# Convert Z-score (Z-value, standard score) to p-value for normal distribution in Python

How does one convert a Z-score from the Z-distribution (standard normal distribution, Gaussian distribution) to a p-value? I have yet to find the magical function in Scipy's `stats` module to do this, but one must be there.

I like the survival function (upper tail probability) of the normal distribution a bit better, because the function name is more informative:

``````p_values = scipy.stats.norm.sf(abs(z_scores)) #one-sided

p_values = scipy.stats.norm.sf(abs(z_scores))*2 #twosided
``````

normal distribution "norm" is one of around 90 distributions in scipy.stats

norm.sf also calls the corresponding function in scipy.special as in gotgenes example

small advantage of survival function, sf: numerical precision should better for quantiles close to 1 than using the cdf

I think the cumulative distribution function (cdf) is preferred to the survivor function. The survivor function is defined as 1-cdf, and may communicate improperly the assumptions the language model uses for directional percentiles. Also, the percentage point function (ppf) is the inverse of the cdf, which is very convenient.

``````>>> import scipy.stats as st
>>> st.norm.ppf(.95)
1.6448536269514722
>>> st.norm.cdf(1.64)
0.94949741652589625
``````

Edit: A user requested an example for ''vectors'':

``````import numpy as np
vector = np.array([.925, .95, .975, .99])
p_values = [st.norm.ppf(v) for v in vector]
f_values = [st.norm.cdf(p) for p in p_values]

for p,f in zip(p_values, f_values):
print(f'p: {p}, \tf: {f}')
``````

Yields:

``````p: 1.4395314709384563,  f: 0.925
p: 1.6448536269514722,  f: 0.95
p: 1.959963984540054,   f: 0.975
p: 2.3263478740408408,  f: 0.99
``````
• Could you provide a more complete code answer that shows how to convert a vector of Z-scores to a vector of p-values? Apr 3, 2021 at 11:13
• @RobinDeSchepper Added Apr 6, 2021 at 0:17
• I may be mistaken, but am I not seeing z-scores and percentiles, but no p-values in the above solution? I like the solution a lot; it's just I don't see any p-values; they seem to be z-scores. Apr 8, 2022 at 2:46

Aha! I found it: `scipy.special.ndtr`! This also appears to be under `scipy.stats.stats.zprob` as well (which is just a pointer to `ndtr`).

Specifically, given a one-dimensional `numpy.array` instance `z_scores`, one can obtain the p-values as

``````p_values = 1 - scipy.special.ndtr(z_scores)
``````

or alternatively

``````p_values = scipy.special.ndtr(-z_scores)
``````
• Strange terminology, "Z-distribution" instead of "Normal curve". Z-score I'd probably call standard deviation in this context as well. Aug 16, 2010 at 19:52
• Well, the Z-distribution == "standard normal distribution" == `N(0, 1)`. That said, your point is well taken. I have updated the question to reflect the various terminology for the same concepts. Aug 16, 2010 at 20:43

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

It can be used to apply the inverse cumulative distribution function (`inv_cdf`, also known as the quantile function or the percent-point function) and the cumulative distribution function (`cdf`):

``````NormalDist().inv_cdf(0.95)
# 1.6448536269514715
NormalDist().cdf(1.64)
# 0.9494974165258963
``````

From formula:

``````import numpy as np
import scipy.special as scsp
def z2p(z):
"""From z-score return p-value."""
return 0.5 * (1 + scsp.erf(z / np.sqrt(2)))
``````
• This isn't the best solution; it isn't vectorized like the above answer. Feb 22, 2015 at 17:00
• You can get a vectorized version simply by replacing `math.erf` and `math.sqrt` by `erf` and `sqrt` from scipy. Sep 22, 2015 at 13:56
• this is the best solution, if z is not a vector Jan 14, 2019 at 11:39
``````p_value = scipy.stats.norm.pdf(abs(z_score_max)) #one-sided test
p_value = scipy.stats.norm.pdf(abs(z_score_max))*2 # two - sided test
``````

The probability density function (pdf) function in python yields values p-values that are drawn from a z-score table in a intro/AP stats book.

For Scipy lovers, Tough this is old question but relevant, and we can have not only normal but other distributions as well so here is solution for few more distributions:

``````def get_p_value_normal(z_score: float) -> float:
"""get p value for normal(Gaussian) distribution

Args:
z_score (float): z score

Returns:
float: p value
"""
return round(norm.sf(z_score), decimal_limit)

def get_p_value_t(z_score: float) -> float:
"""get p value for t distribution

Args:
z_score (float): z score

Returns:
float: p value
"""
return round(t.sf(z_score), decimal_limit)

def get_p_value_chi2(z_score: float) -> float:
"""get p value for chi2 distribution

Args:
z_score (float): z score

Returns:
float: p value
"""
return round(chi2.ppf(z_score, df), decimal_limit)
``````