Theory-independent limits on correlations from generalized Bayesian networks

TY - JOUR

T1 - Theory-independent limits on correlations from generalized Bayesian networks

AU - Henson, Joe

AU - Lal, Raymond

AU - Pusey, Matthew F.

PY - 2014/11/20

Y1 - 2014/11/20

N2 - Bayesian networks provide a powerful tool for reasoning about probabilistic causation, used in many areas of science. They are, however, intrinsically classical. In particular, Bayesian networks naturally yield the Bell inequalities. Inspired by this connection, we generalize the formalism of classical Bayesian networks in order to investigate non-classical correlations in arbitrary causal structures. Our framework of 'generalized Bayesian networks' replaces latent variables with the resources of any generalized probabilistic theory, most importantly quantum theory, but also, for example, Popescu–Rohrlich boxes. We obtain three main sets of results. Firstly, we prove that all of the observable conditional independences required by the classical theory also hold in our generalization; to obtain this, we extend the classical d-separation theorem to our setting. Secondly, we find that the theory-independent constraints on probabilities can go beyond these conditional independences. For example we find that no probabilistic theory predicts perfect correlation between three parties using only bipartite common causes. Finally, we begin a classification of those causal structures, such as the Bell scenario, that may yield a separation between classical, quantum and general-probabilistic correlations.

AB - Bayesian networks provide a powerful tool for reasoning about probabilistic causation, used in many areas of science. They are, however, intrinsically classical. In particular, Bayesian networks naturally yield the Bell inequalities. Inspired by this connection, we generalize the formalism of classical Bayesian networks in order to investigate non-classical correlations in arbitrary causal structures. Our framework of 'generalized Bayesian networks' replaces latent variables with the resources of any generalized probabilistic theory, most importantly quantum theory, but also, for example, Popescu–Rohrlich boxes. We obtain three main sets of results. Firstly, we prove that all of the observable conditional independences required by the classical theory also hold in our generalization; to obtain this, we extend the classical d-separation theorem to our setting. Secondly, we find that the theory-independent constraints on probabilities can go beyond these conditional independences. For example we find that no probabilistic theory predicts perfect correlation between three parties using only bipartite common causes. Finally, we begin a classification of those causal structures, such as the Bell scenario, that may yield a separation between classical, quantum and general-probabilistic correlations.

U2 - 10.1088/1367-2630/16/11/113043

DO - 10.1088/1367-2630/16/11/113043

M3 - Article

SN - 1367-2630

VL - 16

JO - New Journal of Physics

JF - New Journal of Physics

IS - 11

M1 - 113043

ER -