Task2 数据分析
此部分为零基础入门金融风控的 Task2 数据分析部分,带你来了解数据,熟悉数据,为后续的特征工程做准备,欢迎大家后续多多交流。
赛题:零基础入门数据挖掘 - 零基础入门金融风控之贷款违约
目的:
-
1.EDA价值主要在于熟悉了解整个数据集的基本情况(缺失值,异常值),对数据集进行验证是否可以进行接下来的机器学习或者深度学习建模.
-
2.了解变量间的相互关系、变量与预测值之间的存在关系。
-
3.为特征工程做准备
项目地址:https://github.com/datawhalechina/team-learning-data-mining/tree/master/FinancialRiskControl
比赛地址:https://tianchi.aliyun.com/competition/entrance/531830/introduction
2.1 学习目标
- 学习如何对数据集整体概况进行分析,包括数据集的基本情况(缺失值,异常值)
- 学习了解变量间的相互关系、变量与预测值之间的存在关系
- 完成相应学习打卡任务
2.2 内容介绍
- 数据总体了解:
- 读取数据集并了解数据集大小,原始特征维度;
- 通过info熟悉数据类型;
- 粗略查看数据集中各特征基本统计量;
- 缺失值和唯一值:
- 查看数据缺失值情况
- 查看唯一值特征情况
- 深入数据-查看数据类型
- 类别型数据
- 数值型数据
- 离散数值型数据
- 连续数值型数据
- 数据间相关关系
- 特征和特征之间关系
- 特征和目标变量之间关系
- 用pandas_profiling生成数据报告
2.3 代码示例
2.3.1 导入数据分析及可视化过程需要的库
python
import pandas as pd
import numpy as np
import matplotlib.pyplot as plt
import seaborn as sns
import datetime
import warnings
warnings.filterwarnings('ignore')
/Users/exudingtao/opt/anaconda3/lib/python3.7/site-packages/statsmodels/tools/_testing.py:19: FutureWarning: pandas.util.testing is deprecated. Use the functions in the public API at pandas.testing instead.
import pandas.util.testing as tm
以上库都是pip install 安装就好,如果本机有python2,python3两个python环境傻傻分不清哪个的话,可以pip3 install 。或者直接在notebook中'!pip3 install ****'安装。
说明:
本次数据分析探索,尤其可视化部分均选取某些特定变量进行了举例,所以它只是一个方法的展示而不是整个赛题数据分析的解决方案。
2.3.2 读取文件
python
data_train = pd.read_csv('./train.csv')
python
data_test_a = pd.read_csv('./testA.csv')
2.3.2.1读取文件的拓展知识
- pandas读取数据时相对路径载入报错时,尝试使用os.getcwd()查看当前工作目录。
- TSV与CSV的区别:
- 从名称上即可知道,TSV是用制表符(Tab,'\t')作为字段值的分隔符;CSV是用半角逗号(',')作为字段值的分隔符;
- Python对TSV文件的支持:
Python的csv模块准确的讲应该叫做dsv模块,因为它实际上是支持范式的分隔符分隔值文件(DSV,delimiter-separated values)的。
delimiter参数值默认为半角逗号,即默认将被处理文件视为CSV。当delimiter='\t'时,被处理文件就是TSV。
- 读取文件的部分(适用于文件特别大的场景)
- 通过nrows参数,来设置读取文件的前多少行,nrows是一个大于等于0的整数。
- 分块读取
python
data_train_sample = pd.read_csv("./train.csv",nrows=5)
python
#设置chunksize参数,来控制每次迭代数据的大小
chunker = pd.read_csv("./train.csv",chunksize=5)
for item in chunker:
print(type(item))
#<class 'pandas.core.frame.DataFrame'>
print(len(item))
#5
2.3.3总体了解
查看数据集的样本个数和原始特征维度
python
data_test_a.shape
(200000, 48)
python
data_train.shape
(800000, 47)
python
data_train.columns
Index(['id', 'loanAmnt', 'term', 'interestRate', 'installment', 'grade',
'subGrade', 'employmentTitle', 'employmentLength', 'homeOwnership',
'annualIncome', 'verificationStatus', 'issueDate', 'isDefault',
'purpose', 'postCode', 'regionCode', 'dti', 'delinquency_2years',
'ficoRangeLow', 'ficoRangeHigh', 'openAcc', 'pubRec',
'pubRecBankruptcies', 'revolBal', 'revolUtil', 'totalAcc',
'initialListStatus', 'applicationType', 'earliesCreditLine', 'title',
