"""
分箱逻辑:
1.类别型特征:
1)类别数在5个以下,可以直接根据类别来分箱 (binning_cate)
2)类别数在5个以上,建议做降基处理,再根据降基后的类别做分箱
2.数值型特征:
1)离散型数值特征(特征value的变动幅度较小):
若特征value的非重复计数在5个以下,可以直接根据非重复计数值来分箱(binning_cate)
若特征value的非重复计数在5个以上,建议根据业务解释或者数据分布做自定义分箱(binning_self)
2)连续型数值特征(特征value的变动幅度较大):
可以用卡方分箱或自定义分箱。(binning_num,binning_self)
PS:一些特征用卡方分可能会报错,建议这些特征改为手动自定义分箱
3.特征有缺失:
1)缺失率在5%以下,可以先对缺失做填充处理再分箱(binning_num)
2)缺失率在5%以上,建议将缺失当作一个类别来分箱(binning_sparse_col)
4.稀疏特征分箱
建议将稀疏值(一般为0)单独分为一箱,剩下的值做卡方或者自定义分箱(binning_sparse_col)
"""
def binning_cate(df, col, target):
"""
df:数据集
col:输入的特征
target:好坏标记的字段名
return:
bin_df :特征的评估结果
"""
total = df[target].count()
bad = df[target].sum()
good = total - bad
d1 = df.groupby([col], as_index=True)
d2 = pd.DataFrame()
d2['样本数'] = d1[target].count()
d2['黑样本数'] = d1[target].sum()
d2['白样本数'] = d2['样本数'] - d2['黑样本数']
d2['逾期用户占比'] = d2['黑样本数'] / d2['样本数']
d2['badattr'] = d2['黑样本数'] / bad
d2['goodattr'] = d2['白样本数'] / good
d2['WOE'] = np.log(d2['badattr'] / d2['goodattr'])
d2['bin_iv'] = (d2['badattr'] - d2['goodattr']) * d2['WOE']
d2['IV'] = d2['bin_iv'].sum()
bin_df = d2.reset_index()
bin_df.drop(['badattr', 'goodattr', 'bin_iv'], axis=1, inplace=True)
bin_df.rename(columns={col: '分箱结果'}, inplace=True)
bin_df['特征名'] = col
bin_df = pd.concat([bin_df['特征名'], bin_df.iloc[:, :-1]], axis=1)
return bin_df
def binning_self(df, col, target, cut=None, right_border=True):
"""
df:数据集
col:输入的特征
target:好坏标记的字段名
cut:总定义划分区间的list
right_border:设定左开右闭、左闭右开
return:
bin_df :特征的评估结果
"""
total = df[target].count()
bad = df[target].sum()
good = total - bad
bucket = pd.cut(df[col], cut, right=right_border)
d1 = df.groupby(bucket)
d2 = pd.DataFrame()
d2['样本数'] = d1[target].count()
d2['黑样本数'] = d1[target].sum()
d2['白样本数'] = d2['样本数'] - d2['黑样本数']
d2['逾期用户占比'] = d2['黑样本数'] / d2['样本数']
d2['badattr'] = d2['黑样本数'] / bad
d2['goodattr'] = d2['白样本数'] / good
d2['WOE'] = np.log(d2['badattr'] / d2['goodattr'])
d2['bin_iv'] = (d2['badattr'] - d2['goodattr']) * d2['WOE']
d2['IV'] = d2['bin_iv'].sum()
bin_df = d2.reset_index()
bin_df.drop(['badattr', 'goodattr', 'bin_iv'], axis=1, inplace=True)
bin_df.rename(columns={col: '分箱结果'}, inplace=True)
bin_df['特征名'] = col
bin_df = pd.concat([bin_df['特征名'], bin_df.iloc[:, :-1]], axis=1)
ks, precision, tpr, fpr = cal_ks(df, col, target)
bin_df['准确率'] = precision
bin_df['召回率'] = tpr
bin_df['打扰率'] = fpr
bin_df['KS'] = ks
return bin_df
def binning_num(df, target, col, max_bin=None, min_binpct=None):
"""
df:数据集
col:输入的特征
target:好坏标记的字段名
max_bin:最大的分箱个数
min_binpct:区间内样本所占总体的最小比
return:
bin_df :特征的评估结果
"""
total = df[target].count()
bad = df[target].sum()
good = total - bad
inf = float('inf')
ninf = float('-inf')
cut = ChiMerge(df, col, target, max_bin=max_bin, min_binpct=min_binpct)
cut.insert(0, ninf)
cut.append(inf)
bucket = pd.cut(df[col], cut)
d1 = df.groupby(bucket)
d2 = pd.DataFrame()
