rAitchison: Aitchison Distribution

dAitchison

Returns the density of the Aitchison distribution evaluated at x as a numeric vector.

rAitchison

Returns a sample of size n of simulated compostions as an acomp object.

AitchisondistributionIntegrals

Returns a list with

• thetathe theta parameter given or computed

• betathe beta parameter given or computed

• alphathe alpha parameter given or computed

• muthe mu parameter given or computed

• sigmathe sigma parameter given or computed

• expKappathe integral over the density without closing constant. I.e. the inverse of the closing constant and the exp of \(\kappa_{Ait(\theta,\beta)}\)

• kappaIntegralThe expected value of the mean of the logs of the components as numerically computed

• clrMeanThe mean of the clr transformed random variable, computed numerically

• clrSqExpectationThe expectation of \(clr(X)clr(X)^t\) computed numerically.

• clrVarThe variance covariance matrix of clr(X), computed numerically

The Aitchison Distribution is a joint generalisation of the Dirichlet Distribution and the additive log-normal distribution (or normal on the simplex). It can be parametrized by Ait(theta,beta) or by Ait(alpha,mu,Sigma). Actually, beta and Sigma can be easily transformed into each other, such that only one of them is necessary. Parameter theta is a vector in \(R^D\), alpha is its sum, mu is a composition in \(S^D\), and beta and sigma are symmetric matrices, which can either be expressed in ilr or clr space. The parameters are transformed as $$\beta=-1/2 \Sigma^{-1}$$ $$\theta=clr(\mu)\Sigma+\alpha (1,\ldots,1)^t$$ The distribution exists, if either, \(\alpha\geq 0\) and Sigma is positive definite (or beta negative definite) in ilr-coordinates, or if each theta is strictly positive and Sigma has at least one positive eigenvalue (or beta has at least one negative eigenvalue). The simulation procedure currently only works with the first case.
AitchisonDistributionIntegral is a convenience function to compute the parameter transformation and several functions of these parameters. This is done by numerical integration over a multinomial simplex lattice of D parts with grid many elements (see xsimplex).
The density of the Aitchison distribution is given by: $$f(x,\theta,\beta)=exp((\theta-1)^t \log(x)+ilr(x)^t \beta ilr(x))/exp(\kappa_{Ait(\theta,\beta)})$$ with respect to the classical Haar measure on the simplex, and as $$f(x,\theta,\beta)=exp(\theta^t \log(x)+ilr(x)^t \beta ilr(x))/exp(\kappa_{Ait(\theta,\beta)})$$ with respect to the Aitchison measure of the simplex. The closure constant expKappa is computed numerically, in AitchisonDistributionIntegrals.

The random composition generation is done by rejection sampling based on an optimally fitted additive logistic normal distribution. Thus, it only works if the correponding Sigma in ilr would be positive definite.