Python3.5 Pandas模块缺失值处理和层次索引实例详解

本文实例讲述了Python3.5 Pandas模块缺失值处理和层次索引。分享给大家供大家参考，具体如下：

1、pandas缺失值处理

import numpy as np
    import pandas as pd
    from pandas import Series,DataFrame
    
    df3 = DataFrame([
      ["Tom",np.nan,456.67,"M"],
      ["Merry",34,345.56,np.nan],
      [np.nan,np.nan,np.nan,np.nan],
      ["John",23,np.nan,"M"],
      ["Joe",18,385.12,"F"]
    ],columns = ["name","age","salary","gender"])
    
    print(df3)
    print("=======判断NaN值=======")
    print(df3.isnull())
    print("=======判断非NaN值=======")
    print(df3.notnull())
    print("=======删除包含NaN值的行=======")
    print(df3.dropna())
    print("=======删除全部为NaN值的行=======")
    print(df3.dropna(how="all"))
    
    df3.ix[2,0] = "Gerry"    #修改第2行第0列的值
    print(df3)
    
    print("=======删除包含NaN值的列=======")
    print(df3.dropna(axis=1))
    
           

运行结果：

name age salary gender

0 Tom NaN 456.67 M

1 Merry 34.0 345.56 NaN

2 NaN NaN NaN NaN

3 John 23.0 NaN M

4 Joe 18.0 385.12 F

=判断NaN值=

name age salary gender

0 False True False False

1 False False False True

2 True True True True

3 False False True False

4 False False False False

=判断非NaN值=

name age salary gender

0 True False True True

1 True True True False

2 False False False False

3 True True False True

4 True True True True

=删除包含NaN值的行=

name age salary gender

4 Joe 18.0 385.12 F

=删除全部为NaN值的行=

name age salary gender

0 Tom NaN 456.67 M

1 Merry 34.0 345.56 NaN

3 John 23.0 NaN M

4 Joe 18.0 385.12 F

name age salary gender

0 Tom NaN 456.67 M

1 Merry 34.0 345.56 NaN

2 Gerry NaN NaN NaN

3 John 23.0 NaN M

4 Joe 18.0 385.12 F

=删除包含NaN值的列=

name

0 Tom

1 Merry

2 Gerry

3 John

4 Joe

import numpy as np
    import pandas as pd
    from pandas import Series,DataFrame
    
    df4 = DataFrame(np.random.randn(7,3))
    print(df4)
    
    df4.ix[:4,1] = np.nan    #第0至3行，第1列的数据
    df4.ix[:2,2] = np.nan
    print(df4)
    
    print(df4.fillna(0))    #将缺失值用传入的指定值0替换
    
    print(df4.fillna({1:0.5,2:-1}))   #将缺失值按照指定形式填充
    
           

运行结果：

0 1 2

0 -0.737618 -0.530302 -2.716457

1 0.810339 0.063028 -0.341343

2 0.070564 0.347308 -0.121137

3 -0.501875 -1.573071 -0.816077

4 -2.159196 -0.659185 -0.885185

5 0.175086 -0.954109 -0.758657

6 0.395744 -0.875943 0.950323

0 1 2

0 -0.737618 NaN NaN

1 0.810339 NaN NaN

2 0.070564 NaN NaN

3 -0.501875 NaN -0.816077

4 -2.159196 NaN -0.885185

5 0.175086 -0.954109 -0.758657

6 0.395744 -0.875943 0.950323

0 1 2

0 -0.737618 0.000000 0.000000

1 0.810339 0.000000 0.000000

2 0.070564 0.000000 0.000000

3 -0.501875 0.000000 -0.816077

4 -2.159196 0.000000 -0.885185

5 0.175086 -0.954109 -0.758657

6 0.395744 -0.875943 0.950323

0 1 2

0 -0.737618 0.500000 -1.000000

1 0.810339 0.500000 -1.000000

2 0.070564 0.500000 -1.000000

3 -0.501875 0.500000 -0.816077

4 -2.159196 0.500000 -0.885185

5 0.175086 -0.954109 -0.758657

6 0.395744 -0.875943 0.950323

2、pandas常用数学统计方法

import numpy as np
    import pandas as pd
    from pandas import Series,DataFrame
    
    #pandas常用数学统计方法
    
    arr = np.array([
      [98.5,89.5,88.5],
      [98.5,85.5,88],
      [70,85,60],
      [80,85,82]
    ])
    df1 = DataFrame(arr,columns=["语文","数学","英语"])
    print(df1)
    print("=======针对列计算总统计值=======")
    print(df1.describe())
    print("=======默认计算各列非NaN值个数=======")
    print(df1.count())
    print("=======计算各行非NaN值个数=======")
    print(df1.count(axis=1))
    
    
           