'policyCode', 'n0', 'n1', 'n2', 'n2.1', 'n4', 'n5', 'n6', 'n7', 'n8',
'n9', 'n10', 'n11', 'n12', 'n13', 'n14'],
dtype='object')
查看一下具体的列名,赛题理解部分已经给出具体的特征含义,这里方便阅读再给一下:
- id 为贷款清单分配的唯一信用证标识
- loanAmnt 贷款金额
- term 贷款期限(year)
- interestRate 贷款利率
- installment 分期付款金额
- grade 贷款等级
- subGrade 贷款等级之子级
- employmentTitle 就业职称
- employmentLength 就业年限(年)
- homeOwnership 借款人在登记时提供的房屋所有权状况
- annualIncome 年收入
- verificationStatus 验证状态
- issueDate 贷款发放的月份
- purpose 借款人在贷款申请时的贷款用途类别
- postCode 借款人在贷款申请中提供的邮政编码的前3位数字
- regionCode 地区编码
- dti 债务收入比
- delinquency_2years 借款人过去2年信用档案中逾期30天以上的违约事件数
- ficoRangeLow 借款人在贷款发放时的fico所属的下限范围
- ficoRangeHigh 借款人在贷款发放时的fico所属的上限范围
- openAcc 借款人信用档案中未结信用额度的数量
- pubRec 贬损公共记录的数量
- pubRecBankruptcies 公开记录清除的数量
- revolBal 信贷周转余额合计
- revolUtil 循环额度利用率,或借款人使用的相对于所有可用循环信贷的信贷金额
- totalAcc 借款人信用档案中当前的信用额度总数
- initialListStatus 贷款的初始列表状态
- applicationType 表明贷款是个人申请还是与两个共同借款人的联合申请
- earliesCreditLine 借款人最早报告的信用额度开立的月份
- title 借款人提供的贷款名称
- policyCode 公开可用的策略_代码=1新产品不公开可用的策略_代码=2
- n系列匿名特征 匿名特征n0-n14,为一些贷款人行为计数特征的处理
通过info()来熟悉数据类型
python
data_train.info()
<class 'pandas.core.frame.DataFrame'>
RangeIndex: 800000 entries, 0 to 799999
Data columns (total 47 columns):
# Column Non-Null Count Dtype
--- ------ -------------- -----
0 id 800000 non-null int64
1 loanAmnt 800000 non-null float64
2 term 800000 non-null int64
3 interestRate 800000 non-null float64
4 installment 800000 non-null float64
5 grade 800000 non-null object
6 subGrade 800000 non-null object
7 employmentTitle 799999 non-null float64
8 employmentLength 753201 non-null object
9 homeOwnership 800000 non-null int64
10 annualIncome 800000 non-null float64
11 verificationStatus 800000 non-null int64
12 issueDate 800000 non-null object
13 isDefault 800000 non-null int64
14 purpose 800000 non-null int64
15 postCode 799999 non-null float64
16 regionCode 800000 non-null int64
17 dti 799761 non-null float64
18 delinquency_2years 800000 non-null float64
19 ficoRangeLow 800000 non-null float64
20 ficoRangeHigh 800000 non-null float64
21 openAcc 800000 non-null float64
22 pubRec 800000 non-null float64
23 pubRecBankruptcies 799595 non-null float64
24 revolBal 800000 non-null float64
25 revolUtil 799469 non-null float64
26 totalAcc 800000 non-null float64
27 initialListStatus 800000 non-null int64
28 applicationType 800000 non-null int64
29 earliesCreditLine 800000 non-null object
30 title 799999 non-null float64
31 policyCode 800000 non-null float64
32 n0 759730 non-null float64
33 n1 759730 non-null float64
34 n2 759730 non-null float64
35 n2.1 759730 non-null float64
36 n4 766761 non-null float64
37 n5 759730 non-null float64
38 n6 759730 non-null float64
39 n7 759730 non-null float64
