I have a dataframe in pandas where each column has different value range. For example:


A     B   C
1000  10  0.5
765   5   0.35
800   7   0.09

Any idea how I can normalize the columns of this dataframe where each value is between 0 and 1?

My desired output is:

A     B    C
1     1    1
0.765 0.5  0.7
0.8   0.7  0.18(which is 0.09/0.5)
  • 1
    there is an apply function, e.g. frame.apply(f, axis=1) where f is a function that does something with a row... – tschm Oct 16 '14 at 22:30
  • 1
    Normalization might not be the most appropriate wording, since scikit-learn documentation defines it as "the process of scaling individual samples to have unit norm" (i.e. row by row, if I get it correctly). – Skippy le Grand Gourou Mar 5 '19 at 16:58
  • I do not get it, why min_max scaling is considered normalization! normal has got to have meaning in the sense of normal distribution with mean zero and variance 1. – OverFlow Police Apr 21 '19 at 2:21
  • 3
    If you are visiting this question in 2020 or later, look at answer by @Poudel, you get different answer of normalizing if you use pandas vs sklearn. – Bhishan Poudel Jan 29 '20 at 20:10
  • @Poudel is this due to the ddof argument? – fffrost Apr 4 '20 at 20:26

20 Answers 20


You can use the package sklearn and its associated preprocessing utilities to normalize the data.

import pandas as pd
from sklearn import preprocessing

x = df.values #returns a numpy array
min_max_scaler = preprocessing.MinMaxScaler()
x_scaled = min_max_scaler.fit_transform(x)
df = pd.DataFrame(x_scaled)

For more information look at the scikit-learn documentation on preprocessing data: scaling features to a range.

  • 57
    i think this will get rid of the column names, which might be one of the reasons op is using dataframes in the first place. – pietz Jan 16 '17 at 21:02
  • 59
    This will normalize the rows and not the columns, unless you transpose it first. To do what the Q asks for: pd.DataFrame(min_max_scaler.fit_transform(df.T), columns=df.columns, index=df.index) – hobs Jan 20 '17 at 23:47
  • 30
    @pietz to keep column names, see this post. Basically replace the last line with , df=pandas.DataFrame(x_scaled, columns=df.columns) – ijoseph Jun 26 '17 at 18:52
  • 5
    @hobs This is not correct. Sandman's code normalizes column-wise and per-column. You get the wrong result if you transpose. – petezurich Apr 1 '18 at 14:10
  • 9
    @petezurich It looks like Sandman or Praveen corrected their code. Unfortunately, it's not possible to correct comments ;) – hobs Apr 3 '18 at 21:25

one easy way by using Pandas: (here I want to use mean normalization)


to use min-max normalization:


Edit: To address some concerns, need to say that Pandas automatically applies colomn-wise function in the code above.

  • 24
    i like this one. it's short, it's expressive and it preserves the header information. but i think you need to subtract the min in the denominator as well. – pietz Jan 16 '17 at 20:49
  • 1
    This solution is beautiful, concise, and wrong. The mean() and str() methods don't return a dataframe, but a series. That produces ridiculous error messages ("ValueError: cannot reindex from a duplicate axis") To get something that works, you have to uglify it in the following way: normalized_df=(df-df.mean().to_frame().T)/df.std().to_frame().T – MightyCurious Oct 6 '18 at 18:40
  • 8
    I don't think it's wrong. Works beautifully for me - I don't think mean() and std() need to return a dataframe in order for this to work and your error message does not imply that them not being a dataframe is a problem. – Strandtasche Oct 23 '18 at 9:19
  • 7
    Also worked for me beautifully. @Nguaial you might be trying this on a numpy matrix in which case the result would be what you said. But for Pandas dataframes, the min, max, ... measures apply column-wise by default. – Auxiliary Aug 22 '19 at 14:38
  • 1
    this is a good solution, but you need a lot of less-beautiful checks to avoid divide by zero errors – Teddy Ward May 7 '20 at 21:26

Based on this post: https://stats.stackexchange.com/questions/70801/how-to-normalize-data-to-0-1-range

You can do the following:

def normalize(df):
    result = df.copy()
    for feature_name in df.columns:
        max_value = df[feature_name].max()
        min_value = df[feature_name].min()
        result[feature_name] = (df[feature_name] - min_value) / (max_value - min_value)
    return result

You don't need to stay worrying about whether your values are negative or positive. And the values should be nicely spread out between 0 and 1.

