Loading Data from OpenML

First, we load the wine reviews dataset, where the target is the points given be a reviewer:

from sklearn.datasets import fetch_openml

wine_reviews = fetch_openml(data_id=42074, as_frame=True)

df = wine_reviews.frame
df.head()

For this example, we use the following subset of numerical and categorical features in the data. The target are continuous values from 80 to 100:

numerical_features = ["price"]
categorical_features = [
    "country",
    "province",
    "region_1",
    "region_2",
    "variety",
    "winery",
]
target_name = "points"

X = df[numerical_features + categorical_features]
y = df[target_name]

_ = y.hist()

Training and Evaluating Pipelines with Different Encoders

In this section, we will evaluate pipelines with HistGradientBoostingRegressor with different encoding strategies. First, we list out the encoders we will be using to preprocess the categorical features:

from sklearn.compose import ColumnTransformer
from sklearn.preprocessing import OneHotEncoder, OrdinalEncoder, TargetEncoder

categorical_preprocessors = [
    ("drop", "drop"),
    ("ordinal", OrdinalEncoder(handle_unknown="use_encoded_value", unknown_value=-1)),
    (
        "one_hot",
        OneHotEncoder(handle_unknown="ignore", max_categories=20, sparse_output=False),
    ),
    ("target", TargetEncoder(target_type="continuous")),
]

Next, we evaluate the models using cross validation and record the results:

from sklearn.ensemble import HistGradientBoostingRegressor
from sklearn.model_selection import cross_validate
from sklearn.pipeline import make_pipeline

n_cv_folds = 3
max_iter = 20
results = []


def evaluate_model_and_store(name, pipe):
    result = cross_validate(
        pipe,
        X,
        y,
        scoring="neg_root_mean_squared_error",
        cv=n_cv_folds,
        return_train_score=True,
    )
    rmse_test_score = -result["test_score"]
    rmse_train_score = -result["train_score"]
    results.append(
        {
            "preprocessor": name,
            "rmse_test_mean": rmse_test_score.mean(),
            "rmse_test_std": rmse_train_score.std(),
            "rmse_train_mean": rmse_train_score.mean(),
            "rmse_train_std": rmse_train_score.std(),
        }
    )


for name, categorical_preprocessor in categorical_preprocessors:
    preprocessor = ColumnTransformer(
        [
            ("numerical", "passthrough", numerical_features),
            ("categorical", categorical_preprocessor, categorical_features),
        ]
    )
    pipe = make_pipeline(
        preprocessor, HistGradientBoostingRegressor(random_state=0, max_iter=max_iter)
    )
    evaluate_model_and_store(name, pipe)

Native Categorical Feature Support

In this section, we build and evaluate a pipeline that uses native categorical feature support in HistGradientBoostingRegressor, which only supports up to 255 unique categories. In our dataset, the most of the categorical features have more than 255 unique categories:

n_unique_categories = df[categorical_features].nunique().sort_values(ascending=False)
n_unique_categories

winery      14810
region_1     1236
variety       632
province      455
country        48
region_2       18
dtype: int64

To workaround the limitation above, we group the categorical features into low cardinality and high cardinality features. The high cardinality features will be target encoded and the low cardinality features will use the native categorical feature in gradient boosting.

high_cardinality_features = n_unique_categories[n_unique_categories > 255].index
low_cardinality_features = n_unique_categories[n_unique_categories <= 255].index
mixed_encoded_preprocessor = ColumnTransformer(
    [
        ("numerical", "passthrough", numerical_features),
        (
            "high_cardinality",
            TargetEncoder(target_type="continuous"),
            high_cardinality_features,
        ),
        (
            "low_cardinality",
            OrdinalEncoder(handle_unknown="use_encoded_value", unknown_value=-1),
            low_cardinality_features,
        ),
    ],
    verbose_feature_names_out=False,
)

# The output of the of the preprocessor must be set to pandas so the
# gradient boosting model can detect the low cardinality features.
mixed_encoded_preprocessor.set_output(transform="pandas")
mixed_pipe = make_pipeline(
    mixed_encoded_preprocessor,
    HistGradientBoostingRegressor(
        random_state=0, max_iter=max_iter, categorical_features=low_cardinality_features
    ),
)
mixed_pipe

Pipeline(steps=[('columntransformer',
                 ColumnTransformer(transformers=[('numerical', 'passthrough',
                                                  ['price']),
                                                 ('high_cardinality',
                                                  TargetEncoder(target_type='continuous'),
                                                  Index(['winery', 'region_1', 'variety', 'province'], dtype='object')),
                                                 ('low_cardinality',
                                                  OrdinalEncoder(handle_unknown='use_encoded_value',
                                                                 unknown_value=-1),
                                                  Index(['country', 'region_2'], dtype='object'))],
                                   verbose_feature_names_out=False)),
                ('histgradientboostingregressor',
                 HistGradientBoostingRegressor(categorical_features=Index(['country', 'region_2'], dtype='object'),
                                               max_iter=20, random_state=0))])