40 n8 759729 non-null float64
41 n9 759730 non-null float64
42 n10 766761 non-null float64
43 n11 730248 non-null float64
44 n12 759730 non-null float64
45 n13 759730 non-null float64
46 n14 759730 non-null float64
dtypes: float64(33), int64(9), object(5)
memory usage: 286.9+ MB
总体粗略的查看数据集各个特征的一些基本统计量
python
data_train.describe()
| | id | loanAmnt | term | interestRate | installment | employmentTitle | homeOwnership | annualIncome | verificationStatus | isDefault | ... | n5 | n6 | n7 | n8 | n9 | n10 | n11 | n12 | n13 | n14 |
| count | 800000.000000 | 800000.000000 | 800000.000000 | 800000.000000 | 800000.000000 | 799999.000000 | 800000.000000 | 8.000000e+05 | 800000.000000 | 800000.000000 | ... | 759730.000000 | 759730.000000 | 759730.000000 | 759729.000000 | 759730.000000 | 766761.000000 | 730248.000000 | 759730.000000 | 759730.000000 | 759730.000000 |
| mean | 399999.500000 | 14416.818875 | 3.482745 | 13.238391 | 437.947723 | 72005.351714 | 0.614213 | 7.613391e+04 | 1.009683 | 0.199513 | ... | 8.107937 | 8.575994 | 8.282953 | 14.622488 | 5.592345 | 11.643896 | 0.000815 | 0.003384 | 0.089366 | 2.178606 |
| std | 230940.252015 | 8716.086178 | 0.855832 | 4.765757 | 261.460393 | 106585.640204 | 0.675749 | 6.894751e+04 | 0.782716 | 0.399634 | ... | 4.799210 | 7.400536 | 4.561689 | 8.124610 | 3.216184 | 5.484104 | 0.030075 | 0.062041 | 0.509069 | 1.844377 |
| min | 0.000000 | 500.000000 | 3.000000 | 5.310000 | 15.690000 | 0.000000 | 0.000000 | 0.000000e+00 | 0.000000 | 0.000000 | ... | 0.000000 | 0.000000 | 0.000000 | 1.000000 | 0.000000 | 0.000000 | 0.000000 | 0.000000 | 0.000000 | 0.000000 |
| 25% | 199999.750000 | 8000.000000 | 3.000000 | 9.750000 | 248.450000 | 427.000000 | 0.000000 | 4.560000e+04 | 0.000000 | 0.000000 | ... | 5.000000 | 4.000000 | 5.000000 | 9.000000 | 3.000000 | 8.000000 | 0.000000 | 0.000000 | 0.000000 | 1.000000 |
| 50% | 399999.500000 | 12000.000000 | 3.000000 | 12.740000 | 375.135000 | 7755.000000 | 1.000000 | 6.500000e+04 | 1.000000 | 0.000000 | ... | 7.000000 | 7.000000 | 7.000000 | 13.000000 | 5.000000 | 11.000000 | 0.000000 | 0.000000 | 0.000000 | 2.000000 |
| 75% | 599999.250000 | 20000.000000 | 3.000000 | 15.990000 | 580.710000 | 117663.500000 | 1.000000 | 9.000000e+04 | 2.000000 | 0.000000 | ... | 11.000000 | 11.000000 | 10.000000 | 19.000000 | 7.000000 | 14.000000 | 0.000000 | 0.000000 | 0.000000 | 3.000000 |
max | 799999.000000 | 40000.000000 | 5.000000 | 30.990000 | 1715.420000 | 378351.000000 | 5.000000 | 1.099920e+07 | 2.000000 | 1.000000 | ... | 70.000000 | 132.000000 | 79.000000 | 128.000000 | 45.000000 | 82.000000 | 4.000000 | 4.000000 | 39.000000 | 30.000000 |
---|
