max_after_balance_size
¶
Available in: GBM, DRF, Deep Learning, GLM, Naïve-Bayes, AutoML, Uplift DRF
Hyperparameter: yes
Description¶
When your datasest includes imbalanced data, you may find it necessary to balance the data using the balance_classes
option. When specified, the algorithm will either undersample the majority classes or oversampling the minority classes. In most cases, though, enabling the balance_classes
option will increase the data frame size. To reduce the data frame size, you can use the max_after_balance_size
option. This specifies the maximum relative size of the training data after balancing class counts and defaults to 5.0.
Example¶
library(h2o)
h2o.init()
# import the covtype dataset:
# this dataset is used to classify the correct forest cover type
# original dataset can be found at https://archive.ics.uci.edu/ml/datasets/Covertype
covtype <- h2o.importFile("https://s3.amazonaws.com/h2o-public-test-data/smalldata/covtype/covtype.20k.data")
# convert response column to a factor
covtype[, 55] <- as.factor(covtype[, 55])
# set the predictor names and the response column name
predictors <- colnames(covtype[1:54])
response <- 'C55'
# split into train and validation sets
covtype_splits <- h2o.splitFrame(data = covtype, ratios = 0.8, seed = 1234)
train <- covtype_splits[[1]]
valid <- covtype_splits[[2]]
# look at the frequencies of each class
print(h2o.table(covtype['C55']))
# try using the max_after_balance_size parameter:
max <- 0.85
cov_gbm <- h2o.gbm(x = predictors, y = response, training_frame = train,
validation_frame = valid, balance_classes = TRUE,
max_after_balance_size = max, seed = 1234)
# print the logloss for your model
print(h2o.logloss(cov_gbm, valid = TRUE))
# grid over `max_after_balance_size`
# select the values for `max_after_balance_size` to grid over
# the first and last max_after_balance_sizes reduce the size of the
# original dataset, the second increases the dataset by 1.7
hyper_params <- list( max_after_balance_size = c(0.85, 1.7, 0.5) )
# this example uses cartesian grid search because the search space is small
# and we want to see the performance of all models. For a larger search space use
# random grid search instead: {'strategy': "RandomDiscrete"}
# build grid search with previously made GBM and hyperparameters
grid <- h2o.grid(x = predictors, y = response, training_frame = train, validation_frame = valid,
algorithm = "gbm", grid_id = "covtype_grid", balance_classes = TRUE, hyper_params = hyper_params,
search_criteria = list(strategy = "Cartesian"), seed = 1234)
# Sort the grid models by logloss
sorted_grid <- h2o.getGrid("covtype_grid", sort_by = "logloss", decreasing = FALSE)
sorted_grid
import h2o
from h2o.estimators.gbm import H2OGradientBoostingEstimator
h2o.init()
h2o.cluster().show_status()
# import the covtype dataset:
# this dataset is used to classify the correct forest cover type
# original dataset can be found at https://archive.ics.uci.edu/ml/datasets/Covertype
covtype = h2o.import_file("https://s3.amazonaws.com/h2o-public-test-data/smalldata/covtype/covtype.20k.data")
# convert response column to a factor
covtype[54] = covtype[54].asfactor()
# set the predictor names and the response column name
predictors = covtype.columns[0:54]
response = 'C55'
# split into train and validation sets
train, valid = covtype.split_frame(ratios = [.8], seed = 1234)
# look at the frequencies of each class
print(covtype[54].table())
# try using the max_after_balance_size parameter:
max = .85
cov_gbm = H2OGradientBoostingEstimator(balance_classes = True,
max_after_balance_size = max,
seed = 1234)
cov_gbm.train(x = predictors, y = response, training_frame = train, validation_frame = valid)
# print the logloss for your model
print('logloss', cov_gbm.logloss(valid = True))
# grid over `max_after_balance_size`
# import Grid Search
from h2o.grid.grid_search import H2OGridSearch
# select the values for `max_after_balance_size` to grid over
# the first and last max_after_balance_sizes reduce the size of the
# original dataset, the second increases the dataset by 1.7
hyper_params = {'max_after_balance_size': [.85, 1.7,.5]}
# this example uses cartesian grid search because the search space is small
# and we want to see the performance of all models. For a larger search space use
# random grid search instead: {'strategy': "RandomDiscrete"}
# initialize the GBM estimator
cov_gbm_2 = H2OGradientBoostingEstimator(balance_classes = True, seed = 1234)
# build grid search with previously made GBM and hyperparameters
grid = H2OGridSearch(model = cov_gbm_2, hyper_params = hyper_params,
search_criteria = {'strategy': "Cartesian"})
# train using the grid
grid.train(x = predictors, y = response, training_frame = train, validation_frame = valid)
# sort the grid models by logloss
sorted_grid = grid.get_grid(sort_by='logloss', decreasing=False)
print(sorted_grid)