I am looking for a function in Numpy or Scipy (or any rigorous Python library) that will give me the cumulative normal distribution function in Python.
Here's an example:
>>> from scipy.stats import norm
>>> norm.cdf(1.96)
0.9750021048517795
>>> norm.cdf(1.96)
0.024997895148220435
In other words, approximately 95% of the standard normal interval lies within two standard deviations, centered on a standard mean of zero.
If you need the inverse CDF:
>>> norm.ppf(norm.cdf(1.96))
array(1.9599999999999991)

11Also, you can specify the mean (loc) and variance (scale) as parameters. e.g, d = norm(loc=10.0, scale=2.0); d.cdf(12.0); Details here: docs.scipy.org/doc/scipy0.14.0/reference/generated/… – Irvan Oct 31 '14 at 13:41

7@Irvan, the scale parameter is actually the standard deviation, NOT the variance. – qkhhly Jun 2 '15 at 19:08

2Why does scipy name these as
loc
andscale
? I used thehelp(norm.ppf)
but then what the heck areloc
andscale
 need a help for the help.. – StephenBoesch Dec 22 '16 at 20:31 
3@javadba  location and scale are more general terms in statistics that are used to parameterize a wide range of distributions. For the normal distribution, they line up with mean and sd, but not so for other distributions. – Michael Ohlrogge Aug 25 '17 at 17:59

1@MichaelOhlrogge . Thx! Here is a page from NIST explaining further itl.nist.gov/div898/handbook/eda/section3/eda364.htm – StephenBoesch Aug 25 '17 at 18:03
It may be too late to answer the question but since Google still leads people here, I decide to write my solution here.
That is, since Python 2.7, the math
library has integrated the error function math.erf(x)
The erf()
function can be used to compute traditional statistical functions such as the cumulative standard normal distribution:
from math import *
def phi(x):
#'Cumulative distribution function for the standard normal distribution'
return (1.0 + erf(x / sqrt(2.0))) / 2.0
Ref:
https://docs.python.org/2/library/math.html
https://docs.python.org/3/library/math.html
How are the Error Function and Standard Normal distribution function related?

3This was exactly what I was looking for. If someone else than me wonders how this can be used to calculate "percentage of data that lies within the standard distribution", well: 1  (1  phi(1)) * 2 = 0.6827 ("68% of data within 1 standard deviation") – Hannes Landeholm Jul 10 '17 at 18:30

2For a general normal distribution, it would be
def phi(x, mu, sigma): return (1 + erf((x  mu) / sigma / sqrt(2))) / 2
. – Bernhard Barker Mar 15 '20 at 19:18
Starting Python 3.8
, the standard library provides the NormalDist
object as part of the statistics
module.
It can be used to get the cumulative distribution function (cdf
 probability that a random sample X will be less than or equal to x) for a given mean (mu
) and standard deviation (sigma
):
from statistics import NormalDist
NormalDist(mu=0, sigma=1).cdf(1.96)
# 0.9750021048517796
Which can be simplified for the standard normal distribution (mu = 0
and sigma = 1
):
NormalDist().cdf(1.96)
# 0.9750021048517796
NormalDist().cdf(1.96)
# 0.024997895148220428

Based on some quick checks, this is significantly faster than norm.cdf from scipy.stats and a fair bit faster than both scipy and math implementations of erf. – dcl Mar 15 at 4:33
Adapted from here http://mail.python.org/pipermail/pythonlist/2000June/039873.html
from math import *
def erfcc(x):
"""Complementary error function."""
z = abs(x)
t = 1. / (1. + 0.5*z)
r = t * exp(z*z1.26551223+t*(1.00002368+t*(.37409196+
t*(.09678418+t*(.18628806+t*(.27886807+
t*(1.13520398+t*(1.48851587+t*(.82215223+
t*.17087277)))))))))
if (x >= 0.):
return r
else:
return 2.  r
def ncdf(x):
return 1.  0.5*erfcc(x/(2**0.5))

4Since the std lib implements math.erf(), there is no need for a sep implementation. – Marc Feb 25 '16 at 20:10

1
To build upon Unknown's example, the Python equivalent of the function normdist() implemented in a lot of libraries would be:
def normcdf(x, mu, sigma):
t = xmu;
y = 0.5*erfcc(t/(sigma*sqrt(2.0)));
if y>1.0:
y = 1.0;
return y
def normpdf(x, mu, sigma):
u = (xmu)/abs(sigma)
y = (1/(sqrt(2*pi)*abs(sigma)))*exp(u*u/2)
return y
def normdist(x, mu, sigma, f):
if f:
y = normcdf(x,mu,sigma)
else:
y = normpdf(x,mu,sigma)
return y
Alex's answer shows you a solution for standard normal distribution (mean = 0, standard deviation = 1). If you have normal distribution with mean
and std
(which is sqr(var)
) and you want to calculate:
from scipy.stats import norm
# cdf(x < val)
print norm.cdf(val, m, s)
# cdf(x > val)
print 1  norm.cdf(val, m, s)
# cdf(v1 < x < v2)
print norm.cdf(v2, m, s)  norm.cdf(v1, m, s)
Read more about cdf here and scipy implementation of normal distribution with many formulas here.
Taken from above:
from scipy.stats import norm
>>> norm.cdf(1.96)
0.9750021048517795
>>> norm.cdf(1.96)
0.024997895148220435
For a twotailed test:
Import numpy as np
z = 1.96
p_value = 2 * norm.cdf(np.abs(z))
0.04999579029644087
Simple like this:
import math
def my_cdf(x):
return 0.5*(1+math.erf(x/math.sqrt(2)))
I found the formula in this page https://www.danielsoper.com/statcalc/formulas.aspx?id=55
As Google gives this answer for the search netlogo pdf, here's the netlogo version of the above python code
;; Normal distribution cumulative density function toreport normcdf [x mu sigma] let t x  mu let y 0.5 * erfcc [  t / ( sigma * sqrt 2.0)] if ( y > 1.0 ) [ set y 1.0 ] report y end ;; Normal distribution probability density function toreport normpdf [x mu sigma] let u = (x  mu) / abs sigma let y = 1 / ( sqrt [2 * pi] * abs sigma ) * exp (  u * u / 2.0) report y end ;; Complementary error function toreport erfcc [x] let z abs x let t 1.0 / (1.0 + 0.5 * z) let r t * exp (  z * z 1.26551223 + t * (1.00002368 + t * (0.37409196 + t * (0.09678418 + t * (0.18628806 + t * (.27886807 + t * (1.13520398 +t * (1.48851587 +t * (0.82215223 + t * .17087277 ))))))))) ifelse (x >= 0) [ report r ] [report 2.0  r] end

6The question is about Python, not NetLogo. This answer should not be here. And please don't edit the question to change its meaning. – interjay Oct 18 '12 at 13:07

I am aware that this is not the preferred way, but I guess it is most helpful this way as people are directed to this page by google (currently...) – platipodium Oct 18 '12 at 13:19