# Can anyone explain me StandardScaler?

I am unable to understand the page of the `StandardScaler` in the documentation of `sklearn`.

Can anyone explain this to me in simple terms?

# Intro

I assume that you have a matrix `X` where each row/line is a sample/observation and each column is a variable/feature (this is the expected input for any `sklearn` ML function by the way -- `X.shape` should be `[number_of_samples, number_of_features]`).

# Core of method

The main idea is to normalize/standardize i.e. `μ = 0` and `σ = 1` your features/variables/columns of `X`, individually, before applying any machine learning model.

`StandardScaler()` will normalize the features i.e. each column of X, INDIVIDUALLY, so that each column/feature/variable will have `μ = 0` and `σ = 1`.

P.S: I find the most upvoted answer on this page, wrong. I am quoting "each value in the dataset will have the sample mean value subtracted" -- This is neither true nor correct.

# Example with code

``````from sklearn.preprocessing import StandardScaler
import numpy as np

# 4 samples/observations and 2 variables/features
data = np.array([[0, 0], [1, 0], [0, 1], [1, 1]])
scaler = StandardScaler()
scaled_data = scaler.fit_transform(data)

print(data)
[[0, 0],
[1, 0],
[0, 1],
[1, 1]])

print(scaled_data)
[[-1. -1.]
[ 1. -1.]
[-1.  1.]
[ 1.  1.]]
``````

Verify that the mean of each feature (column) is 0:

``````scaled_data.mean(axis = 0)
array([0., 0.])
``````

Verify that the std of each feature (column) is 1:

``````scaled_data.std(axis = 0)
array([1., 1.])
``````

# Appendix: The maths

UPDATE 08/2020: Concerning the input parameters `with_mean` and `with_std` to `False`/`True`, I have provided an answer here: StandardScaler difference between “with_std=False or True” and “with_mean=False or True”

• Do you have any idea why I get `[1.15, 1.15]` when I compute as a pandas df: `pd.DataFrame(scaled_data).std(0)`?
– Sos
Aug 16, 2019 at 14:21
• when I run `pd.DataFrame(scaled_data)[0]` I get a series with `Name: 0, dtype: float64` and values `[-1.0, 1.0, -1.0, 1.0]`. Sorry for the formatting
– Sos
Aug 19, 2019 at 13:27
• @seralouk I liked you answer, however I am still wondering what is the intention behind transforming input data using `StandardScaler`, does it make the machine learning algorithm go faster, or helps making more accurate decisions, or something else? May 17, 2020 at 10:10
• Standardization of a dataset is a common requirement for many machine learning estimators: they might behave badly if the individual features do not more or less look like standard normally distributed data (e.g. Gaussian with 0 mean and unit variance). For instance many elements used in the objective function of a learning algorithm (such as the RBF kernel of SVM or the L1 and L2 regularizers of linear models) assume that all features are centered around 0 and have variance in the same order. May 17, 2020 at 10:18
• So, Standardization leads to a) more stable b) less influenced by the range of variables c) faster fitting d) more stable performance May 17, 2020 at 10:19

The idea behind `StandardScaler` is that it will transform your data such that its distribution will have a mean value 0 and standard deviation of 1.
In case of multivariate data, this is done feature-wise (in other words independently for each column of the data).
Given the distribution of the data, each value in the dataset will have the mean value subtracted, and then divided by the standard deviation of the whole dataset (or feature in the multivariate case).

• I find that this answer is not correct. `each value in the dataset will have the sample mean value subtracted`-- this is not true. The mean of EACH feature/column will be subtracted from the values of the specific column. This is done column-wise. There is no `sample mean value subtracted` - See my answer below Nov 27, 2019 at 11:55
• @makis I edited my answer following the clarification you suggest. Nov 27, 2019 at 12:03

StandardScaler performs the task of Standardization. Usually a dataset contains variables that are different in scale. For e.g. an Employee dataset will contain AGE column with values on scale 20-70 and SALARY column with values on scale 10000-80000.
As these two columns are different in scale, they are Standardized to have common scale while building machine learning model.

• Best Easy Answer to Understand! thanks. Can you explain the process even more? Jul 2, 2021 at 20:11

How to calculate it:

You can read more here:

This is useful when you want to compare data that correspond to different units. In that case, you want to remove the units. To do that in a consistent way of all the data, you transform the data in a way that the variance is unitary and that the mean of the series is 0.

• can u pls explain with an example..as in how it helps?..that wud be really helpful..thanks Jul 2, 2018 at 12:23

Following is a simple working example to explain how standarization calculation works. The theory part is already well explained in other answers.

``````>>>import numpy as np
>>>data = [[6, 2], [4, 2], [6, 4], [8, 2]]
>>>a = np.array(data)

>>>np.std(a, axis=0)
array([1.41421356, 0.8660254 ])

>>>np.mean(a, axis=0)
array([6. , 2.5])

>>>from sklearn.preprocessing import StandardScaler
>>>scaler = StandardScaler()
>>>scaler.fit(data)
>>>print(scaler.mean_)

#Xchanged = (X−μ)/σ  WHERE σ is Standard Deviation and μ is mean
>>>z=scaler.transform(data)
>>>z
``````

Calculation

As you can see in the output, mean is [6. , 2.5] and std deviation is [1.41421356, 0.8660254 ]

Data is (0,1) position is 2 Standardization = (2 - 2.5)/0.8660254 = -0.57735027

Data in (1,0) position is 4 Standardization = (4-6)/1.41421356 = -1.414

Result After Standardization

Check Mean and Std Deviation After Standardization

Note: -2.77555756e-17 is very close to 0.