  • 10
    Be careful when min and max values are same, your denominator is 0 and you will get a NaN value. – Hrushikesh Dhumal Feb 1 '19 at 6:02
  • @HrushikeshDhumal, No need to normalize then, Since all values would be equal. – Appaji Chintimi Oct 26 '20 at 9:13
  • @AppajiChintimi, this solution applies to entire data, if you haven't done sanity check you could run into trouble. – Hrushikesh Dhumal Oct 29 '20 at 23:54

Your problem is actually a simple transform acting on the columns:

def f(s):
    return s/s.max()

frame.apply(f, axis=0)

Or even more terse:

   frame.apply(lambda x: x/x.max(), axis=0)
  • 3
    The lambda one is the best :-) – Abu Shoeb Dec 8 '18 at 23:49
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    isn't this supposed to be axis=1 since the question is column wise normalization? – Nguai al Apr 26 '19 at 23:27
  • 3
    No, from the docs: axis [...] 0 or 'index': apply function to each column. The default is actually axis=0 so this one-liner can be written even shorter :-) Thanks @tschm. – jorijnsmit Apr 11 '20 at 15:01
  • This is only correct if the min is 0, which isn't something that you should really assume – QFSW Nov 21 '20 at 17:19
  • My example was meant to illustrate how to apply functions on columns of dataframes. Obviously, as always, you need to pay attention to corner cases, e.g. here the max could be zero and result in an issue. Not sure I understand @QFSW. – tschm Nov 22 '20 at 18:28

If you like using the sklearn package, you can keep the column and index names by using pandas loc like so:

from sklearn.preprocessing import MinMaxScaler

scaler = MinMaxScaler() 
scaled_values = scaler.fit_transform(df) 
df.loc[:,:] = scaled_values

You can create a list of columns that you want to normalize

column_names_to_normalize = ['A', 'E', 'G', 'sadasdsd', 'lol']
x = df[column_names_to_normalize].values
x_scaled = min_max_scaler.fit_transform(x)
df_temp = pd.DataFrame(x_scaled, columns=column_names_to_normalize, index = df.index)
df[column_names_to_normalize] = df_temp

Your Pandas Dataframe is now normalized only at the columns you want

However, if you want the opposite, select a list of columns that you DON'T want to normalize, you can simply create a list of all columns and remove that non desired ones

column_names_to_not_normalize = ['B', 'J', 'K']
column_names_to_normalize = [x for x in list(df) if x not in column_names_to_not_normalize ]

Simple is Beautiful:

df["A"] = df["A"] / df["A"].max()
df["B"] = df["B"] / df["B"].max()
df["C"] = df["C"] / df["C"].max()
  • 6
    Note, that OP asked for [0..1] range and this solution scales to [-1..1] range. Try this with the array [-10, 10]. – Alexander Sosnovshchenko Apr 28 '18 at 9:20
  • 3
    @AlexanderSosnovshchenko not really. Basil Musa is assuming the OP's matrix is always non-negative, that's why he has given this solution. If some column has a negative entry then this code does NOT normalize to the [-1,1] range. Try it with the array [-5, 10]. The correct way to normalize to [0,1] with negative values was given by Cina's answer df["A"] = (df["A"]-df["A"].min()) / (df["A"].max()-df["A"].min()) – Pepe Mandioca Nov 9 '18 at 13:24
  • simple AND explicit – joshi123 Dec 12 '18 at 16:17
  • Perhaps even simpler: df /= df.max() - assuming the goal is to normalise each and every column, individually. – n1k31t4 May 31 '20 at 22:26

Detailed Example of Normalization Methods

  • Pandas normalization (unbiased)
  • Sklearn normalization (biased)
  • Does biased-vs-unbiased affect Machine Learning?
  • Mix-max scaling

References: Wikipedia: Unbiased Estimation of Standard Deviation

Example Data

import pandas as pd
df = pd.DataFrame({
   A    B  C
0  1  100  a
1  2  300  b
2  3  500  c

Normalization using pandas (Gives unbiased estimates)

When normalizing we simply subtract the mean and divide by standard deviation.

df.iloc[:,0:-1] = df.iloc[:,0:-1].apply(lambda x: (x-x.mean())/ x.std(), axis=0)
     A    B  C
0 -1.0 -1.0  a
1  0.0  0.0  b
2  1.0  1.0  c

Normalization using sklearn (Gives biased estimates, different from pandas)

If you do the same thing with sklearn you will get DIFFERENT output!

import pandas as pd

from sklearn.preprocessing import StandardScaler
scaler = StandardScaler()

df = pd.DataFrame({
df.iloc[:,0:-1] = scaler.fit_transform(df.iloc[:,0:-1].to_numpy())
          A         B  C
0 -1.224745 -1.224745  a
1  0.000000  0.000000  b
2  1.224745  1.224745  c

Does Biased estimates of sklearn makes Machine Learning Less Powerful?


The official documentation of sklearn.preprocessing.scale states that using biased estimator is UNLIKELY to affect the performance of machine learning algorithms and we can safely use them.

From official documentation:

We use a biased estimator for the standard deviation, equivalent to numpy.std(x, ddof=0). Note that the choice of ddof is unlikely to affect model performance.

What about MinMax Scaling?