8 rows × 42 columns
python
data_train.head(3).append(data_train.tail(3))
| | id | loanAmnt | term | interestRate | installment | grade | subGrade | employmentTitle | employmentLength | homeOwnership | ... | n5 | n6 | n7 | n8 | n9 | n10 | n11 | n12 | n13 | n14 |
| 0 | 0 | 35000.0 | 5 | 19.52 | 917.97 | E | E2 | 320.0 | 2 years | 2 | ... | 9.0 | 8.0 | 4.0 | 12.0 | 2.0 | 7.0 | 0.0 | 0.0 | 0.0 | 2.0 |
| 1 | 1 | 18000.0 | 5 | 18.49 | 461.90 | D | D2 | 219843.0 | 5 years | 0 | ... | NaN | NaN | NaN | NaN | NaN | 13.0 | NaN | NaN | NaN | NaN |
| 2 | 2 | 12000.0 | 5 | 16.99 | 298.17 | D | D3 | 31698.0 | 8 years | 0 | ... | 0.0 | 21.0 | 4.0 | 5.0 | 3.0 | 11.0 | 0.0 | 0.0 | 0.0 | 4.0 |
| 799997 | 799997 | 6000.0 | 3 | 13.33 | 203.12 | C | C3 | 2582.0 | 10+ years | 1 | ... | 4.0 | 26.0 | 4.0 | 10.0 | 4.0 | 5.0 | 0.0 | 0.0 | 1.0 | 4.0 |
| 799998 | 799998 | 19200.0 | 3 | 6.92 | 592.14 | A | A4 | 151.0 | 10+ years | 0 | ... | 10.0 | 6.0 | 12.0 | 22.0 | 8.0 | 16.0 | 0.0 | 0.0 | 0.0 | 5.0 |
799999 | 799999 | 9000.0 | 3 | 11.06 | 294.91 | B | B3 | 13.0 | 5 years | 0 | ... | 3.0 | 4.0 | 4.0 | 8.0 | 3.0 | 7.0 | 0.0 | 0.0 | 0.0 | 2.0 |
---|
6 rows × 47 columns
2.3.4查看数据集中特征缺失值,唯一值等
查看缺失值
python
print(f'There are {data_train.isnull().any().sum()} columns in train dataset with missing values.')
There are 22 columns in train dataset with missing values.
上面得到训练集有22列特征有缺失值,进一步查看缺失特征中缺失率大于50%的特征
python
have_null_fea_dict = (data_train.isnull().sum()/len(data_train)).to_dict()
fea_null_moreThanHalf = {}
for key,value in have_null_fea_dict.items():
if value > 0.5:
fea_null_moreThanHalf[key] = value
python
fea_null_moreThanHalf
{}
具体的查看缺失特征及缺失率
python
# nan可视化
missing = data_train.isnull().sum()/len(data_train)
missing = missing[missing > 0]
missing.sort_values(inplace=True)
missing.plot.bar()
<matplotlib.axes._subplots.AxesSubplot at 0x1229ab890>
- 纵向了解哪些列存在 "nan", 并可以把nan的个数打印,主要的目的在于查看某一列nan存在的个数是否真的很大,如果nan存在的过多,说明这一列对label的影响几乎不起作用了,可以考虑删掉。如果缺失值很小一般可以选择填充。
- 另外可以横向比较,如果在数据集中,某些样本数据的大部分列都是缺失的且样本足够的情况下可以考虑删除。
Tips:
比赛大杀器lgb模型可以自动处理缺失值,Task4模型会具体学习模型了解模型哦!
查看训练集测试集中特征属性只有一值的特征
python
one_value_fea = [col for col in data_train.columns if data_train[col].nunique() <= 1]
python
one_value_fea_test = [col for col in data_test_a.columns if data_test_a[col].nunique() <= 1]
python
one_value_fea
['policyCode']
python
one_value_fea_test
['policyCode']
python
print(f'There are {len(one_value_fea)} columns in train dataset with one unique value.')
print(f'There are {len(one_value_fea_test)} columns in test dataset with one unique value.')
There are 1 columns in train dataset with one unique value.
There are 1 columns in test dataset with one unique value.
