MII_Salin_Oleg_PIbd-33/lec4.ipynb

Загрузка набора данных¶

In [2]:

import pandas as pd

from sklearn import set_config

set_config(transform_output="pandas")

random_state=9

df = pd.read_csv("data/Medical_insurance.csv", index_col=False)

df["smoker"] = df["smoker"].apply(lambda x: 1 if x == "yes" else 0)

Разделение набора данных на обучающую и тестовые выборки (80/20) для задачи классификации¶

Целевой признак -- Survived

In [3]:

from utils import split_stratified_into_train_val_test
X_train, X_val, X_test, y_train, y_val, y_test = split_stratified_into_train_val_test(
    df, stratify_colname="smoker", target_colname="smoker",frac_train=0.80, frac_val=0, frac_test=0.20, random_state=random_state
)

display("X_train", X_train)
display("y_train", y_train)

display("X_test", X_test)
display("y_test", y_test)

'X_train'

	age	sex	bmi	children	smoker	region	charges
671	29	female	31.160	0	0	northeast	3943.59540
808	18	male	30.140	0	0	southeast	1131.50660
795	27	male	28.500	0	1	northwest	18310.74200
576	22	male	26.840	0	0	southeast	1664.99960
1232	54	female	24.605	3	0	northwest	12479.70895
...	...	...	...	...	...	...	...
105	20	male	28.025	1	1	northwest	17560.37975
461	42	male	30.000	0	1	southwest	22144.03200
2650	49	female	33.345	2	0	northeast	10370.91255
1674	59	female	36.765	1	1	northeast	47896.79135
2689	43	male	27.800	0	1	southwest	37829.72420

2217 rows × 7 columns

'y_train'

	smoker
671	0
808	0
795	1
576	0
1232	0
...	...
105	1
461	1
2650	0
1674	1
2689	1

2217 rows × 1 columns

'X_test'

	age	sex	bmi	children	smoker	region	charges
124	47	female	33.915	3	0	northwest	10115.00885
778	35	male	34.320	3	0	southeast	5934.37980
372	42	female	33.155	1	0	northeast	7639.41745
1969	32	female	23.650	1	0	southeast	17626.23951
2522	44	female	25.000	1	0	southwest	7623.51800
...	...	...	...	...	...	...	...
908	63	male	39.800	3	0	southwest	15170.06900
1203	51	male	32.300	1	0	northeast	9964.06000
45	55	male	37.300	0	0	southwest	20630.28351
2669	18	male	30.030	1	0	southeast	1720.35370
1230	52	male	34.485	3	1	northwest	60021.39897

555 rows × 7 columns

'y_test'

	smoker
124	0
778	0
372	0
1969	0
2522	0
...	...
908	0
1203	0
45	0
2669	0
1230	1

555 rows × 1 columns

Формирование конвейера для классификации данных¶

preprocessing_num -- конвейер для обработки числовых данных: заполнение пропущенных значений и стандартизация

preprocessing_cat -- конвейер для обработки категориальных данных: заполнение пропущенных данных и унитарное кодирование

features_preprocessing -- трансформер для предобработки признаков

features_engineering -- трансформер для конструирования признаков

drop_columns -- трансформер для удаления колонок

features_postprocessing -- трансформер для унитарного кодирования новых признаков

pipeline_end -- основной конвейер предобработки данных и конструирования признаков

Конвейер выполняется последовательно.

Трансформер выполняет параллельно для указанного набора колонок.

Документация:

https://scikit-learn.org/1.5/api/sklearn.pipeline.html

https://scikit-learn.org/1.5/modules/generated/sklearn.compose.ColumnTransformer.html#sklearn.compose.ColumnTransformer

In [4]:

from sklearn.compose import ColumnTransformer
from sklearn.discriminant_analysis import StandardScaler
from sklearn.impute import SimpleImputer
from sklearn.pipeline import Pipeline
from sklearn.preprocessing import OneHotEncoder

columns_to_drop = ["smoker"]
num_columns = [
    column
    for column in df.columns
    if df[column].dtype != "object"
]
cat_columns = [
    column
    for column in df.columns
    if df[column].dtype == "object"
]

num_imputer = SimpleImputer(strategy="median")
num_scaler = StandardScaler()
preprocessing_num = Pipeline(
    [
        ("imputer", num_imputer),
        ("scaler", num_scaler),
    ]
)

cat_imputer = SimpleImputer(strategy="constant", fill_value="unknown")
cat_encoder = OneHotEncoder(handle_unknown="ignore", sparse_output=False, drop="first")
preprocessing_cat = Pipeline(
    [
        ("imputer", cat_imputer),
        ("encoder", cat_encoder),
    ]
)

