# How can I calculate the variance of a list in python?

If I have a list like this:

``````results=[-14.82381293, -0.29423447, -13.56067979, -1.6288903, -0.31632439,
0.53459687, -1.34069996, -1.61042692, -4.03220519, -0.24332097]
``````

I want to calculate the variance of this list in Python which is the average of the squared differences from the mean.

How can I go about this? Accessing the elements in the list to do the computations is confusing me for getting the square differences.

• You do just that. What's the problem? Feb 23, 2016 at 16:47
• @Vincent accessing the elements of the list to get the squared differences Feb 23, 2016 at 16:51

You can use numpy's built-in function `var`:

``````import numpy as np

results = [-14.82381293, -0.29423447, -13.56067979, -1.6288903, -0.31632439,
0.53459687, -1.34069996, -1.61042692, -4.03220519, -0.24332097]

print(np.var(results))
``````

This gives you `28.822364260579157`

If - for whatever reason - you cannot use `numpy` and/or you don't want to use a built-in function for it, you can also calculate it "by hand" using e.g. a list comprehension:

``````# calculate mean
m = sum(results) / len(results)

# calculate variance using a list comprehension
var_res = sum((xi - m) ** 2 for xi in results) / len(results)
``````

which gives you the identical result.

If you are interested in the standard deviation, you can use numpy.std:

``````print(np.std(results))
5.36864640860051
``````

@Serge Ballesta explained very well the difference between variance `n` and `n-1`. In numpy you can easily set this parameter using the option `ddof`; its default is `0`, so for the `n-1` case you can simply do:

``````np.var(results, ddof=1)
``````

The "by hand" solution is given in @Serge Ballesta's answer.

Both approaches yield `32.024849178421285`.

You can set the parameter also for `std`:

``````np.std(results, ddof=1)
5.659050201086865
``````

Starting `Python 3.4`, the standard library comes with the `variance` function (sample variance or variance n-1) as part of the `statistics` module:

``````from statistics import variance
# data = [-14.82381293, -0.29423447, -13.56067979, -1.6288903, -0.31632439, 0.53459687, -1.34069996, -1.61042692, -4.03220519, -0.24332097]
variance(data)
# 32.024849178421285
``````

The population variance (or variance n) can be obtained using the `pvariance` function:

``````from statistics import pvariance
# data = [-14.82381293, -0.29423447, -13.56067979, -1.6288903, -0.31632439, 0.53459687, -1.34069996, -1.61042692, -4.03220519, -0.24332097]
pvariance(data)
# 28.822364260579157
``````

Also note that if you already know the mean of your list, the `variance` and `pvariance` functions take a second argument (respectively `xbar` and `mu`) in order to spare recomputing the mean of the sample (which is part of the variance computation).

Well, there are two ways for defining the variance. You have the variance n that you use when you have a full set, and the variance n-1 that you use when you have a sample.

The difference between the 2 is whether the value `m = sum(xi) / n` is the real average or whether it is just an approximation of what the average should be.

Example1 : you want to know the average height of the students in a class and its variance : ok, the value `m = sum(xi) / n` is the real average, and the formulas given by Cleb are ok (variance n).

Example2 : you want to know the average hour at which a bus passes at the bus stop and its variance. You note the hour for a month, and get 30 values. Here the value `m = sum(xi) / n` is only an approximation of the real average, and that approximation will be more accurate with more values. In that case the best approximation for the actual variance is the variance n-1

``````varRes = sum([(xi - m)**2 for xi in results]) / (len(results) -1)
``````

Ok, it has nothing to do with Python, but it does have an impact on statistical analysis, and the question is tagged and

Note: ordinarily, statistical libraries like numpy use the variance n for what they call `var` or `variance`, and the variance n-1 for the function that gives the standard deviation.

Numpy is indeed the most elegant and fast way to do it.