总结:
47列数据中有22列都缺少数据,这在现实世界中很正常。'policyCode'具有一个唯一值(或全部缺失)。有很多连续变量和一些分类变量。
2.3.5 查看特征的数值类型有哪些,对象类型有哪些
- 特征一般都是由类别型特征和数值型特征组成,而数值型特征又分为连续型和离散型。
- 类别型特征有时具有非数值关系,有时也具有数值关系。比如'grade'中的等级A,B,C等,是否只是单纯的分类,还是A优于其他要结合业务判断。
- 数值型特征本是可以直接入模的,但往往风控人员要对其做分箱,转化为WOE编码进而做标准评分卡等操作。从模型效果上来看,特征分箱主要是为了降低变量的复杂性,减少变量噪音对模型的影响,提高自变量和因变量的相关度。从而使模型更加稳定。
python
numerical_fea = list(data_train.select_dtypes(exclude=['object']).columns)
category_fea = list(filter(lambda x: x not in numerical_fea,list(data_train.columns)))
python
numerical_fea
['id',
'loanAmnt',
'term',
'interestRate',
'installment',
'employmentTitle',
'homeOwnership',
'annualIncome',
'verificationStatus',
'isDefault',
'purpose',
'postCode',
'regionCode',
'dti',
'delinquency_2years',
'ficoRangeLow',
'ficoRangeHigh',
'openAcc',
'pubRec',
'pubRecBankruptcies',
'revolBal',
'revolUtil',
'totalAcc',
'initialListStatus',
'applicationType',
'title',
'policyCode',
'n0',
'n1',
'n2',
'n2.1',
'n4',
'n5',
'n6',
'n7',
'n8',
'n9',
'n10',
'n11',
'n12',
'n13',
'n14']
python
category_fea
['grade', 'subGrade', 'employmentLength', 'issueDate', 'earliesCreditLine']
python
data_train.grade
0 E
1 D
2 D
3 A
4 C
..
799995 C
799996 A
799997 C
799998 A
799999 B
Name: grade, Length: 800000, dtype: object
数值型变量分析,数值型肯定是包括连续型变量和离散型变量的,找出来
- 划分数值型变量中的连续变量和离散型变量
python
#过滤数值型类别特征
def get_numerical_serial_fea(data,feas):
numerical_serial_fea = []
numerical_noserial_fea = []
for fea in feas:
temp = data[fea].nunique()
if temp <= 10:
numerical_noserial_fea.append(fea)
continue
numerical_serial_fea.append(fea)
return numerical_serial_fea,numerical_noserial_fea
numerical_serial_fea,numerical_noserial_fea = get_numerical_serial_fea(data_train,numerical_fea)
python
numerical_serial_fea
['id',
'loanAmnt',
'interestRate',
'installment',
'employmentTitle',
'annualIncome',
'purpose',
'postCode',
'regionCode',
'dti',
'delinquency_2years',
'ficoRangeLow',
'ficoRangeHigh',
'openAcc',
'pubRec',
'pubRecBankruptcies',
'revolBal',
'revolUtil',
'totalAcc',
'title',
'n0',
'n1',
'n2',
'n2.1',
'n4',
'n5',
'n6',
'n7',
'n8',
'n9',
'n10',
'n13',
'n14']
python
numerical_noserial_fea
['term',
'homeOwnership',
'verificationStatus',
'isDefault',
'initialListStatus',
'applicationType',
'policyCode',
'n11',
'n12']
- 数值类别型变量分析
python
data_train['term'].value_counts()#离散型变量
3 606902
5 193098
Name: term, dtype: int64
python
data_train['homeOwnership'].value_counts()#离散型变量
0 395732
1 317660
2 86309
3 185
5 81
4 33
Name: homeOwnership, dtype: int64
python
data_train['verificationStatus'].value_counts()#离散型变量
1 309810
2 248968
0 241222
Name: verificationStatus, dtype: int64
python
data_train['initialListStatus'].value_counts()#离散型变量
0 466438
1 333562