features_preprocessing = ColumnTransformer(
    verbose_feature_names_out=False,
    transformers=[
        ("prepocessing_num", preprocessing_num, num_columns),
        ("prepocessing_cat", preprocessing_cat, cat_columns),
    ],
    remainder="passthrough"
)

drop_columns = ColumnTransformer(
    verbose_feature_names_out=False,
    transformers=[
        ("drop_columns", "drop", columns_to_drop),
    ],
    remainder="passthrough",
)

pipeline_end = Pipeline(
    [
        ("features_preprocessing", features_preprocessing),
        ("drop_columns", drop_columns),
    ]
)

Демонстрация работы конвейера для предобработки данных при классификации¶

In [5]:

preprocessing_result = pipeline_end.fit_transform(X_train)
preprocessed_df = pd.DataFrame(
    preprocessing_result,
    columns=pipeline_end.get_feature_names_out(),
)

preprocessed_df

Out[5]:

	age	bmi	children	charges	sex_male	region_northwest	region_southeast	region_southwest
671	-0.730722	0.085028	-0.907368	-0.769241	0.0	0.0	0.0	0.0
808	-1.513302	-0.081153	-0.907368	-0.999824	1.0	0.0	1.0	0.0
795	-0.873009	-0.348348	-0.907368	0.408827	1.0	1.0	0.0	0.0
576	-1.228727	-0.618800	-0.907368	-0.956079	1.0	0.0	1.0	0.0
1232	1.047868	-0.982934	1.555858	-0.069302	0.0	1.0	0.0	0.0
...	...	...	...	...	...	...	...	...
105	-1.371015	-0.425736	-0.086293	0.347299	1.0	1.0	0.0	0.0
461	0.194145	-0.103963	-0.907368	0.723147	1.0	0.0	0.0	1.0
2650	0.692150	0.441016	0.734783	-0.242218	0.0	0.0	0.0	0.0
1674	1.403586	0.998214	-0.086293	2.834804	0.0	0.0	0.0	0.0
2689	0.265288	-0.462394	-0.907368	2.009332	1.0	0.0	0.0	1.0

2217 rows × 8 columns

Формирование набора моделей для классификации¶

logistic -- логистическая регрессия

ridge -- гребневая регрессия

decision_tree -- дерево решений

knn -- k-ближайших соседей

naive_bayes -- наивный Байесовский классификатор

gradient_boosting -- метод градиентного бустинга (набор деревьев решений)

random_forest -- метод случайного леса (набор деревьев решений)

mlp -- многослойный персептрон (нейронная сеть)

Документация: https://scikit-learn.org/1.5/supervised_learning.html

In [6]:

from sklearn import ensemble, linear_model, naive_bayes, neighbors, neural_network, tree

class_models = {
    "logistic": {"model": linear_model.LogisticRegression()},
    # "ridge": {"model": linear_model.RidgeClassifierCV(cv=5, class_weight="balanced")},
    "ridge": {"model": linear_model.LogisticRegression(penalty="l2", class_weight="balanced")},
    "decision_tree": {
        "model": tree.DecisionTreeClassifier(max_depth=7, random_state=random_state)
    },
    "knn": {"model": neighbors.KNeighborsClassifier(n_neighbors=7)},
    "naive_bayes": {"model": naive_bayes.GaussianNB()},
    "gradient_boosting": {
        "model": ensemble.GradientBoostingClassifier(n_estimators=210)
    },
    "random_forest": {
        "model": ensemble.RandomForestClassifier(
            max_depth=11, class_weight="balanced", random_state=random_state
        )
    },
    "mlp": {
        "model": neural_network.MLPClassifier(
            hidden_layer_sizes=(7,),
            max_iter=500,
            early_stopping=True,
            random_state=random_state,
        )
    },
}

