# Robust Bayesian Correlation with PyMC3

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])

# 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

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.

• So... did you find what you were looking for? 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

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
``````