Name: initialListStatus, dtype: int64
python
data_train['applicationType'].value_counts()#离散型变量
0 784586
1 15414
Name: applicationType, dtype: int64
python
data_train['policyCode'].value_counts()#离散型变量,无用,全部一个值
1.0 800000
Name: policyCode, dtype: int64
python
data_train['n11'].value_counts()#离散型变量,相差悬殊,用不用再分析
0.0 729682
1.0 540
2.0 24
4.0 1
3.0 1
Name: n11, dtype: int64
python
data_train['n12'].value_counts()#离散型变量,相差悬殊,用不用再分析
0.0 757315
1.0 2281
2.0 115
3.0 16
4.0 3
Name: n12, dtype: int64
- 数值连续型变量分析
python
#每个数字特征得分布可视化
f = pd.melt(data_train, value_vars=numerical_serial_fea)
g = sns.FacetGrid(f, col="variable", col_wrap=2, sharex=False, sharey=False)
g = g.map(sns.distplot, "value")
- 查看某一个数值型变量的分布,查看变量是否符合正态分布,如果不符合正太分布的变量可以log化后再观察下是否符合正态分布。
- 如果想统一处理一批数据变标准化 必须把这些之前已经正态化的数据提出
- 正态化的原因:一些情况下正态非正态可以让模型更快的收敛,一些模型要求数据正态(eg. GMM、KNN),保证数据不要过偏态即可,过于偏态可能会影响模型预测结果。
python
#Ploting Transaction Amount Values Distribution
plt.figure(figsize=(16,12))
plt.suptitle('Transaction Values Distribution', fontsize=22)
plt.subplot(221)
sub_plot_1 = sns.distplot(data_train['loanAmnt'])
sub_plot_1.set_title("loanAmnt Distribuition", fontsize=18)
sub_plot_1.set_xlabel("")
sub_plot_1.set_ylabel("Probability", fontsize=15)
plt.subplot(222)
sub_plot_2 = sns.distplot(np.log(data_train['loanAmnt']))
sub_plot_2.set_title("loanAmnt (Log) Distribuition", fontsize=18)
sub_plot_2.set_xlabel("")
sub_plot_2.set_ylabel("Probability", fontsize=15)
Text(0, 0.5, 'Probability')
- 非数值类别型变量分析
python
category_fea
['grade', 'subGrade', 'employmentLength', 'issueDate', 'earliesCreditLine']
python
data_train['grade'].value_counts()
B 233690
C 227118
A 139661
D 119453
E 55661
F 19053
G 5364
Name: grade, dtype: int64
python
data_train['subGrade'].value_counts()
C1 50763
B4 49516
B5 48965
B3 48600
C2 47068
C3 44751
C4 44272
B2 44227
B1 42382
C5 40264
A5 38045
A4 30928
D1 30538
D2 26528
A1 25909
D3 23410
A3 22655
A2 22124
D4 21139
D5 17838
E1 14064
E2 12746
E3 10925
E4 9273
E5 8653
F1 5925
F2 4340
F3 3577
F4 2859
F5 2352
G1 1759
G2 1231
G3 978
G4 751
G5 645
Name: subGrade, dtype: int64
python
data_train['employmentLength'].value_counts()
10+ years 262753
2 years 72358
< 1 year 64237
3 years 64152
1 year 52489
5 years 50102
4 years 47985
6 years 37254
8 years 36192
7 years 35407
9 years 30272
Name: employmentLength, dtype: int64
python
data_train['issueDate'].value_counts()
2016-03-01 29066
2015-10-01 25525
2015-07-01 24496
2015-12-01 23245
2014-10-01 21461
...
2007-08-01 23
2007-07-01 21
2008-09-01 19
2007-09-01 7
2007-06-01 1
Name: issueDate, Length: 139, dtype: int64
python
data_train['earliesCreditLine'].value_counts()
Aug-2001 5567
Sep-2003 5403
Aug-2002 5403
Oct-2001 5258
Aug-2000 5246
...
