returns
The between cluster sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> betweenss = km.betweenss() # <- Default: return training metrics >>> betweenss >>> betweenss3 = km.betweenss(train=False, ... valid=False, ... xval=True) >>> betweenss3
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centers
()[source]¶ The centers for the KMeans model.
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.centers()
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centers_std
()[source]¶ The standardized centers for the kmeans model.
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.centers_std()
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centroid_stats
(train=False, valid=False, xval=False)[source]¶ Get the centroid statistics for each cluster.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the centroid statistic for the training data.
valid (bool) – If True, return the centroid statistic for the validation data.
xval (bool) – If True, return the centroid statistic for each of the cross-validated splits.
- Returns
The centroid statistics for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> centroid_stats = km.centroid_stats() # <- Default: return training metrics >>> centroid_stats >>> centroid_stats1 = km.centroid_stats(train=True, ... valid=False, ... xval=False) >>> centroid_stats1
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num_iterations
()[source]¶ Get the number of iterations it took to converge or reach max iterations.
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> km.num_iterations()
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size
(train=False, valid=False, xval=False)[source]¶ Get the sizes of each cluster.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the cluster sizes for the training data.
valid (bool) – If True, return the cluster sizes for the validation data.
xval (bool) – If True, return the cluster sizes for each of the cross-validated splits.
- Returns
The cluster sizes for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> size = km.size() # <- Default: return training metrics >>> size >>> size1 = km.size(train=False, ... valid=False, ... xval=True) >>> size1
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tot_withinss
(train=False, valid=False, xval=False)[source]¶ Get the total within cluster sum of squares.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the total within cluster sum of squares value for the training data.
valid (bool) – If True, return the total within cluster sum of squares value for the validation data.
xval (bool) – If True, return the total within cluster sum of squares value for each of the cross-validated splits.
- Returns
The total within cluster sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> tot_withinss = km.tot_withinss() # <- Default: return training metrics >>> tot_withinss >>> tot_withinss2 = km.tot_withinss(train=True, ... valid=False, ... xval=True) >>> tot_withinss2
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totss
(train=False, valid=False, xval=False)[source]¶ Get the total sum of squares.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the total sum of squares value for the training data.
valid (bool) – If True, return the total sum of squares value for the validation data.
xval (bool) – If True, return the total sum of squares value for each of the cross-validated splits.
- Returns
The total sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> totss = km.totss() # <- Default: return training metrics >>> totss
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withinss
(train=False, valid=False, xval=False)[source]¶ Get the within cluster sum of squares for each cluster.
If all are False (default), then return the training metric value. If more than one options is set to True, then return a dictionary of metrics where the keys are “train”, “valid”, and “xval”.
- Parameters
train (bool) – If True, return the total sum of squares value for the training data.
valid (bool) – If True, return the total sum of squares value for the validation data.
xval (bool) – If True, return the total sum of squares value for each of the cross-validated splits.
- Returns
The total sum of squares values for the specified key(s).
- Examples
>>> iris = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/iris/iris_train.csv") >>> km = H2OKMeansEstimator(k=3, nfolds=3) >>> km.train(x=list(range(4)), training_frame=iris) >>> withinss = km.withinss() # <- Default: return training metrics >>> withinss >>> withinss2 = km.withinss(train=True, ... valid=True, ... xval=True) >>> withinss2
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AutoEncoders
¶
-
class
h2o.model.autoencoder.
H2OAutoEncoderModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
-
anomaly
(test_data, per_feature=False)[source]¶ Obtain the reconstruction error for the input test_data.
- Parameters
test_data (H2OFrame) – The dataset upon which the reconstruction error is computed.
per_feature (bool) – Whether to return the square reconstruction error per feature. Otherwise, return the mean square error.
- Returns
the reconstruction error.
