The probability density function of the normal distribution expressed in Python is

```
from math import pi
from math import exp
from scipy import stats
def normal_pdf(x, mu, sigma):
return 1.0 / (sigma * (2.0 * pi)**(1/2)) * exp(-1.0 * (x - mu)**2 / (2.0 * (sigma**2)))
```

(compare that to the wikipedia definition). And this is exactly what `scipy.stats.norm().pdf()`

computes: the **value** of the pdf at point `x`

for a given `mu, sigma`

.

Note that this is **not** a probability (= **area** under the pdf) but rather the *value* of the pdf at the point `x`

you pass to `pdf(x)`

(and that value can very well be greater than `1.0`

!). You can see that, for example, for `N(0, 0.1)`

at `x = 0`

:

```
val = stats.norm(0, 0.1).pdf(0)
print(val)
val = normal_pdf(0, 0, 0.1)
print(val)
```

which gives the output

3.98942280401

3.989422804014327

Not at all a probability = area under the curve!

Note that this doesn't contradict the statement that the probability of particular value like `x = 0`

is `0`

because, formally, the area under the pdf for a point (i.e., an interval of length `0`

) is zero (if **f** is a continuous function on [a, b] and **F** is its antiderivative on [a, b], then the definite integral of **f** over [a, b] = **F(a) - F(b)**. Here, `a = b = x`

hence the value of the integral is `F(x) - F(x) = 0`

).

`0.03520653267642995`