Обучение моделей на обучающем наборе данных и оценка на тестовом¶

In [7]:

import numpy as np # type: ignore
from sklearn import metrics

for model_name in class_models.keys():
    print(f"Model: {model_name}")
    model = class_models[model_name]["model"]

    model_pipeline = Pipeline([("pipeline", pipeline_end), ("model", model)])
    model_pipeline = model_pipeline.fit(X_train, y_train.values.ravel())

    y_train_predict = model_pipeline.predict(X_train)
    y_test_probs = model_pipeline.predict_proba(X_test)[:, 1]
    y_test_predict = np.where(y_test_probs > 0.5, 1, 0)

    class_models[model_name]["pipeline"] = model_pipeline
    class_models[model_name]["probs"] = y_test_probs
    class_models[model_name]["preds"] = y_test_predict

    class_models[model_name]["Precision_train"] = metrics.precision_score(
        y_train, y_train_predict
    )
    class_models[model_name]["Precision_test"] = metrics.precision_score(
        y_test, y_test_predict
    )
    class_models[model_name]["Recall_train"] = metrics.recall_score(
        y_train, y_train_predict
    )
    class_models[model_name]["Recall_test"] = metrics.recall_score(
        y_test, y_test_predict
    )
    class_models[model_name]["Accuracy_train"] = metrics.accuracy_score(
        y_train, y_train_predict
    )
    class_models[model_name]["Accuracy_test"] = metrics.accuracy_score(
        y_test, y_test_predict
    )
    class_models[model_name]["ROC_AUC_test"] = metrics.roc_auc_score(
        y_test, y_test_probs
    )
    class_models[model_name]["F1_train"] = metrics.f1_score(y_train, y_train_predict)
    class_models[model_name]["F1_test"] = metrics.f1_score(y_test, y_test_predict)
    class_models[model_name]["MCC_test"] = metrics.matthews_corrcoef(
        y_test, y_test_predict
    )
    class_models[model_name]["Cohen_kappa_test"] = metrics.cohen_kappa_score(
        y_test, y_test_predict
    )
    class_models[model_name]["Confusion_matrix"] = metrics.confusion_matrix(
        y_test, y_test_predict
    )

Model: logistic
Model: ridge
Model: decision_tree
Model: knn
Model: naive_bayes
Model: gradient_boosting
Model: random_forest
Model: mlp

Сводная таблица оценок качества для использованных моделей классификации¶

Документация: https://scikit-learn.org/1.5/modules/model_evaluation.html

Матрица неточностей

In [8]:

from sklearn.metrics import ConfusionMatrixDisplay
import matplotlib.pyplot as plt

_, ax = plt.subplots(int(len(class_models) / 2), 2, figsize=(12, 10), sharex=False, sharey=False)
for index, key in enumerate(class_models.keys()):
    c_matrix = class_models[key]["Confusion_matrix"]
    disp = ConfusionMatrixDisplay(
        confusion_matrix=c_matrix, display_labels=["non smoker", "smoker"]
    ).plot(ax=ax.flat[index])
    disp.ax_.set_title(key)

plt.subplots_adjust(top=1, bottom=0, hspace=0.4, wspace=0.1)
plt.show()

Точность, полнота, верность (аккуратность), F-мера

In [9]:

class_metrics = pd.DataFrame.from_dict(class_models, "index")[
    [
        "Precision_train",
        "Precision_test",
        "Recall_train",
        "Recall_test",
        "Accuracy_train",
        "Accuracy_test",
        "F1_train",
        "F1_test",
    ]
]
class_metrics.sort_values(
    by="Accuracy_test", ascending=False
).style.background_gradient(
    cmap="plasma",
    low=0.3,
    high=1,
    subset=["Accuracy_train", "Accuracy_test", "F1_train", "F1_test"],
).background_gradient(
    cmap="viridis",
    low=1,
    high=0.3,
    subset=[
        "Precision_train",
        "Precision_test",
        "Recall_train",
        "Recall_test",
    ],
)

Out[9]:

	Precision_train	Precision_test	Recall_train	Recall_test	Accuracy_train	Accuracy_test	F1_train	F1_test
gradient_boosting	1.000000	0.982609	1.000000	1.000000	1.000000	0.996396	1.000000	0.991228
decision_tree	0.976035	0.956522	0.993348	0.973451	0.993685	0.985586	0.984615	0.964912
random_forest	0.995585	0.948718	1.000000	0.982301	0.999098	0.985586	0.997788	0.965217
ridge	0.846154	0.837037	1.000000	1.000000	0.963013	0.960360	0.916667	0.911290
knn	0.903846	0.870690	0.937916	0.893805	0.967073	0.951351	0.920566	0.882096
logistic	0.867368	0.849558	0.913525	0.849558	0.953992	0.938739	0.889849	0.849558
naive_bayes	0.794045	0.824742	0.709534	0.707965	0.903473	0.909910	0.749415	0.761905
mlp	0.910112	0.907692	0.538803	0.522124	0.895354	0.891892	0.676880	0.662921

