I want to find mean and standard deviation of 1st, 2nd,... digits of several (Z) lists. For example, I have

# etc (up to Z_rank )...

Now I want to take the mean and std of *_Rank[0], the mean and std of *_Rank[1], etc.
(ie: mean and std of the 1st digit from all the (A..Z)_rank lists;
the mean and std of the 2nd digit from all the (A..Z)_rank lists;
the mean and std of the 3rd digit...; etc).

  • 12
    Hello, viral. Stack Overflow works best as a question-and-answer site. You ask a question, and everyone else provides answers. Your post contains only statements, no questions. Do you have a specific programming question? To put it another way, what have you tried so far, and where are you stuck? – Robᵩ Mar 13 '13 at 15:40
  • 2
    Why aren't these lists in a dictionary or something? – Waleed Khan Mar 13 '13 at 15:44
  • Sorry If I did not convey question properly. I want to take mean of A_rank[0] (0.8),B_rank[0](0.1),C_rank[0](1.2),...Z_rank[0]. same for A_rank[1](0.4),B_rank[1](2.8),C_rank[1](3.4),...Z_rank[1]. – physics_for_all Mar 13 '13 at 15:45

Since Python 3.4 / PEP450 there is a statistics module in the standard library, which has a method stdev for calculating the standard deviation of iterables like yours:

>>> A_rank = [0.8, 0.4, 1.2, 3.7, 2.6, 5.8]
>>> import statistics
>>> statistics.stdev(A_rank)
  • 30
    It's worth pointing out that pstddev should probably be used instead if your list represents the entire population (i.e. the list is not a sample of a population). stddev is calculated using sample variance and will overestimate the population mean. – Alex Riley Jan 3 '15 at 17:55
  • 3
    The functions are actually called stdev and pstdev, not using std for standard as one would expect. I couldn't edit the post as edits need to modify at least 6 chars... – mknaf Jan 6 '17 at 16:00

I would put A_Rank et al into a 2D NumPy array, and then use numpy.mean() and numpy.std() to compute the means and the standard deviations:

In [17]: import numpy

In [18]: arr = numpy.array([A_rank, B_rank, C_rank])

In [20]: numpy.mean(arr, axis=0)
array([ 0.7       ,  2.2       ,  1.8       ,  2.13333333,  3.36666667,
        5.1       ])

In [21]: numpy.std(arr, axis=0)
array([ 0.45460606,  1.29614814,  1.37355985,  1.50628314,  1.15566239,
        1.2083046 ])
  • 2
    the result of numpy.std is not correct. Given these values: 20,31,50,69,80 and put in Excel using STDEV.S(A1:A5) the result is 25,109 NOT 22,45. – Jim Clermonts Oct 1 '15 at 9:28
  • 6
    This is correct: numpy.std(arr, ddof=1) – Jim Clermonts Oct 1 '15 at 9:34
  • 22
    @JimClermonts It has nothing to do with correctness. Whether or not ddof=0 (default, interprete data as population) or ddof=1 (interprete it as samples, i.e. estimate true variance) depends on what you're doing. – runDOSrun Jan 15 '16 at 10:32
  • 15
    To further clarify @runDOSrun's point, the Excel function STDEV.P() and the Numpy function std(ddof=0) calculate the population sd, or uncorrected sample sd, whilst the Excel function STDEV.S() and Numpy function std(ddof=1) calculate the (corrected) sample sd, which equals sqrt(N/(N-1)) times the population sd, where N is the number of points. See more: en.m.wikipedia.org/wiki/… – binaryfunt Apr 9 '16 at 15:56

Here's some pure-Python code you can use to calculate the mean and standard deviation.

All code below is based on the statistics module in Python 3.4+.

def mean(data):
    """Return the sample arithmetic mean of data."""
    n = len(data)
    if n < 1:
        raise ValueError('mean requires at least one data point')
    return sum(data)/n # in Python 2 use sum(data)/float(n)

def _ss(data):
    """Return sum of square deviations of sequence data."""
    c = mean(data)
    ss = sum((x-c)**2 for x in data)
    return ss

def stddev(data, ddof=0):
    """Calculates the population standard deviation
    by default; specify ddof=1 to compute the sample
    standard deviation."""
    n = len(data)
    if n < 2:
        raise ValueError('variance requires at least two data points')
    ss = _ss(data)
    pvar = ss/(n-ddof)
    return pvar**0.5

Note: for improved accuracy when summing floats, the statistics module uses a custom function _sum rather than the built-in sum which I've used in its place.

