Strictly and asymptotically scale-invariant probabilistic models of N correlated binary random variables having q--Gaussians as N ∞ limiting distributions

Abstract

In order to physically enlighten the relationship between q--independence and scale-invariance, we introduce three types of asymptotically scale-invariant probabilistic models with binary random variables, namely (i) a family, characterized by an index =1,2,3,..., unifying the Leibnitz triangle (=1) and the case of independent variables (∞); (ii) two slightly different discretizations of q--Gaussians; (iii) a special family, characterized by the parameter , which generalizes the usual case of independent variables (recovered for =1/2). Models (i) and (iii) are in fact strictly scale-invariant. For models (i), we analytically show that the N ∞ probability distribution is a q--Gaussian with q=( -2)/(-1). Models (ii) approach q--Gaussians by construction, and we numerically show that they do so with asymptotic scale-invariance. Models (iii), like two other strictly scale-invariant models recently discussed by Hilhorst and Schehr (2007), approach instead limiting distributions which are not q--Gaussians. The scenario which emerges is that asymptotic (or even strict) scale-invariance is not sufficient but it might be necessary for having strict (or asymptotic) q--independence, which, in turn, mandates q--Gaussian attractors.