References

The answers above are great, but I needed a simple example to alleviate some concerns that I have had in the past. I wanted to make sure it was indeed treating each column separately. I am now reassured and can't find what example had caused me concern. All columns ARE scaled separately as described by those above.

### CODE

``````import pandas as pd
import scipy.stats as ss
from sklearn.preprocessing import StandardScaler

data= [[1, 1, 1, 1, 1],[2, 5, 10, 50, 100],[3, 10, 20, 150, 200],[4, 15, 40, 200, 300]]

df = pd.DataFrame(data, columns=['N0', 'N1', 'N2', 'N3', 'N4']).astype('float64')

sc_X = StandardScaler()
df = sc_X.fit_transform(df)

num_cols = len(df[0,:])
for i in range(num_cols):
col = df[:,i]
col_stats = ss.describe(col)
print(col_stats)
``````

## OUTPUT

``````DescribeResult(nobs=4, minmax=(-1.3416407864998738, 1.3416407864998738), mean=0.0, variance=1.3333333333333333, skewness=0.0, kurtosis=-1.3599999999999999)
DescribeResult(nobs=4, minmax=(-1.2828087129930659, 1.3778315806221817), mean=-5.551115123125783e-17, variance=1.3333333333333337, skewness=0.11003776770595125, kurtosis=-1.394993095506219)
DescribeResult(nobs=4, minmax=(-1.155344148338584, 1.53471088361394), mean=0.0, variance=1.3333333333333333, skewness=0.48089217736510326, kurtosis=-1.1471008824318165)
DescribeResult(nobs=4, minmax=(-1.2604572012883055, 1.2668071116222517), mean=-5.551115123125783e-17, variance=1.3333333333333333, skewness=0.0056842140599118185, kurtosis=-1.6438177182479734)
DescribeResult(nobs=4, minmax=(-1.338945389819976, 1.3434309690153527), mean=5.551115123125783e-17, variance=1.3333333333333333, skewness=0.005374558840039456, kurtosis=-1.3619131970819205)
``````

# NOTE:

The scipy.stats module is correctly reporting the "sample" variance, which uses (n - 1) in the denominator. The "population" variance would use n in the denominator for the calculation of variance. To understand better, please see the code below that uses scaled data from the first column of the data set above:

## Code

``````import scipy.stats as ss

sc_Data = [[-1.34164079], [-0.4472136], [0.4472136], [1.34164079]]
col_stats = ss.describe([-1.34164079, -0.4472136, 0.4472136, 1.34164079])
print(col_stats)
print()

mean_by_hand = 0
for row in sc_Data:
for element in row:
mean_by_hand += element
mean_by_hand /= 4

variance_by_hand = 0
for row in sc_Data:
for element in row:
variance_by_hand += (mean_by_hand - element)**2
sample_variance_by_hand = variance_by_hand / 3
sample_std_dev_by_hand = sample_variance_by_hand ** 0.5

pop_variance_by_hand = variance_by_hand / 4
pop_std_dev_by_hand = pop_variance_by_hand ** 0.5

print("Sample of Population Calcs:")
print(mean_by_hand, sample_variance_by_hand, sample_std_dev_by_hand, '\n')
print("Population Calcs:")
print(mean_by_hand, pop_variance_by_hand, pop_std_dev_by_hand)
``````

## Output

``````DescribeResult(nobs=4, minmax=(-1.34164079, 1.34164079), mean=0.0, variance=1.3333333422778562, skewness=0.0, kurtosis=-1.36000000429325)

Sample of Population Calcs:
0.0 1.3333333422778562 1.1547005422523435

Population Calcs:
0.0 1.000000006708392 1.000000003354196
``````
• Why variance is not 1, please?
– Max
Mar 5, 2019 at 0:17
• @Max, scipy stats is using sample variance. See new additions to answer. Sep 25, 2020 at 18:32
• @seralouk Yes if the population variance and std deviation, but not for the sample variance and std deviation - scipy stats defaulting to the sample calcs. Sep 25, 2020 at 18:33

After applying `StandardScaler()`, each column in X will have mean of 0 and standard deviation of 1.

Formulas are listed by others on this page.

Rationale: some algorithms require data to look like this (see sklearn docs).

• Correct. Some answers showing the scipy stats description of the scaled data's sample mean and variance. Sample variance for small data sets can be significantly different from population variance. Sep 25, 2020 at 18:36

We apply `StandardScalar()` on a row basis.

So, for each row in a column (I am assuming that you are working with a Pandas DataFrame):

``````x_new = (x_original - mean_of_distribution) / std_of_distribution
``````

Few points -

1. It is called Standard Scalar as we are dividing it by the standard deviation of the distribution (distr. of the feature). Similarly, you can guess for `MinMaxScalar()`.

2. The original distribution remains the same after applying `StandardScalar()`. It is a common misconception that the distribution gets changed to a Normal Distribution. We are just squashing the range into [0, 1].