Pipeline(steps=[('columntransformer',
                 ColumnTransformer(transformers=[('numerical', 'passthrough',
                                                  ['price']),
                                                 ('high_cardinality',
                                                  TargetEncoder(target_type='continuous'),
                                                  Index(['winery', 'region_1', 'variety', 'province'], dtype='object')),
                                                 ('low_cardinality',
                                                  OrdinalEncoder(handle_unknown='use_encoded_value',
                                                                 unknown_value=-1),
                                                  Index(['country', 'region_2'], dtype='object'))],
                                   verbose_feature_names_out=False)),
                ('histgradientboostingregressor',
                 HistGradientBoostingRegressor(categorical_features=Index(['country', 'region_2'], dtype='object'),
                                               max_iter=20, random_state=0))])

ColumnTransformer(transformers=[('numerical', 'passthrough', ['price']),
                                ('high_cardinality',
                                 TargetEncoder(target_type='continuous'),
                                 Index(['winery', 'region_1', 'variety', 'province'], dtype='object')),
                                ('low_cardinality',
                                 OrdinalEncoder(handle_unknown='use_encoded_value',
                                                unknown_value=-1),
                                 Index(['country', 'region_2'], dtype='object'))],
                  verbose_feature_names_out=False)

['price']

passthrough

Index(['winery', 'region_1', 'variety', 'province'], dtype='object')

TargetEncoder(target_type='continuous')

Index(['country', 'region_2'], dtype='object')

OrdinalEncoder(handle_unknown='use_encoded_value', unknown_value=-1)

HistGradientBoostingRegressor(categorical_features=Index(['country', 'region_2'], dtype='object'),
                              max_iter=20, random_state=0)

Finally, we evaluate the pipeline using cross validation and record the results:

evaluate_model_and_store("mixed_target", mixed_pipe)

Plotting the Results

In this section, we display the results by plotting the test and train scores:

import matplotlib.pyplot as plt
import pandas as pd

results_df = (
    pd.DataFrame(results).set_index("preprocessor").sort_values("rmse_test_mean")
)

fig, (ax1, ax2) = plt.subplots(
    1, 2, figsize=(12, 8), sharey=True, constrained_layout=True
)
xticks = range(len(results_df))
name_to_color = dict(
    zip((r["preprocessor"] for r in results), ["C0", "C1", "C2", "C3", "C4"])
)

for subset, ax in zip(["test", "train"], [ax1, ax2]):
    mean, std = f"rmse_{subset}_mean", f"rmse_{subset}_std"
    data = results_df[[mean, std]].sort_values(mean)
    ax.bar(
        x=xticks,
        height=data[mean],
        yerr=data[std],
        width=0.9,
        color=[name_to_color[name] for name in data.index],
    )
    ax.set(
        title=f"RMSE ({subset.title()})",
        xlabel="Encoding Scheme",
        xticks=xticks,
        xticklabels=data.index,
    )

When evaluating the predictive performance on the test set, dropping the categories perform the worst and the target encoders performs the best. This can be explained as follows:

• Dropping the categorical features makes the pipeline less expressive and underfitting as a result;
• Due to the high cardinality and to reduce the training time, the one-hot encoding scheme uses max_categories=20 which prevents the features from expanding too much, which can result in underfitting.
• If we had not set max_categories=20, the one-hot encoding scheme would have likely made the pipeline overfitting as the number of features explodes with rare category occurrences that are correlated with the target by chance (on the training set only);
• The ordinal encoding imposes an arbitrary order to the features which are then treated as numerical values by the HistGradientBoostingRegressor. Since this model groups numerical features in 256 bins per feature, many unrelated categories can be grouped together and as a result overall pipeline can underfit;
• When using the target encoder, the same binning happens, but since the encoded values are statistically ordered by marginal association with the target variable, the binning use by the HistGradientBoostingRegressor makes sense and leads to good results: the combination of smoothed target encoding and binning works as a good regularizing strategy against overfitting while not limiting the expressiveness of the pipeline too much.

Total running time of the script: (0 minutes 25.772 seconds)

Download Jupyter notebook: plot_target_encoder.ipynb

Download Python source code: plot_target_encoder.py

Download zipped: plot_target_encoder.zip

Related examples

Categorical Feature Support in Gradient Boosting

Target Encoder’s Internal Cross fitting

Column Transformer with Mixed Types

Release Highlights for scikit-learn 1.4