运行结果：

语文 数学 英语

0 98.5 89.5 88.5

1 98.5 85.5 88.0

2 70.0 85.0 60.0

3 80.0 85.0 82.0

=针对列计算总统计值=

语文 数学 英语

count 4.000000 4.000000 4.000000

mean 86.750000 86.250000 79.625000

std 14.168627 2.179449 13.412525

min 70.000000 85.000000 60.000000

25% 77.500000 85.000000 76.500000

50% 89.250000 85.250000 85.000000

75% 98.500000 86.500000 88.125000

max 98.500000 89.500000 88.500000

=默认计算各列非NaN值个数=

语文 4

数学 4

英语 4

dtype: int64

=计算各行非NaN值个数=

0 3

1 3

2 3

3 3

dtype: int64

import numpy as np
    import pandas as pd
    from pandas import Series,DataFrame、
    
    #2.pandas相关系数与协方差
    df2 = DataFrame({
      "GDP":[12,23,34,45,56],
      "air_temperature":[23,25,26,27,30],
      "year":["2001","2002","2003","2004","2005"]
    })
    
    print(df2)
    print("=========相关系数========")
    print(df2.corr())
    print("=========协方差========")
    print(df2.cov())
    print("=========两个量之间的相关系数========")
    print(df2["GDP"].corr(df2["air_temperature"]))
    print("=========两个量之间协方差========")
    print(df2["GDP"].cov(df2["air_temperature"]))
    
    
           

运行结果：

GDP air_temperature year

0 12 23 2001

1 23 25 2002

2 34 26 2003

3 45 27 2004

4 56 30 2005

=相关系数

GDP air_temperature

GDP 1.000000 0.977356

air_temperature 0.977356 1.000000

=协方差

GDP air_temperature

GDP 302.5 44.0

air_temperature 44.0 6.7

=两个量之间的相关系数

0.97735555485

=两个量之间协方差

44.0

import numpy as np
    import pandas as pd
    from pandas import Series,DataFrame
    
    #3.pandas唯一值、值计数及成员资格
    
    df3 = DataFrame({
      "order_id":["1001","1002","1003","1004","1005"],
      "member_id":["m01","m01","m02","m01","m02",],
      "order_amt":[345,312.2,123,250.2,235]
    })
    
    print(df3)
    
    print("=========去重后的数组=========")
    print(df3["member_id"].unique())
    
    print("=========值出现的频率=========")
    print(df3["member_id"].value_counts())
    
    print("=========成员资格=========")
    df3 = df3["member_id"]
    mask = df3.isin(["m01"])
    print(mask)
    print(df3[mask])
    
    
           

运行结果：

member_id order_amt order_id

0 m01 345.0 1001

1 m01 312.2 1002

2 m02 123.0 1003

3 m01 250.2 1004

4 m02 235.0 1005

=去重后的数组=

[‘m01’ ‘m02’]

=值出现的频率=

m01 3

m02 2

Name: member_id, dtype: int64

=成员资格=

0 True

1 True

2 False

3 True

4 False

Name: member_id, dtype: bool

0 m01

1 m01

3 m01

Name: member_id, dtype: object

3、pandas层次索引

import numpy as np
    import pandas as pd
    from pandas import Series,DataFrame
    
    #3.pandas层次索引
    data = Series([998.4,6455,5432,9765,5432],
           index=[["2001","2001","2001","2002","2002"],
           ["苹果","香蕉","西瓜","苹果","西瓜"]]
           )
    print(data)
    
    df4 = DataFrame({
      "year":[2001,2001,2002,2002,2003],
      "fruit":["apple","banana","apple","banana","apple"],
      "production":[2345,5632,3245,6432,4532],
      "profits":[245.6,432.7,534.1,354,467.8]
    })
    
    print(df4)
    print("=======层次化索引=======")
    df4 = df4.set_index(["year","fruit"])
    print(df4)
    print("=======依照索引取值=======")
    print(df4.ix[2002,"apple"])
    print("=======依照层次化索引统计数据=======")
    print(df4.sum(level="year"))
    print(df4.mean(level="fruit"))
    print(df4.min(level=["year","fruit"]))
    
    
           

运行结果：

2001 苹果 998.4

香蕉 6455.0

西瓜 5432.0

2002 苹果 9765.0

西瓜 5432.0

dtype: float64

fruit production profits year

0 apple 2345 245.6 2001

1 banana 5632 432.7 2001

2 apple 3245 534.1 2002

3 banana 6432 354.0 2002

4 apple 4532 467.8 2003

=层次化索引=

production profits

year fruit

2001 apple 2345 245.6

banana 5632 432.7

2002 apple 3245 534.1

banana 6432 354.0

2003 apple 4532 467.8

=依照索引取值=

production 3245.0

profits 534.1

Name: (2002, apple), dtype: float64

=依照层次化索引统计数据=

production profits

year

2001 7977 678.3

2002 9677 888.1

2003 4532 467.8

production profits

fruit

apple 3374 415.833333

banana 6032 393.350000

production profits

year fruit

2001 apple 2345 245.6

banana 5632 432.7

2002 apple 3245 534.1

banana 6432 354.0

2003 apple 4532 467.8

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