24

Given a posterior p(Θ|D) over some parameters Θ, one can define the following:

Highest Posterior Density Region:

The Highest Posterior Density Region is the set of most probable values of Θ that, in total, constitute 100(1-α) % of the posterior mass.

In other words, for a given α, we look for a p* that satisfies:

enter image description here

and then obtain the Highest Posterior Density Region as the set:

enter image description here

Central Credible Region:

Using the same notation as above, a Credible Region (or interval) is defined as:

enter image description here

Depending on the distribution, there could be many such intervals. The central credible interval is defined as a credible interval where there is (1-α)/2 mass on each tail.

Computation:

  • For general distributions, given samples from the distribution, are there any built-ins in to obtain the two quantities above in Python or PyMC?

  • For common parametric distributions (e.g. Beta, Gaussian, etc.) are there any built-ins or libraries to compute this using SciPy or statsmodels?

  • Why the close vote? Can you please elaborate? – Amelio Vazquez-Reina Mar 9 '14 at 16:28
  • confidence intervals come from frequentist inference; posterior distribution is the bayesian approach; these are very different paradigms; what is the point of mixing them together? – behzad.nouri Mar 9 '14 at 20:43
  • 11
    @behzad.nouri - nowhere in my post I mentioned confidence intervals. Both credible and HPD regions are Bayesian. – Amelio Vazquez-Reina Mar 9 '14 at 21:06
7

To calculate HPD you can leverage pymc3, Here is an example

import pymc3
from scipy.stats import norm
a = norm.rvs(size=10000)
pymc3.stats.hpd(a)
  • If you want to use pymc: import pymc as pm pm.utils.hpd(a, alpha=0.025). The docstring says: """Calculate highest posterior density (HPD) of array for given alpha. The HPD is the minimum width Bayesian credible interval (BCI). :Arguments: x : Numpy array An array containing MCMC samples alpha : float Desired probability of type I error """ – denvar Jun 18 '18 at 17:59
12

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:

enter image description here


[ 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*.

enter image description here

  • 1
    Thanks @behzad.nouri -- If we assume that the Normal distribution in your code refers to the posterior of Θ (as I assumed in the OP) then, what you are computing above is the central credible region and not a confidence interval. – Amelio Vazquez-Reina Mar 10 '14 at 2:19
  • @user815423426 i am just saying the computation is similar to how confidence intervals are calculated, ( in the sense that you look at inverse cdf function ); – behzad.nouri Mar 10 '14 at 2:22
  • That is correct. Thanks. I'm definitely interested in the last sentence of your answer. Assuming e.g. a mix. of two Gaussians, would you mind elaborating further on the computation of the HPD using integration methods from SciPy? – Amelio Vazquez-Reina Mar 10 '14 at 2:26
  • 2
    @user815423426 i will edit my answer to include more details when i get the chance – behzad.nouri Mar 10 '14 at 2:29
  • 3
    @user815423426 edits are there – behzad.nouri Mar 10 '14 at 18:18
8

PyMC has a built in function for computing the hpd. In v2.3 it's in utils. See the source here. As an example of a linear model and it's HPD

import pymc as pc  
import numpy as np
import matplotlib.pyplot as plt 
## data
np.random.seed(1)
x = np.array(range(0,50))
y = np.random.uniform(low=0.0, high=40.0, size=50)
y = 2*x+y
## plt.scatter(x,y)

## priors
emm = pc.Uniform('m', -100.0, 100.0, value=0)
cee = pc.Uniform('c', -100.0, 100.0, value=0) 

#linear-model
@pc.deterministic(plot=False)
def lin_mod(x=x, cee=cee, emm=emm):
    return emm*x + cee 

#likelihood
llhy = pc.Normal('y', mu=lin_mod, tau=1.0/(10.0**2), value=y, observed=True)

linearModel = pc.Model( [llhy, lin_mod, emm, cee] )
MCMClinear = pc.MCMC( linearModel)
MCMClinear.sample(10000,burn=5000,thin=5)
linear_output=MCMClinear.stats()

## pc.Matplot.plot(MCMClinear)
## print HPD using the trace of each parameter 
print(pc.utils.hpd(MCMClinear.trace('m')[:] , 1.- 0.95))
print(pc.utils.hpd(MCMClinear.trace('c')[:] , 1.- 0.95))

You may also consider calculating the quantiles

print(linear_output['m']['quantiles'])
print(linear_output['c']['quantiles'])

where I think if you just take the 2.5% to 97.5% values you get your 95% central credible interval.