- Examples
>>> from h2o.estimators.deeplearning import H2OAutoEncoderEstimator >>> train = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/bigdata/laptop/mnist/train.csv.gz") >>> test = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/bigdata/laptop/mnist/test.csv.gz") >>> predictors = list(range(0,784)) >>> resp = 784 >>> train = train[predictors] >>> test = test[predictors] >>> ae_model = H2OAutoEncoderEstimator(activation="Tanh", ... hidden=[2], ... l1=1e-5, ... ignore_const_cols=False, ... epochs=1) >>> ae_model.train(x=predictors,training_frame=train) >>> test_rec_error = ae_model.anomaly(test) >>> test_rec_error >>> test_rec_error_features = ae_model.anomaly(test, per_feature=True) >>> test_rec_error_features
-
Word Embedding
¶
-
class
h2o.model.word_embedding.
H2OWordEmbeddingModel
[source]¶ Bases:
h2o.model.model_base.ModelBase
Word embedding model.
-
find_synonyms
(word, count=20)[source]¶ Find synonyms using a word2vec model.
- Parameters
word (str) – A single word to find synonyms for.
count (int) – The first “count” synonyms will be returned.
- Returns
the approximate reconstruction of the training data.
- Examples
>>> job_titles = h2o.import_file(("https://s3.amazonaws.com/h2o-public-test-data/smalldata/craigslistJobTitles.csv"), ... col_names = ["category", "jobtitle"], ... col_types = ["string", "string"], ... header = 1) >>> words = job_titles.tokenize(" ") >>> w2v_model = H2OWord2vecEstimator(epochs = 10) >>> w2v_model.train(training_frame=words) >>> synonyms = w2v_model.find_synonyms("teacher", count = 5) >>> print(synonyms)
-
to_frame
()[source]¶ Converts a given word2vec model into H2OFrame.
- Returns
a frame representing learned word embeddings.
- Examples
>>> words = h2o.create_frame(rows=1000,cols=1,string_fraction=1.0,missing_fraction=0.0) >>> embeddings = h2o.create_frame(rows=1000,cols=100,real_fraction=1.0,missing_fraction=0.0) >>> word_embeddings = words.cbind(embeddings) >>> w2v_model = H2OWord2vecEstimator(pre_trained=word_embeddings) >>> w2v_model.train(training_frame=word_embeddings) >>> w2v_frame = w2v_model.to_frame() >>> word_embeddings.names = w2v_frame.names >>> word_embeddings.as_data_frame().equals(word_embeddings.as_data_frame())
-
transform
(words, aggregate_method)[source]¶ Transform words (or sequences of words) to vectors using a word2vec model.
- Parameters
words (str) – An H2OFrame made of a single column containing source words.
aggregate_method (str) – Specifies how to aggregate sequences of words. If method is NONE then no aggregation is performed and each input word is mapped to a single word-vector. If method is ‘AVERAGE’ then input is treated as sequences of words delimited by NA. Each word of a sequences is internally mapped to a vector and vectors belonging to the same sentence are averaged and returned in the result.
- Returns
the approximate reconstruction of the training data.
- Examples
>>> job_titles = h2o.import_file(("https://s3.amazonaws.com/h2o-public-test-data/smalldata/craigslistJobTitles.csv"), ... col_names = ["category", "jobtitle"], ... col_types = ["string", "string"], ... header = 1) >>> STOP_WORDS = ["ax","i","you","edu","s","t","m","subject","can","lines","re","what", ... "there","all","we","one","the","a","an","of","or","in","for","by","on", ... "but","is","in","a","not","with","as","was","if","they","are","this","and","it","have", ... "from","at","my","be","by","not","that","to","from","com","org","like","likes","so"] >>> words = job_titles.tokenize(" ") >>> words = words[(words.isna()) | (~ words.isin(STOP_WORDS)),:] >>> w2v_model = H2OWord2vecEstimator(epochs = 10) >>> w2v_model.train(training_frame=words) >>> job_title_vecs = w2v_model.transform(words, aggregate_method = "AVERAGE")
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