There is no Standard Deviation calculation in MinMax scaling. So the result is same in both pandas and scikit-learn.

import pandas as pd
df = pd.DataFrame({
(df - df.min()) / (df.max() - df.min())
     A    B
0  0.0  0.0
1  0.5  0.5
2  1.0  1.0

# Using sklearn
from sklearn.preprocessing import MinMaxScaler

scaler = MinMaxScaler() 
arr_scaled = scaler.fit_transform(df) 

[[0.  0. ]
 [0.5 0.5]
 [1.  1. ]]

df_scaled = pd.DataFrame(arr_scaled, columns=df.columns,index=df.index)
     A    B
0  0.0  0.0
1  0.5  0.5
2  1.0  1.0

I think that a better way to do that in pandas is just

df = df/df.max().astype(np.float64)

Edit If in your data frame negative numbers are present you should use instead

df = df/df.loc[df.abs().idxmax()].astype(np.float64)
  • 1
    In case all values of a column are zero this won't work – ahajib Sep 2 '15 at 23:23
  • dividing the current value by the max will not give you a correct normalisation unless the min is 0. – pietz Jan 16 '17 at 21:16
  • I agree, but that is what the OT was asking for (see his example) – Daniele Feb 21 '17 at 14:33

The solution given by Sandman and Praveen is very well. The only problem with that if you have categorical variables in other columns of your data frame this method will need some adjustments.

My solution to this type of issue is following:

 from sklearn import preprocesing
 x = pd.concat([df.Numerical1, df.Numerical2,df.Numerical3])
 min_max_scaler = preprocessing.MinMaxScaler()
 x_scaled = min_max_scaler.fit_transform(x)
 x_new = pd.DataFrame(x_scaled)
 df = pd.concat([df.Categoricals,x_new])
  • 2
    This answer is useful because most examples on the internet apply one scaler to all the columns, whereas this actually addresses the situation where one scaler, say the MinMaxScaler, should not apply to all columns. – demongolem Sep 10 '18 at 17:07

You might want to have some of columns being normalized and the others be unchanged like some of regression tasks which data labels or categorical columns are unchanged So I suggest you this pythonic way (It's a combination of @shg and @Cina answers ):

features_to_normalize = ['A', 'B', 'C']
# could be ['A','B'] 

df[features_to_normalize] = df[features_to_normalize].apply(lambda x:(x-x.min()) / (x.max()-x.min()))

It is only simple mathematics. The answer should as simple as below.

normed_df = (df - df.min()) / (df.max() - df.min())
df_normalized = df / df.max(axis=0)

This is how you do it column-wise using list comprehension:

[df[col].update((df[col] - df[col].min()) / (df[col].max() - df[col].min())) for col in df.columns]
def normalize(x):
        x = x/np.linalg.norm(x,ord=1)
        return x
    except :
data = pd.DataFrame.apply(data,normalize)

From the document of pandas,DataFrame structure can apply an operation (function) to itself .

DataFrame.apply(func, axis=0, broadcast=False, raw=False, reduce=None, args=(), **kwds)

Applies function along input axis of DataFrame. Objects passed to functions are Series objects having index either the DataFrame’s index (axis=0) or the columns (axis=1). Return type depends on whether passed function aggregates, or the reduce argument if the DataFrame is empty.

You can apply a custom function to operate the DataFrame .

  • 3
    It would be good to explain, why your code solves the OPs problem, so people can adapt the strategy rather than just copy your code. Please read How do I write a good answer? – Mr. T Apr 13 '18 at 9:53

The following function calculates the Z score:

def standardization(dataset):
  """ Standardization of numeric fields, where all values will have mean of zero 
  and standard deviation of one. (z-score)

    dataset: A `Pandas.Dataframe` 
  dtypes = list(zip(dataset.dtypes.index, map(str, dataset.dtypes)))
  # Normalize numeric columns.
  for column, dtype in dtypes:
      if dtype == 'float32':
          dataset[column] -= dataset[column].mean()
          dataset[column] /= dataset[column].std()
  return dataset

You can simply use the pandas.DataFrame.transform1 function in this way:

df.transform(lambda x: x/x.max())
  • 1
    This solution won't work if all values are negative. Consider [-1, -2, -3]. We divide by -1, and now we have [1,2,3]. – Dave Liu Dec 5 '19 at 19:42
  • To properly handle negative numbers: df.transform(lambda x: x / abs(x).max()) – nvd Mar 25 at 21:26

You can do this in one line

DF_test = DF_test.sub(DF_test.mean(axis=0), axis=1)/DF_test.mean(axis=0)

it takes mean for each of the column and then subtracts it(mean) from every row(mean of particular column subtracts from its row only) and divide by mean only. Finally, we what we get is the normalized data set.


Pandas does column wise normalization by default. Try the code below.

X= pd.read_csv('.\\data.csv')
X = (X-X.min())/(X.max()-X.min())

The output values will be in range of 0 and 1.


If your data is positively skewed, the best way to normalize is to use the log transformation:

df = np.log10(df)

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