Python Pandas: how to turn a DataFrame with “factors” into a design matrix for linear regression?

If memory servies me, in R there is a data type called factor which when used within a DataFrame can be automatically unpacked into the necessary columns of a regression design matrix. For example, a factor containing True/False/Maybe values would be transformed into:

``````1 0 0
0 1 0
or
0 0 1
``````

for the purpose of using lower level regression code. Is there a way to achieve something similar using the pandas library? I see that there is some regression support within Pandas, but since I have my own customised regression routines I am really interested in the construction of the design matrix (a 2d numpy array or matrix) from heterogeneous data with support for mapping back and fort between columns of the numpy object and the Pandas DataFrame from which it is derived.

Update: Here is an example of a data matrix with heterogeneous data of the sort I am thinking of (the example comes from the Pandas manual):

``````>>> df2 = DataFrame({'a' : ['one', 'one', 'two', 'three', 'two', 'one', 'six'],'b' : ['x', 'y', 'y', 'x', 'y', 'x', 'x'],'c' : np.random.randn(7)})
>>> df2
a  b         c
0    one  x  0.000343
1    one  y -0.055651
2    two  y  0.249194
3  three  x -1.486462
4    two  y -0.406930
5    one  x -0.223973
6    six  x -0.189001
>>>
``````

The 'a' column should be converted into 4 floating point columns (in spite of the meaning, there are only four unique atoms), the 'b' column can be converted to a single floating point column, and the 'c' column should be an unmodified final column in the design matrix.

Thanks,

SetJmp

-
It's not clear what you mean by "The 'a' column should be converted into 4 floating point columns" ... Do you mean 4 floating point values? I don't see how splitting the first columns into mutliple columns will allow a design matrix. My understanding is that the first two columns here are categorical variables. Do you mean that you want 4 binary variables, which are equal to 1 only if that row of the data had that first-column-categorical number? –  Mr. F Apr 17 '12 at 21:36
Converting a factor with k levels into k distinct columns/variables is called discretization. –  smci Mar 10 '13 at 6:20

There is a new module called patsy that solves this problem. The quickstart linked below solves exactly the problem described above in a couple lines of code.

Here is an example usage:

``````import pandas
import patsy

#salary2.txt is a re-formatted data set from the textbook
#Introductory Econometrics: A Modern Approach
#by Jeffrey Wooldridge
y,X = patsy.dmatrices("sl ~ 1+sx+rk+yr+dg+yd",dataFrame)
#X.design_info provides the meta data behind the X columns
print X.design_info
``````

generates:

``````> DesignInfo(['Intercept',
>             'sx[T.male]',
>             'rk[T.associate]',
>             'rk[T.full]',
>             'dg[T.masters]',
>             'yr',
>             'yd'],
>            term_slices=OrderedDict([(Term([]), slice(0, 1, None)), (Term([EvalFactor('sx')]), slice(1, 2, None)),
> (Term([EvalFactor('rk')]), slice(2, 4, None)),
> (Term([EvalFactor('dg')]), slice(4, 5, None)),
> (Term([EvalFactor('yr')]), slice(5, 6, None)),
> (Term([EvalFactor('yd')]), slice(6, 7, None))]),
>            builder=<patsy.build.DesignMatrixBuilder at 0x10f169510>)
``````
-
``````import pandas
import numpy as np

num_rows = 7;
df2 = pandas.DataFrame(
{
'a' : ['one', 'one', 'two', 'three', 'two', 'one', 'six'],
'b' : ['x', 'y', 'y', 'x', 'y', 'x', 'x'],
'c' : np.random.randn(num_rows)
}
)

a_attribute_list = ['one', 'two', 'three', 'six']; #Or use list(set(df2['a'].values)), but that doesn't guarantee ordering.
b_attribute_list = ['x','y']

a_membership = [ np.reshape(np.array(df2['a'].values == elem).astype(np.float64),   (num_rows,1)) for elem in a_attribute_list ]
b_membership = [ np.reshape((df2['b'].values == elem).astype(np.float64), (num_rows,1)) for elem in b_attribute_list ]
c_column =  np.reshape(df2['c'].values, (num_rows,1))

design_matrix_a = np.hstack(tuple(a_membership))
design_matrix_b = np.hstack(tuple(b_membership))
design_matrix = np.hstack(( design_matrix_a, design_matrix_b, c_column ))

# Print out the design matrix to see that it's what you want.
for row in design_matrix:
print row
``````