d2['样本数'] = d1[target].count()
d2['黑样本数'] = d1[target].sum()
d2['白样本数'] = d2['样本数'] - d2['黑样本数']
d2['逾期用户占比'] = d2['黑样本数'] / d2['样本数']
d2['badattr'] = d2['黑样本数'] / bad
d2['goodattr'] = d2['白样本数'] / good
d2['WOE'] = np.log(d2['badattr'] / d2['goodattr'])
d2['bin_iv'] = (d2['badattr'] - d2['goodattr']) * d2['WOE']
d2['IV'] = d2['bin_iv'].sum()
bin_df = d2.reset_index()
bin_df.drop(['badattr', 'goodattr', 'bin_iv'], axis=1, inplace=True)
bin_df.rename(columns={col: '分箱结果'}, inplace=True)
bin_df['特征名'] = col
bin_df = pd.concat([bin_df['特征名'], bin_df.iloc[:, :-1]], axis=1)
ks, precision, tpr, fpr = cal_ks(df, col, target)
bin_df['准确率'] = precision
bin_df['召回率'] = tpr
bin_df['打扰率'] = fpr
bin_df['KS'] = ks
return bin_df
def binning_sparse_col(df, target, col, max_bin=None, min_binpct=None, sparse_value=None):
"""
df:数据集
col:输入的特征
target:好坏标记的字段名
max_bin:最大的分箱个数
min_binpct:区间内样本所占总体的最小比
sparse_value:单独分为一箱的value值
return:
bin_df :特征的评估结果
"""
total = df[target].count()
bad = df[target].sum()
good = total - bad
# 对稀疏值0值或者缺失值单独分箱
temp1 = df[df[col] == sparse_value]
temp2 = df[~(df[col] == sparse_value)]
bucket_sparse = pd.cut(temp1[col], [float('-inf'), sparse_value])
group1 = temp1.groupby(bucket_sparse)
bin_df1 = pd.DataFrame()
bin_df1['样本数'] = group1[target].count()
bin_df1['黑样本数'] = group1[target].sum()
bin_df1['白样本数'] = bin_df1['样本数'] - bin_df1['黑样本数']
bin_df1['逾期用户占比'] = bin_df1['黑样本数'] / bin_df1['样本数']
bin_df1['badattr'] = bin_df1['黑样本数'] / bad
bin_df1['goodattr'] = bin_df1['白样本数'] / good
bin_df1['WOE'] = np.log(bin_df1['badattr'] / bin_df1['goodattr'])
bin_df1['bin_iv'] = (bin_df1['badattr'] - bin_df1['goodattr']) * bin_df1['WOE']
bin_df1 = bin_df1.reset_index()
# 对剩余部分做卡方分箱
cut = ChiMerge(temp2, col, target, max_bin=max_bin, min_binpct=min_binpct)
cut.insert(0, sparse_value)
cut.append(float('inf'))
bucket = pd.cut(temp2[col], cut)
group2 = temp2.groupby(bucket)
bin_df2 = pd.DataFrame()
bin_df2['样本数'] = group2[target].count()
bin_df2['黑样本数'] = group2[target].sum()
bin_df2['白样本数'] = bin_df2['样本数'] - bin_df2['黑样本数']
bin_df2['逾期用户占比'] = bin_df2['黑样本数'] / bin_df2['样本数']
bin_df2['badattr'] = bin_df2['黑样本数'] / bad
bin_df2['goodattr'] = bin_df2['白样本数'] / good
bin_df2['WOE'] = np.log(bin_df2['badattr'] / bin_df2['goodattr'])
bin_df2['bin_iv'] = (bin_df2['badattr'] - bin_df2['goodattr']) * bin_df2['WOE']
bin_df2 = bin_df2.reset_index()
# 合并分箱结果
bin_df = pd.concat([bin_df1, bin_df2], axis=0)
bin_df['IV'] = bin_df['bin_iv'].sum().round(3)
bin_df.drop(['badattr', 'goodattr', 'bin_iv'], axis=1, inplace=True)
bin_df.rename(columns={col: '分箱结果'}, inplace=True)
bin_df['特征名'] = col
bin_df = pd.concat([bin_df['特征名'], bin_df.iloc[:, :-1]], axis=1)
ks, precision, tpr, fpr = cal_ks(df, col, target)
bin_df['准确率'] = precision
bin_df['召回率'] = tpr
bin_df['打扰率'] = fpr
bin_df['KS'] = ks
return bin_df