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This is a follow-up question on Bayesian correlation analysis as described in this example for PyMC2.

I successfully ported the non-robust approach, which uses the multivariate normal distribution to PyMC3, but I'm struggling with the robust version, where the multivariate Student-t distribution is used instead.

The problem is that the sigma vector denoting the variance eventually gets too large and the inverse of the covariance matrix cannot be computed anymore. Consequently, the posterior of the correlation r almost spans the whole interval [-1; 1].

The full code is available in this notebook for PyMC2 and in this notebook for PyMC3.

The relevant code for PyMC2 is:

import pymc
import numpy as np
from scipy.special import gammaln

def analyze(data):
    mu = pymc.Normal('mu', 0, 0.000001, size=2)
    sigma = pymc.Uniform('sigma', 0, 1000, size=2)
    rho = pymc.Uniform('r', -1, 1)

    nu = pymc.Exponential('nu',1/29., 1)
    # we model nu as an Exponential plus one
    @pymc.deterministic
    def nuplus(nu=nu):
        return nu + 1

    @pymc.deterministic
    def precision(sigma=sigma,rho=rho):
        ss1 = float(sigma[0] * sigma[0])
        ss2 = float(sigma[1] * sigma[1])
        rss = float(rho * sigma[0] * sigma[1])
        return np.linalg.inv(np.mat([[ss1, rss], [rss, ss2]]))

    # log-likelihood of multivariate t-distribution
    @pymc.stochastic(observed=True)
    def mult_t(value=data.T, mu=mu, tau=precision, nu=nuplus):
        k = float(tau.shape[0])
        res = 0
        for r in value:
            delta = r - mu
            enum1 = gammaln((nu+k)/2.) + 0.5 * np.log(np.linalg.det(tau))
            denom = (k/2.)*np.log(nu*np.pi) + gammaln(nu/2.)
            enum2 = (-(nu+k)/2.) * np.log (1 + (1/nu)*delta.dot(tau).dot(delta.T))
            result = enum1 + enum2 - denom
            res += result[0]
        return res[0,0]

    model = pymc.MCMC(locals()) 
    model.sample(50000,25000)

For PyMC3, I can use the built-in MvStudentT distribution, which expects a covariance matrix instead of a precision matrix.

import pymc3 as pm
import numpy as np

def mad(data, axis=None):
    return np.median(np.absolute(data - np.median(data, axis)), axis)


def covariance(sigma, rho):
    C = T.alloc(rho, 2, 2)
    C = T.fill_diagonal(C, 1.)
    S = T.diag(sigma)
    return S.dot(C).dot(S)


def analyze_robust(data):
    with pm.Model() as model:
        # priors might be adapted here to be less flat
        mu = pm.Normal('mu', mu=0., tau=0.000001, shape=2, testval=np.median(data, axis=1))
        sigma = pm.Uniform('sigma', lower=0, upper=1000, shape=2, testval=mad(data.T, axis=0))
        rho = pm.Uniform('r', lower=-1., upper=1., testval=0.5)

        cov = pm.Deterministic('cov', covariance(sigma, rho))
        nu = pm.Exponential('nu_minus_one', lam=1./29.) + 1
        mult_t = pm.MvStudentT('mult_t', nu=nu, mu=mu, Sigma=cov, observed=data.T)

    return model

Any hints that might explain the behaviour under PyMC3 are highly appreciated.

2
  • So... did you find what you were looking for?
    – David
    Commented Aug 9, 2018 at 3:42
  • I'm afraid not. I haven't investigated this problem further. I did file a bug though: github.com/pymc-devs/pymc3/issues/1501
    – sebp
    Commented Aug 15, 2018 at 11:36

1 Answer 1

0

I've found that the following seems to produce reasonable results. I based the priors on this article, and also used it to validate the correlation. All the work is in this notebook.

def mad(data, axis=None):
    return np.median(np.absolute(data - np.median(data, axis)), axis)

def covariance(sigma, rho):
    C = T.alloc(rho, 2, 2)
    C = T.fill_diagonal(C, 1.)
    S = T.diag(sigma)
    return S.dot(C).dot(S)

def analyze_robust(data):
    with pm.Model() as model:
        # priors might be adapted here to be less flat
        mu = pm.Normal('mu', mu=0., sd=100., shape=2, testval=np.median(data.T, axis=1))
        bound_sigma = pm.Bound(pm.Normal, lower=0.)
        sigma = bound_sigma('sigma', mu=0., sd=100., shape=2, testval=mad(data, axis=0))
        rho = pm.Uniform('r', lower=-1., upper=1., testval=0)
        cov = pm.Deterministic('cov', covariance(sigma, rho))
        bound_nu = pm.Bound(pm.Gamma, lower=1.)
        nu = bound_nu('nu', alpha=2, beta=10)
        mult_t = pm.MvStudentT('mult_t', nu=nu, mu=mu, Sigma=cov, observed=data)
    return model

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