I think the actual question was about how to access the individual elements of a list to do such a calculation yourself, so below an example:

``````results=[-14.82381293, -0.29423447, -13.56067979, -1.6288903, -0.31632439,
0.53459687, -1.34069996, -1.61042692, -4.03220519, -0.24332097]

import numpy as np
print 'numpy variance: ', np.var(results)

# without numpy by hand

# there are two ways of calculating the variance
#   - 1. direct as central 2nd order moment (https://en.wikipedia.org/wiki/Moment_(mathematics))divided by the length of the vector
#   - 2. "mean of square minus square of mean" (see https://en.wikipedia.org/wiki/Variance)

# calculate mean
n= len(results)
sum=0
for i in range(n):
sum = sum+ results[i]

mean=sum/n
print 'mean: ', mean

#  calculate the central moment
sum2=0
for i in range(n):
sum2=sum2+ (results[i]-mean)**2

myvar1=sum2/n
print "my variance1: ", myvar1

# calculate the mean of square minus square of mean
sum3=0
for i in range(n):
sum3=sum3+ results[i]**2

myvar2 = sum3/n - mean**2
print "my variance2: ", myvar2
``````

gives you:

``````numpy variance:  28.8223642606
mean:  -3.731599805
my variance1:  28.8223642606
my variance2:  28.8223642606
``````
``````import numpy as np
def get_variance(xs):
mean = np.mean(xs)
summed = 0
for x in xs:
summed += (x - mean)**2
return summed / (len(xs))
print(get_variance([1,2,3,4,5]))
``````

out 2.0

``````a = [1,2,3,4,5]
variance = np.var(a, ddof=1)
print(variance)
``````
• why is summed divided by (len(xs) - 1) as opposed to just len(xs)? Oct 21, 2019 at 15:32

The correct answer is to use one of the packages like NumPy, but if you want to roll your own, and you want to do incrementally, there is a good algorithm that has higher accuracy. See this link https://www.johndcook.com/blog/standard_deviation/

I ported my perl implementation to Python. Please point out issues in the comments.

``````Mklast = 0
Mk = 0
Sk = 0
k  = 0

for xi in results:
k = k +1
Mk = Mklast + (xi - Mklast) / k
Sk = Sk + (xi - Mklast) * ( xi - Mk)
Mklast = Mk

var = Sk / (k -1)
print var
``````

``````>>> print var
32.0248491784
``````
• That's the sample variance, not the population variance. Jul 22, 2019 at 20:38

Without imports, I would use the following python3 script:

``````#!/usr/bin/env python3

def createData():
data1=[12,54,60,3,15,6,36]
data2=[1,2,3,4,5]
data3=[100,30000,1567,3467,20000,23457,400,1,15]

dataset=[]
dataset.append(data1)
dataset.append(data2)
dataset.append(data3)

return dataset

def calculateMean(data):
means=[]
# one list of the nested list
for oneDataset in data:
sum=0
mean=0
# one datapoint in one inner list
for number in oneDataset:
# summing up
sum+=number
# mean for one inner list
mean=sum/len(oneDataset)
# adding a tuples of the original data and their mean to
# a list of tuples
item=(oneDataset, mean)
means.append(item)

return means

# to do: substract mean from each element and square the result
# sum up the square results and divide by number of elements
def calculateVariance(meanData):
variances=[]
# meanData is the list of tuples
# pair is one tuple
for pair in meanData:
# pair is the original data
interResult=0
squareSum=0
for element in pair:
interResult=(element-pair)**2
squareSum+=interResult
variance=squareSum/len(pair)
variances.append((pair, pair, variance))

return variances

def main():
my_data=createData()
my_means=calculateMean(my_data)
my_variances=calculateVariance(my_means)
print(my_variances)

if __name__ == "__main__":
main()
``````

here you get a print of the original data, their mean and the variance. I know this approach covers a list of several datasets, yet I think you can adapt it quickly for your purpose ;)

Here's my solutions

vac_nums = [0,0,0,0,0, 1,1,1,1,1,1,1,1, 2,2,2,2, 3,3,3 ] #your code goes here

``````mean = sum(vac_nums)/len(vac_nums);

count=0;

for i in range(len(vac_nums)):
variance = (vac_nums[i]-mean)**2;
count += variance;

print (count/len(vac_nums));
``````