I get this output:

``````[ 1.          0.          0.          0.          1.          0.          0.36444463]
[ 1.          0.          0.          0.          0.          1.         -0.63610264]
[ 0.          1.          0.          0.          0.          1.          1.27876991]
[ 0.          0.          1.          0.          1.          0.          0.69048607]
[ 0.          1.          0.          0.          0.          1.          0.34243241]
[ 1.          0.          0.          0.          1.          0.         -1.17370649]
[ 0.          0.          0.          1.          1.          0.         -0.52271636]
``````

So, the first column is an indicator for the DataFrame locations that were 'one', the second column is an indicator for the DataFrame locations that were 'two', and so on. Columns 4 and 5 are indicators of DataFrame locations that were 'x' and 'y', respectively, and the final column is just the random data.

-
The values attribute returns nested ndarray's where the innermost array holds dtype=object. The factors are converted into strings, and the float data are floats within this inner array. –  SetJmp Apr 17 '12 at 19:49
It doesn't work like that for me. I edited the question above to illustrate. –  Mr. F Apr 17 '12 at 19:53
It works for you because in your example all the data happens to be float type. However with string data present I get a different structure as the return type. What I am looking for as a logical mapping that transforms the data frame into a 2d ndarray of floats that could then be put into a low level solver expecting design matrix X and dependent variables y. By low level, I mean speudoinverse code that only knows how to work on 2d float ndarrays (not recarrays). This lower level encoding is what is referred to as a "design matrix" in statistics references. –  SetJmp Apr 17 '12 at 20:40
Here is a discussion highlighting how R code translates factors into a design matrix "behind the scenes" before sending to low lever solver code. Though the example factors has only 2 levels, I believe the correct behaviour can be expected for 3 or more levels.r.789695.n4.nabble.com/… –  SetJmp Apr 17 '12 at 20:47
It seems that a `numpy` `recarray` might be appropriate. I'll look at whether `values` can be easily exported to a `recarray` –  Mr. F Apr 17 '12 at 21:00

`patsy.dmatrices` may in many cases work well. If you just have a vector - a `pandas.Series` - then the below code may work producing a degenerate design matrix and without an intercept column.

``````def factor(series):
"""Convert a pandas.Series to pandas.DataFrame design matrix.

Parameters
----------
series : pandas.Series
Vector with categorical values

Returns
-------
pandas.DataFrame
Design matrix with ones and zeroes.

--------
patsy.dmatrices : Converts categorical columns to numerical

Examples
--------
>>> import pandas as pd
>>> design = factor(pd.Series(['a', 'b', 'a']))
>>> design.ix[0,'[a]']
1.0
>>> list(design.columns)
['[a]', '[b]']

"""
levels = list(set(series))
design_matrix = np.zeros((len(series), len(levels)))
for row_index, elem in enumerate(series):
design_matrix[row_index, levels.index(elem)] = 1
name = series.name or ""
columns = map(lambda level: "%s[%s]" % (name, level), levels)
df = pd.DataFrame(design_matrix, index=series.index,
columns=columns)
return df
``````
-

Pandas 0.13.1 from February 3, 2014 has a method:

``````>>> pd.Series(['one', 'one', 'two', 'three', 'two', 'one', 'six']).str.get_dummies()
one  six  three  two
0    1    0      0    0
1    1    0      0    0
2    0    0      0    1
3    0    0      1    0
4    0    0      0    1
5    1    0      0    0
6    0    1      0    0
``````
-