  • FYI the docstring for the function is: """Calculate highest posterior density (HPD) of array for given alpha. The HPD is the minimum width Bayesian credible interval (BCI). :Arguments: x : Numpy array An array containing MCMC samples alpha : float Desired probability of type I error """ – denvar Jun 18 '18 at 18:00
  • I tried this in Python 3. I installed these: pip install numpy pymc matplotlib pymc scipy From the linear_output=MCMClinear.stats() statement, I get Could not generate output statistics for c Could not generate output statistics for lin_mod Could not generate output statistics for m The HPD prints are: [1.96582851 2.31984871] [10.0042424 20.72279348] The lines like print(linear_output['m']['quantiles']) say: TypeError: 'NoneType' object is not subscriptable. Not sure how to interpret that... – nealmcb Jan 18 at 3:53
8

Another option (adapted from R to Python) and taken from the book Doing bayesian data analysis by John K. Kruschke) is the following:

from scipy.optimize import fmin
from scipy.stats import *

def HDIofICDF(dist_name, credMass=0.95, **args):
    # freeze distribution with given arguments
    distri = dist_name(**args)
    # initial guess for HDIlowTailPr
    incredMass =  1.0 - credMass

    def intervalWidth(lowTailPr):
        return distri.ppf(credMass + lowTailPr) - distri.ppf(lowTailPr)

    # find lowTailPr that minimizes intervalWidth
    HDIlowTailPr = fmin(intervalWidth, incredMass, ftol=1e-8, disp=False)[0]
    # return interval as array([low, high])
    return distri.ppf([HDIlowTailPr, credMass + HDIlowTailPr])

The idea is to create a function intervalWidth that returns the width of the interval that starts at lowTailPr and has credMass mass. The minimum of the intervalWidth function is founded by using the fmin minimizer from scipy.

For example the result of:

print HDIofICDF(norm, credMass=0.95, loc=0, scale=1)

is

    [-1.95996398  1.95996398]

The name of the distribution parameters passed to HDIofICDF, must be exactly the same used in scipy.

  • 1
    This is a really nice solution for unimodal distributions found in scipy. The code style makes me twitch a little, but the simplicity of your answer wins the day. – mtw729 Sep 14 '14 at 2:33
  • Please do clarify which problem you're solving: a restricted version of the original question: the Highest Posterior Density Region restricted to uni-modal distributions? – nealmcb Jan 18 at 3:32
5

I stumbled across this post trying to find a way to estimate an HDI from an MCMC sample but none of the answers worked for me. Like aloctavodia, I adapted an R example from the book Doing Bayesian Data Analysis to Python. I needed to compute a 95% HDI from an MCMC sample. Here's my solution:

import numpy as np
def HDI_from_MCMC(posterior_samples, credible_mass):
    # Computes highest density interval from a sample of representative values,
    # estimated as the shortest credible interval
    # Takes Arguments posterior_samples (samples from posterior) and credible mass (normally .95)
    sorted_points = sorted(posterior_samples)
    ciIdxInc = np.ceil(credible_mass * len(sorted_points)).astype('int')
    nCIs = len(sorted_points) - ciIdxInc
    ciWidth = [0]*nCIs
    for i in range(0, nCIs):
    ciWidth[i] = sorted_points[i + ciIdxInc] - sorted_points[i]
    HDImin = sorted_points[ciWidth.index(min(ciWidth))]
    HDImax = sorted_points[ciWidth.index(min(ciWidth))+ciIdxInc]
    return(HDImin, HDImax)

The method above is giving me logical answers based on the data I have!

2

You can get the central credible interval in two ways: Graphically, when you call summary_plot on variables in your model, there is an bpd flag that is set to True by default. Changing this to False will draw the central intervals. The second place you can get it is when you call the summary method on your model or a node; it will give you posterior quantiles, and the outer ones will be 95% central interval by default (which you can change with the alpha argument).

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