Kaggle ICR比赛现在在进行中,这个比赛是一个典型的数据挖掘比赛,很适合入门学习。本文将介绍现在ICR基础的解决方案。
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赛题名称:ICR - Identifying Age-Related Conditions
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赛题任务:数据挖掘
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https://www.kaggle.com/competitions/icr-identify-age-related-conditions
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代码地址:https://www.kaggle.com/code/chaitanyagiri/icr-2023-single-lgbm-0-12-cv-0-16-lb
赛题任务
比赛数据包含与三种与年龄相关的状况相关联的五十多个匿名健康特征。您的目标是预测受试者是否被诊断出患有这些病症之一——二元分类问题。
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步骤1:读取数据集
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train.csv训练集
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test.csv - 测试集。
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greeks.csv:训练集元数据
COMP_PATH = "/kaggle/input/icr-identify-age-related-conditions"
train = pd.read_csv(f"{
COMP_PATH}/train.csv")
test = pd.read_csv(f"{
COMP_PATH}/test.csv")
sample_submission = pd.read_csv(f"{
COMP_PATH}/sample_submission.csv")
greeks = pd.read_csv(f"{
COMP_PATH}/greeks.csv")
步骤2:自定义评价指标
赛题使用的balance log loss,为了与赛题保持一致,可以自定义指标。当然也可以自定义目标函数。
def competition_log_loss(y_true, y_pred):
N_0 = np.sum(1 - y_true)
N_1 = np.sum(y_true)
p_1 = np.clip(y_pred, 1e-15, 1 - 1e-15)
p_0 = 1 - p_1
log_loss_0 = -np.sum((1 - y_true) * np.log(p_0)) / N_0
log_loss_1 = -np.sum(y_true * np.log(p_1)) / N_1
return (log_loss_0 + log_loss_1)/2
def balanced_log_loss(y_true, y_pred):
N_0 = np.sum(1 - y_true)
N_1 = np.sum(y_true)
p_1 = np.clip(y_pred, 1e-15, 1 - 1e-15)
p_0 = 1 - p_1
log_loss_0 = -np.sum((1 - y_true) * np.log(p_0))
log_loss_1 = -np.sum(y_true * np.log(p_1))
w_0 = 1 / N_0
w_1 = 1 / N_1
balanced_log_loss = 2*(w_0 * log_loss_0 + w_1 * log_loss_1) / (w_0 + w_1)
return balanced_log_loss/(N_0+N_1)
步骤3:定义数据划分
由于数据集存在类别分布不均衡的情况,因此建议按照原信息或比赛标签进行划分验证集。
kf = StratifiedKFold(n_splits=5, random_state=42, shuffle=True)
df['fold'] = -1
for fold, (train_idx, test_idx) in enumerate(kf.split(df, greeks['Alpha'])):
df.loc[test_idx, 'fold'] = fold
df.groupby('fold')["Class"].value_counts()
步骤4:模型训练与验证
由于比赛是典型的数据挖掘赛题,因此建议使用lightgbm。然后在训练中,可以进行调参,加入early stop。
并记录下每折的精度,按照每折的权重作为最终的加权。这也是一种集成方法。
weights = []
for fold in range(5):
train_df = df[df['fold'] != fold]
valid_df = df[df['fold'] == fold]
valid_ids = valid_df.Id.values.tolist()
X_train, y_train = train_df.drop(['Id', 'Class', 'fold'], axis=1), train_df['Class']
X_valid, y_valid = valid_df.drop(['Id', 'Class', 'fold'], axis=1), valid_df['Class']
# 使用lightgbm进行训练和验证
lgb = LGBMClassifier(boosting_type='goss', learning_rate=0.06733232950390658, n_estimators = 50000,
early_stopping_round = 300, random_state=42,
subsample=0.6970532011679706,
colsample_bytree=0.6055755840633003,
class_weight='balanced',
metric='none', is_unbalance=True, max_depth=8)
# 存储每折的权重
weights.append(1/balanced_logloss)
步骤5:模型预测
final_valid_predictions = pd.DataFrame.from_dict(final_valid_predictions, orient="index").reset_index()
final_valid_predictions.columns = ['Id', 'class_0', 'class_1']
final_valid_predictions.to_csv(r"oof.csv", index=False)
test_dict = {
}
test_dict.update(dict(zip(test.Id.values.tolist(), test_preds)))
submission = pd.DataFrame.from_dict(test_dict, orient="index").reset_index()
submission.columns = ['Id', 'class_0', 'class_1']
submission.to_csv(r"submission.csv", index=False)
submission