From my understanding "central credible region" is not any different from how confidence intervals are calculated; all you need is the inverse of `cdf`

function at `alpha/2`

and `1-alpha/2`

; in `scipy`

this is called `ppf`

( percentage point function ); so as for Gaussian posterior distribution:

```
>>> from scipy.stats import norm
>>> alpha = .05
>>> l, u = norm.ppf(alpha / 2), norm.ppf(1 - alpha / 2)
```

to verify that `[l, u]`

covers `(1-alpha)`

of posterior density:

```
>>> norm.cdf(u) - norm.cdf(l)
0.94999999999999996
```

similarly for Beta posterior with say `a=1`

and `b=3`

:

```
>>> from scipy.stats import beta
>>> l, u = beta.ppf(alpha / 2, a=1, b=3), beta.ppf(1 - alpha / 2, a=1, b=3)
```

and again:

```
>>> beta.cdf(u, a=1, b=3) - beta.cdf(l, a=1, b=3)
0.94999999999999996
```

here you can see parametric distributions that are included in scipy; and I guess all of them have `ppf`

function;

As for highest posterior density region, it is more tricky, since `pdf`

function is not necessarily invertible; and in general such a region may not even be connected; for example, in the case of Beta with `a = b = .5`

( as can be seen here);

But, in the case of Gaussian distribution, it is easy to see that "Highest Posterior Density Region" coincides with "Central Credible Region"; and I think that is is the case for all symmetric uni-modal distributions ( i.e. if pdf function is symmetric around the mode of distribution)

A possible numerical approach for the general case would be binary search over the value of `p*`

using numerical integration of `pdf`

; utilizing the fact that the integral is a monotone function of `p*`

;

Here is an example for mixture Gaussian:

**[ 1 ]** First thing you need is an analytical pdf function; for mixture Gaussian that is easy:

```
def mix_norm_pdf(x, loc, scale, weight):
from scipy.stats import norm
return np.dot(weight, norm.pdf(x, loc, scale))
```

so for example for location, scale and weight values as in

```
loc = np.array([-1, 3]) # mean values
scale = np.array([.5, .8]) # standard deviations
weight = np.array([.4, .6]) # mixture probabilities
```

you will get two nice Gaussian distributions holding hands:

**[ 2 ]** now, you need an error function which given a test value for `p*`

integrates pdf function above `p*`

and returns squared error from the desired value `1 - alpha`

:

```
def errfn( p, alpha, *args):
from scipy import integrate
def fn( x ):
pdf = mix_norm_pdf(x, *args)
return pdf if pdf > p else 0
# ideally integration limits should not
# be hard coded but inferred
lb, ub = -3, 6
prob = integrate.quad(fn, lb, ub)[0]
return (prob + alpha - 1.0)**2
```

**[ 3 ]** now, for a given value of `alpha`

we can minimize the error function to obtain `p*`

:

```
alpha = .05
from scipy.optimize import fmin
p = fmin(errfn, x0=0, args=(alpha, loc, scale, weight))[0]
```

which results in `p* = 0.0450`

, and HPD as below; the red area represents `1 - alpha`

of the distribution, and the horizontal dashed line is `p*`

.