Hilbert-Schmidt Separability Probabilities and Noninformativity of Priors
Abstract
The Horodecki family employed the Jaynes maximum-entropy principle, fitting the mean (b1) of the Bell-CHSH observable (B). This model was extended by Rajagopal by incorporating the dispersion (σ12) of the observable, and by Canosa and Rossignoli, by generalizing the observable (Bα). We further extend the Horodecki one-parameter model in both these manners, obtaining a three-parameter (b1,σ12,α) two-qubit model, for which we find a highly interesting/intricate continuum (-∞ < α < ∞) of Hilbert-Schmidt (HS) separability probabilities -- in which, the golden ratio is featured. Our model can be contrasted with the three-parameter (bq, σq2,q) one of Abe and Rajagopal, which employs a q(Tsallis)-parameter rather than α, and has simply q-invariant HS separability probabilities of 1/2. Our results emerge in a study initially focused on embedding certain information metrics over the two-level quantum systems into a q-framework. We find evidence that Srednicki's recently-stated biasedness criterion for noninformative priors yields rankings of priors fully consistent with an information-theoretic test of Clarke, previously applied to quantum systems by Slater.
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