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I have some categorical features in my data along with continuous ones. Is it a good or absolutely bad idea to hot encode category features to find correlation of it to labels along with other continuous creatures?

2
  • Binary or n-ary categorical? Ordered or unordered?
    – smci
    Feb 13, 2018 at 22:37
  • "correlation of it to labels" => correlation of it to a categorical response variable (how many values?)
    – smci
    Feb 13, 2018 at 22:38

3 Answers 3

49

There is a way to calculate the correlation coefficient without one-hot encoding the category variable. Cramers V statistic is one method for calculating the correlation of categorical variables. It can be calculated as follows. The following link is helpful. Using pandas, calculate Cramér's coefficient matrix For variables with other continuous values, you can categorize by using cut of pandas.

import numpy as np
import pandas as pd
import scipy.stats as ss
import seaborn as sns

print('Pandas version:', pd.__version__)
# Pandas version: 1.3.0

tips = sns.load_dataset("tips")

tips["total_bill_cut"] = pd.cut(tips["total_bill"],
                                np.arange(0, 55, 5),
                                include_lowest=True,
                                right=False)

def cramers_v(confusion_matrix):
    """ calculate Cramers V statistic for categorial-categorial association.
        uses correction from Bergsma and Wicher,
        Journal of the Korean Statistical Society 42 (2013): 323-328
    """
    chi2 = ss.chi2_contingency(confusion_matrix)[0]
    n = confusion_matrix.sum()
    phi2 = chi2 / n
    r, k = confusion_matrix.shape
    phi2corr = max(0, phi2 - ((k-1)*(r-1))/(n-1))
    rcorr = r - ((r-1)**2)/(n-1)
    kcorr = k - ((k-1)**2)/(n-1)
    return np.sqrt(phi2corr / min((kcorr-1), (rcorr-1)))

confusion_matrix = pd.crosstab(tips["day"], tips["time"])
cramers_v(confusion_matrix.values)
# Out[2]: 0.9386619340722221

confusion_matrix = pd.crosstab(tips["total_bill_cut"], tips["time"])
cramers_v(confusion_matrix.values)
# Out[3]: 0.1649870749498837

please note the .as_matrix() is deprecated in pandas since verison 0.23.0 . use .values instead

10
  • 4
    Thanks for reply, but my question was not how to calculate the correlation between categorical features. Question is: Is it a good idea or terribly bad idea to use hot encoders for categorical features and then using the features including categorical & continuous ones to calculate correlation. Sep 30, 2017 at 3:04
  • 6
    I am sorry for misunderstanding the question. I think there is no problem to calculate the correlation between one hot encoding feature and another continuous feature, but I think that the correlation coefficient will be a value only for one item of the category.
    – Keiku
    Sep 30, 2017 at 3:14
  • Thank you very much Sep 30, 2017 at 16:39
  • however, as me being a newbie... would you mind explaining a little bit about that, why would it use only one item from the category. Sep 30, 2017 at 16:41
  • 3
    Sorry for lack of explanation. Suppose you have one-hot encoded an item of gender. Gender items are separated into male and female and other variables. The male variable is a flag of 0 or 1, whether it is male or not. I think it is possible to correlate with these flag variables. In general, however, correlation coefficients for categorical variables use statistical analysis methods using statistics such as frequency of categories of items before one-hot encoding. See also stats.stackexchange.com/questions/102778/…
    – Keiku
    Oct 1, 2017 at 3:38
2

I found phik library quite useful in calculating correlation between categorical and interval features. This is also useful for binning numerical features. Try this once: phik documentation

0

I was looking to do same thing in BigQuery. For numeric features you can use built in CORR(x,y) function. For categorical features, you can calculate it as: cardinality (cat1 x cat2) / max (cardinality(cat1), cardinality(cat2). Which translates to following SQL:

SELECT 
COUNT(DISTINCT(CONCAT(cat1, cat2))) / GREATEST (COUNT(DISTINCT(cat1)), COUNT(DISTINCT(cat2))) as cat1_2,
COUNT(DISTINCT(CONCAT(cat1, cat3))) / GREATEST (COUNT(DISTINCT(cat1)), COUNT(DISTINCT(cat3))) as cat1_3,
....
FROM ...

Higher number means lower correlation.

I used following python script to generate SQL:

import itertools

arr = range(1,10)

query = ',\n'.join(list('COUNT(DISTINCT(CONCAT({a}, {b}))) / GREATEST (COUNT(DISTINCT({a})), COUNT(DISTINCT({b}))) as cat{a}_{b}'.format(a=a,b=b) 
  for (a,b) in itertools.combinations(arr,2)))
query = 'SELECT \n ' + query + '\n FROM  `...`;'
print (query)

It should be straightforward to do same thing in numpy.

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