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Neha Kumawat

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Often in real-time, data includes the text columns, which are repetitive. Features like gender, country, and codes are always repetitive. These are the examples for categorical data.

Categorical variables can take on only a limited, and usually fixed number of possible values. Besides the fixed length, categorical data might have an order but cannot perform numerical operation. Categorical are a Pandas data type.

The categorical data type is useful in the following cases −

- A string variable consisting of only a few different values. Converting such a string variable to a categorical variable will save some memory.

A string variable consisting of only a few different values. Converting such a string variable to a categorical variable will save some memory.

- The lexical order of a variable is not the same as the logical order (“one”, “two”, “three”). By converting to a categorical and specifying an order on the categories, sorting and min/max will use the logical order instead of the lexical order.

The lexical order of a variable is not the same as the logical order (“one”, “two”, “three”). By converting to a categorical and specifying an order on the categories, sorting and min/max will use the logical order instead of the lexical order.

- As a signal to other python libraries that this column should be treated as a categorical variable (e.g. to use suitable statistical methods or plot types).

As a signal to other python libraries that this column should be treated as a categorical variable (e.g. to use suitable statistical methods or plot types).

Categorical object can be created in multiple ways. The different ways have been described below −

By specifying the dtype as "category" in pandas object creation.

```
import pandas as pd
s = pd.Series(["a","b","c","a"], dtype="category")
print s
```

Its output is as follows −

```
0 a
1 b
2 c
3 a
dtype: category
Categories (3, object): [a, b, c]
```

The number of elements passed to the series object is four, but the categories are only three. Observe the same in the output Categories.

Using the standard pandas Categorical constructor, we can create a category object.

```
pandas.Categorical(values, categories, ordered)
```

Let’s take an example −

```
import pandas as pd
cat = pd.Categorical(['a', 'b', 'c', 'a', 'b', 'c'])
print cat
```

Its output is as follows −

```
[a, b, c, a, b, c]
Categories (3, object): [a, b, c]
```

Let’s have another example −

```
import pandas as pd
cat = cat=pd.Categorical(['a','b','c','a','b','c','d'], ['c', 'b', 'a'])
print cat
```

Its output is as follows −

```
[a, b, c, a, b, c, NaN]
Categories (3, object): [c, b, a]
```

Here, the second argument signifies the categories. Thus, any value which is not present in the categories will be treated as NaN.

Now, take a look at the following example −

```
import pandas as pd
cat = cat=pd.Categorical(['a','b','c','a','b','c','d'], ['c', 'b', 'a'],ordered=True)
print cat
```

Its output is as follows −

```
[a, b, c, a, b, c, NaN]
Categories (3, object): [c < b < a]
```

Logically, the order means that, a is greater than b and b is greater than c.

Using the .describe() command on the categorical data, we get similar output to a Series or DataFrame of the type string.

```
import pandas as pd
import numpy as np
cat = pd.Categorical(["a", "c", "c", np.nan], categories=["b", "a", "c"])
df = pd.DataFrame({"cat":cat, "s":["a", "c", "c", np.nan]})
print df.describe()
print df["cat"].describe()
```

Its output is as follows −

```
cat s
count 3 3
unique 2 2
top c c
freq 2 2
count 3
unique 2
top c
freq 2
Name: cat, dtype: object
```

obj.cat.categories command is used to get the categories of the object.

```
import pandas as pd
import numpy as np
s = pd.Categorical(["a", "c", "c", np.nan], categories=["b", "a", "c"])
print s.categories
```

Its output is as follows −

```
Index([u'b', u'a', u'c'], dtype='object')
```

obj.ordered command is used to get the order of the object.

```
import pandas as pd
import numpy as np
cat = pd.Categorical(["a", "c", "c", np.nan], categories=["b", "a", "c"])
print cat.ordered
```

Its output is as follows −

```
False
```

The function returned false because we haven't specified any order.

Renaming categories is done by assigning new values to the series.cat.categoriesseries.cat.categories property.

```
import pandas as pd
s = pd.Series(["a","b","c","a"], dtype="category")
s.cat.categories = ["Group %s" % g for g in s.cat.categories]
print s.cat.categories
```

Its output is as follows −

```
Index([u'Group a', u'Group b', u'Group c'], dtype='object')
```

Initial categories [a,b,c] are updated by the s.cat.categories property of the object.

Using the Categorical.add.categories() method, new categories can be appended.

```
import pandas as pd
s = pd.Series(["a","b","c","a"], dtype="category")
s = s.cat.add_categories([4])
print s.cat.categories
```

Its output is as follows −

```
Index([u'a', u'b', u'c', 4], dtype='object')
```

Using the Categorical.remove_categories() method, unwanted categories can be removed.

```
import pandas as pd
s = pd.Series(["a","b","c","a"], dtype="category")
print ("Original object:")
print s
print ("After removal:")
print s.cat.remove_categories("a")
```

Its output is as follows −

```
Original object:
0 a
1 b
2 c
3 a
dtype: category
Categories (3, object): [a, b, c]
After removal:
0 NaN
1 b
2 c
3 NaN
dtype: category
Categories (2, object): [b, c]
```

Comparing categorical data with other objects is possible in three cases −

- comparing equality (== and !=) to a list-like object (list, Series, array, ...) of the same length as the categorical data.

comparing equality (== and !=) to a list-like object (list, Series, array, ...) of the
same length as the categorical data.

- all comparisons (==, !=, >, >=, <, and <=) of categorical data to another categorical Series, when ordered==True and the categories are the same.

all comparisons (==, !=, >, >=, <, and <=) of categorical data to another
categorical Series, when ordered==True and the categories are the same.

- all comparisons of a categorical data to a scalar.

all comparisons of a categorical data to a scalar.

Take a look at the following example −

```
import pandas as pd
cat = pd.Series([1,2,3]).astype("category", categories=[1,2,3], ordered=True)
cat1 = pd.Series([2,2,2]).astype("category", categories=[1,2,3], ordered=True)
print cat>cat1
```

Its output is as follows −

```
0 False
1 False
2 True
dtype: bool
```

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