May-1960 1
Apr-1958 1
Feb-1960 1
Aug-1946 1
Mar-1958 1
Name: earliesCreditLine, Length: 720, dtype: int64
python
data_train['isDefault'].value_counts()
0 640390
1 159610
Name: isDefault, dtype: int64
总结:
- 上面我们用value_counts()等函数看了特征属性的分布,但是图表是概括原始信息最便捷的方式。
- 数无形时少直觉。
- 同一份数据集,在不同的尺度刻画上显示出来的图形反映的规律是不一样的。python将数据转化成图表,但结论是否正确需要由你保证。
2.3.6 变量分布可视化
单一变量分布可视化
python
plt.figure(figsize=(8, 8))
sns.barplot(data_train["employmentLength"].value_counts(dropna=False)[:20],
data_train["employmentLength"].value_counts(dropna=False).keys()[:20])
plt.show()
根绝y值不同可视化x某个特征的分布
- 首先查看类别型变量在不同y值上的分布
python
train_loan_fr = data_train.loc[data_train['isDefault'] == 1]
train_loan_nofr = data_train.loc[data_train['isDefault'] == 0]
python
fig, ((ax1, ax2), (ax3, ax4)) = plt.subplots(2, 2, figsize=(15, 8))
train_loan_fr.groupby('grade')['grade'].count().plot(kind='barh', ax=ax1, title='Count of grade fraud')
train_loan_nofr.groupby('grade')['grade'].count().plot(kind='barh', ax=ax2, title='Count of grade non-fraud')
train_loan_fr.groupby('employmentLength')['employmentLength'].count().plot(kind='barh', ax=ax3, title='Count of employmentLength fraud')
train_loan_nofr.groupby('employmentLength')['employmentLength'].count().plot(kind='barh', ax=ax4, title='Count of employmentLength non-fraud')
plt.show()
- 其次查看连续型变量在不同y值上的分布
python
fig, ((ax1, ax2)) = plt.subplots(1, 2, figsize=(15, 6))
data_train.loc[data_train['isDefault'] == 1] \
['loanAmnt'].apply(np.log) \
.plot(kind='hist',
bins=100,
title='Log Loan Amt - Fraud',
color='r',
xlim=(-3, 10),
ax= ax1)
data_train.loc[data_train['isDefault'] == 0] \
['loanAmnt'].apply(np.log) \
.plot(kind='hist',
bins=100,
title='Log Loan Amt - Not Fraud',
color='b',
xlim=(-3, 10),
ax=ax2)
<matplotlib.axes._subplots.AxesSubplot at 0x126a44b50>
python
total = len(data_train)
total_amt = data_train.groupby(['isDefault'])['loanAmnt'].sum().sum()
plt.figure(figsize=(12,5))
plt.subplot(121)##1代表行,2代表列,所以一共有2个图,1代表此时绘制第一个图。
plot_tr = sns.countplot(x='isDefault',data=data_train)#data_train'isDefault'这个特征每种类别的数量**
plot_tr.set_title("Fraud Loan Distribution \n 0: good user | 1: bad user", fontsize=14)
plot_tr.set_xlabel("Is fraud by count", fontsize=16)
plot_tr.set_ylabel('Count', fontsize=16)
for p in plot_tr.patches:
height = p.get_height()
plot_tr.text(p.get_x()+p.get_width()/2.,
height + 3,
'{:1.2f}%'.format(height/total*100),
ha="center", fontsize=15)
percent_amt = (data_train.groupby(['isDefault'])['loanAmnt'].sum())
percent_amt = percent_amt.reset_index()
plt.subplot(122)
plot_tr_2 = sns.barplot(x='isDefault', y='loanAmnt', dodge=True, data=percent_amt)
plot_tr_2.set_title("Total Amount in loanAmnt \n 0: good user | 1: bad user", fontsize=14)
plot_tr_2.set_xlabel("Is fraud by percent", fontsize=16)
plot_tr_2.set_ylabel('Total Loan Amount Scalar', fontsize=16)
for p in plot_tr_2.patches:
height = p.get_height()
plot_tr_2.text(p.get_x()+p.get_width()/2.,
height + 3,
'{:1.2f}%'.format(height/total_amt * 100),
ha="center", fontsize=15)
2.3.6 时间格式数据处理及查看
python
#转化成时间格式 issueDateDT特征表示数据日期离数据集中日期最早的日期(2007-06-01)的天数
