# Compute a confidence interval from sample data

I have sample data which I would like to compute a confidence interval for, assuming a normal distribution.

I have found and installed the numpy and scipy packages and have gotten numpy to return a mean and standard deviation (numpy.mean(data) with data being a list). Any advice on getting a sample confidence interval would be much appreciated.

• i think you sure specify if you want to compute the CI for the sample mean or the population mean. That would determine if you want to use normal or t distribution to calculate the z-score. And the top answer below is for sample mean, so a t distribution is used. – Jake May 15 at 20:10

## 4 Answers

``````import numpy as np
import scipy.stats

def mean_confidence_interval(data, confidence=0.95):
a = 1.0 * np.array(data)
n = len(a)
m, se = np.mean(a), scipy.stats.sem(a)
h = se * scipy.stats.t.ppf((1 + confidence) / 2., n-1)
return m, m-h, m+h
``````

you can calculate like this way.

• sp.stats.stderr is deprecated. I substituted sp.stats.sem and it worked great! – Bmayer0122 Feb 23 '13 at 1:44
• Importing `scipy` does not necessarily import all the subpackages automatically. Better to import the sub-package `scipy.stats` explicitly. – Vikram Jul 2 '13 at 10:24
• Careful with the "private" use of `sp.stats.t._ppf`. I'm not that comfortable with that in there without further explanation. Better to use `sp.stats.t.ppf` directly, unless you are sure you know what you are doing. On quick inspection of the source there is a fair amount of code skipped with `_ppf`. Possibly benign, but also possibly an unsafe optimization attempt? – Russ Mar 12 '14 at 7:32
• I like it because you can just add `*ss.t._ppf((1+conf)/2.,n-1)` to the built-in pandas dataframe `.sem` method so you don't have to worry about `apply` – TNT Oct 28 '16 at 6:46
• Just want to clarify this calculation is for sample mean, so a t distribution is used. If the questions is to calculation population mean, a normal distribution should be used and the confident interval will be smaller for the same confidence level. – Jake May 15 at 20:11

Here a shortened version of shasan's code, calculating the 95% confidence interval of the mean of array `a`:

``````import numpy as np, scipy.stats as st

st.t.interval(0.95, len(a)-1, loc=np.mean(a), scale=st.sem(a))
``````

But using StatsModels' tconfint_mean is arguably even nicer:

``````import statsmodels.stats.api as sms

sms.DescrStatsW(a).tconfint_mean()
``````

The underlying assumptions for both are that the sample (array `a`) was drawn independently from a normal distribution with unknown standard deviation (see MathWorld or Wikipedia).

For large sample size n, the sample mean is normally distributed, and one can calculate its confidence interval using `st.norm.interval()` (as suggested in Jaime's comment). But the above solutions are correct also for small n, where `st.norm.interval()` gives confidence intervals that are too narrow (i.e., "fake confidence"). See my answer to a similar question for more details (and one of Russ's comments here).

Here an example where the correct options give (essentially) identical confidence intervals:

``````In : a = range(10,14)

In : mean_confidence_interval(a)
Out: (11.5, 9.4457397432391215, 13.554260256760879)

In : st.t.interval(0.95, len(a)-1, loc=np.mean(a), scale=st.sem(a))
Out: (9.4457397432391215, 13.554260256760879)

In : sms.DescrStatsW(a).tconfint_mean()
Out: (9.4457397432391197, 13.55426025676088)
``````

And finally, the incorrect result using `st.norm.interval()`:

``````In : st.norm.interval(0.95, loc=np.mean(a), scale=st.sem(a))
Out: (10.23484868811834, 12.76515131188166)
``````
• I believe you should be calling `st.t.interval(0.05)` to get the 95% confidence interval. – Scimonster Jun 26 '16 at 14:33
• No, `st.t.interval(0.95)` is correct for the 95% confidence interval, see the docs for `scipy.stats.t`. SciPy's naming the argument `alpha` seems less than ideal, though. – Ulrich Stern Jun 26 '16 at 15:33
• If I have two arrays of data and then calculated the difference of their mean. Is there any way to get a 95% CI for this mean difference? Could you think of any easy way to do it like the one you provide here by using StatsModelsl? – steven Jan 26 at 20:50
• @steven, turns out, I answered a question about this. :) – Ulrich Stern Jan 26 at 20:54

Start with looking up the z-value for your desired confidence interval from a look-up table. The confidence interval is then `mean +/- z*sigma`, where `sigma` is the estimated standard deviation of your sample mean, given by `sigma = s / sqrt(n)`, where `s` is the standard deviation computed from your sample data and `n` is your sample size.

• `scipy.stats.norm.interval(confidence, loc=mean, scale=sigma)` – Jaime Feb 22 '13 at 23:41
• The original asker indicated that a normal distribution was to be assumed, but it is worth pointing out that, for small sample populations (N < 100 or so), it is better to look up z in Student t's distribution instead of in the normal distribution. shasan's answer already does this. – Russ Mar 12 '14 at 14:00
• @bogatron, about the suggested calculus for the confidence interval, wouldn't be mean +/- z * sigma/sqrt(n), where n is sample size? – David Feb 19 '15 at 0:12
• @David, you are correct. I misstated the meaning of `sigma`. `sigma` in my answer should be the estimated standard deviation of the sample mean, not the estimated standard deviation of the distribution. I've updated the answer to clarify that. Thanks for pointing that out. – bogatron Feb 19 '15 at 14:34

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

``````from statistics import NormalDist

def confidence_interval(data, confidence=0.95):
dist = NormalDist.from_samples(data)
z = NormalDist().inv_cdf((1 + confidence) / 2.)
h = dist.stdev * z / ((len(data) - 1) ** .5)
return dist.mean - h, dist.mean + h
``````

This:

This assumes the sample size is big enough (let's say more than ~100 points) in order to use the standard normal distribution rather than the student's t distribution to compute the `z` value.