dist.Multivariate.t.Precision: Multivariate t Distribution: Precision Parameterization

dmvtp gives the density and rmvtp generates random deviates.

• Application: Continuous Multivariate

• Density: $$p(\theta) = \frac{\Gamma((\nu+k)/2)}{\Gamma(\nu/2)\nu^{k/2}\pi^{k/2}} |\Omega|^{1/2} (1 + \frac{1}{\nu} (\theta-\mu)^T \Omega (\theta-\mu))^{-(\nu+k)/2}$$

• Inventor: Unknown (to me, anyway)

• Notation 1: \(\theta \sim \mathrm{t}_k(\mu, \Omega^{-1}, \nu)\)

• Notation 2: \(p(\theta) = \mathrm{t}_k(\theta | \mu, \Omega^{-1}, \nu)\)

• Parameter 1: location vector \(\mu\)

• Parameter 2: positive-definite \(k \times k\) precision matrix \(\Omega\)

• Parameter 3: degrees of freedom \(\nu > 0\)

• Mean: \(E(\theta) = \mu\), for \(\nu > 1\), otherwise undefined

• Variance: \(var(\theta) = \frac{\nu}{\nu - 2} \Omega^{-1}\), for \(\nu > 2\)

• Mode: \(mode(\theta) = \mu\)

The multivariate t distribution, also called the multivariate Student or multivariate Student t distribution, is a multidimensional extension of the one-dimensional or univariate Student t distribution. A random vector is considered to be multivariate t-distributed if every linear combination of its components has a univariate Student t-distribution.

It is usually parameterized with mean and a covariance matrix, or in Bayesian inference, with mean and a precision matrix, where the precision matrix is the matrix inverse of the covariance matrix. These functions provide the precision parameterization for convenience and familiarity. It is easier to calculate a multivariate t density with the precision parameterization, because a matrix inversion can be avoided.

This distribution has a mean parameter vector \(\mu\) of length \(k\), and a \(k \times k\) precision matrix \(\Omega\), which must be positive-definite. When degrees of freedom \(\nu=1\), this is the multivariate Cauchy distribution.