ROC-кривая, каппа Коэна, коэффициент корреляции Мэтьюса

In [10]:

class_metrics = pd.DataFrame.from_dict(class_models, "index")[
    [
        "Accuracy_test",
        "F1_test",
        "ROC_AUC_test",
        "Cohen_kappa_test",
        "MCC_test",
    ]
]
class_metrics.sort_values(by="ROC_AUC_test", ascending=False).style.background_gradient(
    cmap="plasma",
    low=0.3,
    high=1,
    subset=[
        "ROC_AUC_test",
        "MCC_test",
        "Cohen_kappa_test",
    ],
).background_gradient(
    cmap="viridis",
    low=1,
    high=0.3,
    subset=[
        "Accuracy_test",
        "F1_test",
    ],
)

Out[10]:

	Accuracy_test	F1_test	ROC_AUC_test	Cohen_kappa_test	MCC_test
random_forest	0.985586	0.965217	0.999039	0.956130	0.956360
gradient_boosting	0.996396	0.991228	0.998118	0.988961	0.989021
decision_tree	0.985586	0.964912	0.995745	0.955843	0.955901
knn	0.951351	0.882096	0.990049	0.851456	0.851572
ridge	0.960360	0.911290	0.982001	0.886026	0.891838
logistic	0.938739	0.849558	0.981520	0.811096	0.811096
naive_bayes	0.909910	0.761905	0.974813	0.706746	0.709879
mlp	0.891892	0.662921	0.968086	0.604043	0.636838

In [11]:

best_model = str(class_metrics.sort_values(by="MCC_test", ascending=False).iloc[0].name)

display(best_model)

'gradient_boosting'

Вывод данных с ошибкой предсказания для оценки¶

In [12]:

preprocessing_result = pipeline_end.transform(X_test)
preprocessed_df = pd.DataFrame(
    preprocessing_result,
    columns=pipeline_end.get_feature_names_out(),
)

y_pred = class_models[best_model]["preds"]

error_index = y_test[y_test["smoker"] != y_pred].index.tolist()
display(f"Error items count: {len(error_index)}")

error_predicted = pd.Series(y_pred, index=y_test.index).loc[error_index]
error_df = X_test.loc[error_index].copy()
error_df.insert(loc=1, column="Predicted", value=error_predicted)
error_df.sort_index()

'Error items count: 2'

Out[12]:

	age	Predicted	sex	bmi	children	smoker	region	charges
583	32	1	female	23.65	1	0	southeast	17626.23951
1969	32	1	female	23.65	1	0	southeast	17626.23951

Пример использования обученной модели (конвейера) для предсказания¶

In [13]:

model = class_models[best_model]["pipeline"]

example_id = 1969
print(X_test.loc[example_id, :])
test = pd.DataFrame(X_test.loc[example_id, :]).T
test_preprocessed = pd.DataFrame(preprocessed_df.loc[example_id, :]).T
display(test)
display(test_preprocessed)
result_proba = model.predict_proba(test)[0]
result = model.predict(test)[0]
real = int(y_test.loc[example_id].values[0])
display(f"predicted: {result} (proba: {result_proba})")
display(f"real: {real}")

age                  32
sex              female
bmi               23.65
children              1
smoker                0
region        southeast
charges     17626.23951
Name: 1969, dtype: object

	age	sex	bmi	children	smoker	region	charges
1969	32	female	23.65	1	0	southeast	17626.23951

	age	bmi	children	charges	sex_male	region_northwest	region_southeast	region_southwest
1969	-0.517291	-1.138526	-0.086293	0.3527	0.0	0.0	1.0	0.0

'predicted: 1 (proba: [0.01087081 0.98912919])'

'real: 0'

Подбор гиперпараметров методом поиска по сетке¶

https://www.kaggle.com/code/sociopath00/random-forest-using-gridsearchcv

https://scikit-learn.org/stable/modules/generated/sklearn.model_selection.GridSearchCV.html

In [ ]:

from sklearn.model_selection import GridSearchCV

optimized_model_type = "random_forest"

random_forest_model = class_models[optimized_model_type]["pipeline"]

param_grid = {
    "model__n_estimators": [10, 20, 30, 40, 50, 100, 150, 200, 250, 500],
    "model__max_features": ["sqrt", "log2", 2],
    "model__max_depth": [2, 3, 4, 5, 6, 7, 8, 9 ,10],
    "model__criterion": ["gini", "entropy", "log_loss"],
}

gs_optomizer = GridSearchCV(
    estimator=random_forest_model, param_grid=param_grid, n_jobs=-1
)
gs_optomizer.fit(X_train, y_train.values.ravel())
gs_optomizer.best_params_