Now we have for example:

>>> mean([1, 2, 3])
>>> stddev([1, 2, 3]) # population standard deviation
>>> stddev([1, 2, 3], ddof=1) # sample standard deviation
  • 1
    Should it not be pvar=ss/(n-1) ? – Ranjith Ramachandra Jun 8 '15 at 13:28
  • 2
    @Ranjith: if you want to calculate the sample variance (or sample SD) you can use n-1. The code above is for the population SD (so there are n degrees of freedom). – Alex Riley Jun 8 '15 at 13:38
  • Hello Alex, Could you please post function for calculating sample standard deviation? I am limited with Python2.6, so I have to relay on this function. – Venu S Oct 8 '17 at 0:56
  • @VenuS: Hello, I've edited the stddev function so that it can calculate both sample and population standard deviations. – Alex Riley Oct 8 '17 at 10:29

In Python 2.7.1, you may calculate standard deviation using numpy.std() for:

  • Population std: Just use numpy.std() with no additional arguments besides to your data list.
  • Sample std: You need to pass ddof (i.e. Delta Degrees of Freedom) set to 1, as in the following example:

numpy.std(< your-list >, ddof=1)

The divisor used in calculations is N - ddof, where N represents the number of elements. By default ddof is zero.

It calculates sample std rather than population std.


In python 2.7 you can use NumPy's numpy.std() gives the population standard deviation.

In Python 3.4 statistics.stdev() returns the sample standard deviation. The pstdv() function is the same as numpy.std().


pure python code:

from math import sqrt

def stddev(lst):
    mean = float(sum(lst)) / len(lst)
    return sqrt(float(reduce(lambda x, y: x + y, map(lambda x: (x - mean) ** 2, lst))) / len(lst))
  • 8
    There's nothing 'pure' about that 1-liner. Yuck. Here's more pythonic version: sqrt(sum((x - mean)**2 for x in lst) / len(lst)) – DBrowne Oct 9 '17 at 4:36

Using python, here are few methods:

import statistics as st

n = int(input())
data = list(map(int, input().split()))

Approach1 - using a function

stdev = st.pstdev(data)

Approach2: calculate variance and take square root of it

variance = st.pvariance(data)
devia = math.sqrt(variance)

Approach3: using basic math

mean = sum(data)/n
variance = sum([((x - mean) ** 2) for x in X]) / n
stddev = variance ** 0.5



  • variance calculates variance of sample population
  • pvariance calculates variance of entire population
  • similar differences between stdev and pstdev

The other answers cover how to do std dev in python sufficiently, but no one explains how to do the bizarre traversal you've described.

I'm going to assume A-Z is the entire population. If not see Ome's answer on how to inference from a sample.

So to get the standard deviation/mean of the first digit of every list you would need something like this:

#standard deviation
numpy.std([A_rank[0], B_rank[0], C_rank[0], ..., Z_rank[0]])

numpy.mean([A_rank[0], B_rank[0], C_rank[0], ..., Z_rank[0]])

To shorten the code and generalize this to any nth digit use the following function I generated for you:

def getAllNthRanks(n):
    return [A_rank[n], B_rank[n], C_rank[n], D_rank[n], E_rank[n], F_rank[n], G_rank[n], H_rank[n], I_rank[n], J_rank[n], K_rank[n], L_rank[n], M_rank[n], N_rank[n], O_rank[n], P_rank[n], Q_rank[n], R_rank[n], S_rank[n], T_rank[n], U_rank[n], V_rank[n], W_rank[n], X_rank[n], Y_rank[n], Z_rank[n]] 

Now you can simply get the stdd and mean of all the nth places from A-Z like this:

#standard deviation

  • For any one interested, I generated the function using this messy one-liner: str([chr(x)+'_rank[n]' for x in range(65,65+26)]).replace("'", "") – Samy Bencherif May 22 '17 at 16:13

Your Answer

By clicking “Post Your Answer”, you agree to our terms of service, privacy policy and cookie policy

Not the answer you're looking for? Browse other questions tagged or ask your own question.