van's answer using scipy is exactly right and using the `scipy.stats.ttest_*`

functions is very convenient.

But I came to this page looking for a solution with pure *numpy*, as stated in the heading, to avoid the scipy dependence. To this end, let me point out the example given here: https://docs.scipy.org/doc/numpy/reference/generated/numpy.random.standard_t.html

The main Problem is, that numpy does not have cumulative distribution functions, hence my conclusion is that you should really use scipy. Anyway, using only numpy is possible:

From the original question I am guessing that you want to compare your datasets and judge with a t-test whether there is a significant deviation? Further, that the samples are paired? (See https://en.wikipedia.org/wiki/Student%27s_t-test#Unpaired_and_paired_two-sample_t-tests )
In that case, you can calculate the t- and p-value like so:

```
import numpy as np
sample1 = np.array([55.0, 55.0, 47.0, 47.0, 55.0, 55.0, 55.0, 63.0])
sample2 = np.array([54.0, 56.0, 48.0, 46.0, 56.0, 56.0, 55.0, 62.0])
# paired sample -> the difference has mean 0
difference = sample1 - sample2
# the t-value is easily computed with numpy
t = (np.mean(difference))/(difference.std(ddof=1)/np.sqrt(len(difference)))
# unfortunately, numpy does not have a build in CDF
# here is a ridiculous work-around integrating by sampling
s = np.random.standard_t(len(difference), size=100000)
p = np.sum(s<t) / float(len(s))
# using a two-sided test
print("There is a {} % probability that the paired samples stem from distributions with the same means.".format(2 * min(p, 1 - p) * 100))
```

This will print `There is a 73.028 % probability that the paired samples stem from distributions with the same means.`

Since this is far above any sane confidence interval (say 5%), you should not conclude anything for the concrete case.