# How to calculate the inverse of the normal cumulative distribution function in python?

How do I calculate the inverse of the cumulative distribution function (CDF) of the normal distribution in Python?

Which library should I use? Possibly scipy?

• Do you mean the inverse Gaussian distribution (en.wikipedia.org/wiki/Inverse_Gaussian_distribution), or the inverse of the cumulative distribution function of the normal distribution (en.wikipedia.org/wiki/Normal_distribution), or something else? Commented Dec 17, 2013 at 6:30
• @WarrenWeckesser the second one: inverse of the cumulative distribution function of the normal distribution Commented Dec 17, 2013 at 6:32
• @WarrenWeckesser i mean the python version of "normsinv" function in excel. Commented Dec 17, 2013 at 6:39

NORMSINV (mentioned in a comment) is the inverse of the CDF of the standard normal distribution. Using `scipy`, you can compute this with the `ppf` method of the `scipy.stats.norm` object. The acronym `ppf` stands for percent point function, which is another name for the quantile function.

``````In [20]: from scipy.stats import norm

In [21]: norm.ppf(0.95)
Out[21]: 1.6448536269514722
``````

Check that it is the inverse of the CDF:

``````In [34]: norm.cdf(norm.ppf(0.95))
Out[34]: 0.94999999999999996
``````

By default, `norm.ppf` uses mean=0 and stddev=1, which is the "standard" normal distribution. You can use a different mean and standard deviation by specifying the `loc` and `scale` arguments, respectively.

``````In [35]: norm.ppf(0.95, loc=10, scale=2)
Out[35]: 13.289707253902945
``````

If you look at the source code for `scipy.stats.norm`, you'll find that the `ppf` method ultimately calls `scipy.special.ndtri`. So to compute the inverse of the CDF of the standard normal distribution, you could use that function directly:

``````In [43]: from scipy.special import ndtri

In [44]: ndtri(0.95)
Out[44]: 1.6448536269514722
``````

`ndtri` is much faster than `norm.ppf`:

``````In [46]: %timeit norm.ppf(0.95)
240 µs ± 1.75 µs per loop (mean ± std. dev. of 7 runs, 1,000 loops each)

In [47]: %timeit ndtri(0.95)
1.47 µs ± 1.3 ns per loop (mean ± std. dev. of 7 runs, 1,000,000 loops each)
``````
• I always think "percent point function" (ppf) is a terrible name. Most people in statistics just use "quantile function". Commented Oct 4, 2014 at 0:44
• Don't you need to specify the mean and the std on both ppf and cdf? Commented Jan 29, 2021 at 19:23
• @bones.felipe, the "standard" normal distribution has mean 0 and standard deviation 1. These are the default values for the location and scale of the `scipy.stats.norm` methods. Commented Jan 29, 2021 at 19:55
• Right, I thought I saw this `norm.cdf(norm.ppf(0.95, loc=10, scale=2))` and I thought it was weird `norm.cdf` did not have `loc=10` and `scale=2` too, I guess it should. Commented Jan 30, 2021 at 5:33

Starting `Python 3.8`, the standard library provides the `NormalDist` object as part of the `statistics` module.

It can be used to get the inverse cumulative distribution function (`inv_cdf` - inverse of the `cdf`), also known as the quantile function or the percent-point function for a given mean (`mu`) and standard deviation (`sigma`):

``````from statistics import NormalDist

NormalDist(mu=10, sigma=2).inv_cdf(0.95)
# 13.289707253902943
``````

Which can be simplified for the standard normal distribution (`mu = 0` and `sigma = 1`):

``````NormalDist().inv_cdf(0.95)
# 1.6448536269514715
``````
• Great tip! This allows me to drop the dependency on scipy, which I needed just for the single stats.norm.ppf method Commented Feb 21, 2020 at 16:56
• can you use that to transform data with uniform distribution to normal ? Commented Mar 31, 2022 at 20:51
``````# given random variable X (house price) with population muy = 60, sigma = 40
import scipy as sc
import scipy.stats as sct
sc.version.full_version # 0.15.1

#a. Find P(X<50)
sct.norm.cdf(x=50,loc=60,scale=40) # 0.4012936743170763

#b. Find P(X>=50)
sct.norm.sf(x=50,loc=60,scale=40) # 0.5987063256829237

#c. Find P(60<=X<=80)
sct.norm.cdf(x=80,loc=60,scale=40) - sct.norm.cdf(x=60,loc=60,scale=40)

#d. how much top most 5% expensive house cost at least? or find x where P(X>=x) = 0.05
sct.norm.isf(q=0.05,loc=60,scale=40)

#e. how much top most 5% cheapest house cost at least? or find x where P(X<=x) = 0.05
sct.norm.ppf(q=0.05,loc=60,scale=40)
``````
• PS: You can assume 'loc' as 'mean' and 'scale' as 'standard deviation' Commented Jul 5, 2017 at 11:11