Обучение модели с новыми гиперпараметрами

In [ ]:

optimized_model = ensemble.RandomForestClassifier(
    random_state=random_state,
    criterion="gini",
    max_depth=7,
    max_features="sqrt",
    n_estimators=30,
)

result = {}

result["pipeline"] = Pipeline([("pipeline", pipeline_end), ("model", optimized_model)]).fit(X_train, y_train.values.ravel())
result["train_preds"] = result["pipeline"].predict(X_train)
result["probs"] = result["pipeline"].predict_proba(X_test)[:, 1]
result["preds"] = np.where(result["probs"] > 0.5, 1, 0)

result["Precision_train"] = metrics.precision_score(y_train, result["train_preds"])
result["Precision_test"] = metrics.precision_score(y_test, result["preds"])
result["Recall_train"] = metrics.recall_score(y_train, result["train_preds"])
result["Recall_test"] = metrics.recall_score(y_test, result["preds"])
result["Accuracy_train"] = metrics.accuracy_score(y_train, result["train_preds"])
result["Accuracy_test"] = metrics.accuracy_score(y_test, result["preds"])
result["ROC_AUC_test"] = metrics.roc_auc_score(y_test, result["probs"])
result["F1_train"] = metrics.f1_score(y_train, result["train_preds"])
result["F1_test"] = metrics.f1_score(y_test, result["preds"])
result["MCC_test"] = metrics.matthews_corrcoef(y_test, result["preds"])
result["Cohen_kappa_test"] = metrics.cohen_kappa_score(y_test, result["preds"])
result["Confusion_matrix"] = metrics.confusion_matrix(y_test, result["preds"])

Формирование данных для оценки старой и новой версии модели

In [ ]:

optimized_metrics = pd.DataFrame(columns=list(result.keys()))
optimized_metrics.loc[len(optimized_metrics)] = pd.Series(
    data=class_models[optimized_model_type]
)
optimized_metrics.loc[len(optimized_metrics)] = pd.Series(
    data=result
)
optimized_metrics.insert(loc=0, column="Name", value=["Old", "New"])
optimized_metrics = optimized_metrics.set_index("Name")

Оценка параметров старой и новой модели

In [ ]:

optimized_metrics[
    [
        "Precision_train",
        "Precision_test",
        "Recall_train",
        "Recall_test",
        "Accuracy_train",
        "Accuracy_test",
        "F1_train",
        "F1_test",
    ]
].style.background_gradient(
    cmap="plasma",
    low=0.3,
    high=1,
    subset=["Accuracy_train", "Accuracy_test", "F1_train", "F1_test"],
).background_gradient(
    cmap="viridis",
    low=1,
    high=0.3,
    subset=[
        "Precision_train",
        "Precision_test",
        "Recall_train",
        "Recall_test",
    ],
)

Out[ ]:

	Precision_train	Precision_test	Recall_train	Recall_test	Accuracy_train	Accuracy_test	F1_train	F1_test
Name
Old	0.995585	0.948718	1.000000	0.982301	0.999098	0.985586	0.997788	0.965217
New	0.971800	0.923077	0.993348	0.955752	0.992783	0.974775	0.982456	0.939130

In [ ]:

optimized_metrics[
    [
        "Accuracy_test",
        "F1_test",
        "ROC_AUC_test",
        "Cohen_kappa_test",
        "MCC_test",
    ]
].style.background_gradient(
    cmap="plasma",
    low=0.3,
    high=1,
    subset=[
        "ROC_AUC_test",
        "MCC_test",
        "Cohen_kappa_test",
    ],
).background_gradient(
    cmap="viridis",
    low=1,
    high=0.3,
    subset=[
        "Accuracy_test",
        "F1_test",
    ],
)

Out[ ]:

	Accuracy_test	F1_test	ROC_AUC_test	Cohen_kappa_test	MCC_test
Name
Old	0.985586	0.965217	0.999039	0.956130	0.956360
New	0.974775	0.939130	0.996276	0.923227	0.923450

In [ ]:

_, ax = plt.subplots(1, 2, figsize=(10, 4), sharex=False, sharey=False
)

for index in range(0, len(optimized_metrics)):
    c_matrix = optimized_metrics.iloc[index]["Confusion_matrix"]
    disp = ConfusionMatrixDisplay(
        confusion_matrix=c_matrix, display_labels=["smokers", "non smokers"]
    ).plot(ax=ax.flat[index])

plt.subplots_adjust(top=1, bottom=0, hspace=0.4, wspace=0.3)
plt.show()