data_train['issueDate'] = pd.to_datetime(data_train['issueDate'],format='%Y-%m-%d')
startdate = datetime.datetime.strptime('2007-06-01', '%Y-%m-%d')
data_train['issueDateDT'] = data_train['issueDate'].apply(lambda x: x-startdate).dt.days
python
#转化成时间格式
data_test_a['issueDate'] = pd.to_datetime(data_train['issueDate'],format='%Y-%m-%d')
startdate = datetime.datetime.strptime('2007-06-01', '%Y-%m-%d')
data_test_a['issueDateDT'] = data_test_a['issueDate'].apply(lambda x: x-startdate).dt.days
python
plt.hist(data_train['issueDateDT'], label='train');
plt.hist(data_test_a['issueDateDT'], label='test');
plt.legend();
plt.title('Distribution of issueDateDT dates');
#train 和 test issueDateDT 日期有重叠 所以使用基于时间的分割进行验证是不明智的
2.3.7 掌握透视图可以让我们更好的了解数据
python
#透视图 索引可以有多个,"columns(列)"是可选的,聚合函数aggfunc最后是被应用到了变量"values"中你所列举的项目上。
pivot = pd.pivot_table(data_train, index=['grade'], columns=['issueDateDT'], values=['loanAmnt'], aggfunc=np.sum)
python
pivot
| | loanAmnt |||||||||||||||||||||
| issueDateDT | 0 | 30 | 61 | 92 | 122 | 153 | 183 | 214 | 245 | 274 | ... | 3926 | 3957 | 3987 | 4018 | 4048 | 4079 | 4110 | 4140 | 4171 | 4201 |
| grade | | | | | | | | | | | | | | | | | | | | | |
| A | NaN | 53650.0 | 42000.0 | 19500.0 | 34425.0 | 63950.0 | 43500.0 | 168825.0 | 85600.0 | 101825.0 | ... | 13093850.0 | 11757325.0 | 11945975.0 | 9144000.0 | 7977650.0 | 6888900.0 | 5109800.0 | 3919275.0 | 2694025.0 | 2245625.0 |
| B | NaN | 13000.0 | 24000.0 | 32125.0 | 7025.0 | 95750.0 | 164300.0 | 303175.0 | 434425.0 | 538450.0 | ... | 16863100.0 | 17275175.0 | 16217500.0 | 11431350.0 | 8967750.0 | 7572725.0 | 4884600.0 | 4329400.0 | 3922575.0 | 3257100.0 |
| C | NaN | 68750.0 | 8175.0 | 10000.0 | 61800.0 | 52550.0 | 175375.0 | 151100.0 | 243725.0 | 393150.0 | ... | 17502375.0 | 17471500.0 | 16111225.0 | 11973675.0 | 10184450.0 | 7765000.0 | 5354450.0 | 4552600.0 | 2870050.0 | 2246250.0 |
| D | NaN | NaN | 5500.0 | 2850.0 | 28625.0 | NaN | 167975.0 | 171325.0 | 192900.0 | 269325.0 | ... | 11403075.0 | 10964150.0 | 10747675.0 | 7082050.0 | 7189625.0 | 5195700.0 | 3455175.0 | 3038500.0 | 2452375.0 | 1771750.0 |
| E | 7500.0 | NaN | 10000.0 | NaN | 17975.0 | 1500.0 | 94375.0 | 116450.0 | 42000.0 | 139775.0 | ... | 3983050.0 | 3410125.0 | 3107150.0 | 2341825.0 | 2225675.0 | 1643675.0 | 1091025.0 | 1131625.0 | 883950.0 | 802425.0 |
| F | NaN | NaN | 31250.0 | 2125.0 | NaN | NaN | NaN | 49000.0 | 27000.0 | 43000.0 | ... | 1074175.0 | 868925.0 | 761675.0 | 685325.0 | 665750.0 | 685200.0 | 316700.0 | 315075.0 | 72300.0 | NaN |
G | NaN | NaN | NaN | NaN | NaN | NaN | NaN | 24625.0 | NaN | NaN | ... | 56100.0 | 243275.0 | 224825.0 | 64050.0 | 198575.0 | 245825.0 | 53125.0 | 23750.0 | 25100.0 | 1000.0 |
---|
7 rows × 139 columns
2.3.8 用pandas_profiling生成数据报告
python
import pandas_profiling
python
pfr = pandas_profiling.ProfileReport(data_train)
pfr.to_file("./example.html")
2.4 总结
数据探索性分析是我们初步了解数据,熟悉数据为特征工程做准备的阶段,甚至很多时候EDA阶段提取出来的特征可以直接当作规则来用。可见EDA的重要性,这个阶段的主要工作还是借助于各个简单的统计量来对数据整体的了解,分析各个类型变量相互之间的关系,以及用合适的图形可视化出来直观观察。希望本节内容能给初学者带来帮助,更期待各位学习者对其中的不足提出建议。