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 [9]: a = range(10,14)
In [10]: mean_confidence_interval(a)
Out[10]: (11.5, 9.4457397432391215, 13.554260256760879)
In [11]: st.t.interval(0.95, len(a)-1, loc=np.mean(a), scale=st.sem(a))
Out[11]: (9.4457397432391215, 13.554260256760879)
In [12]: sms.DescrStatsW(a).tconfint_mean()
Out[12]: (9.4457397432391197, 13.55426025676088)
```

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

:

```
In [13]: st.norm.interval(0.95, loc=np.mean(a), scale=st.sem(a))
Out[13]: (10.23484868811834, 12.76515131188166)
```