Los puntos clave no están disponibles para este artículo en este momento.
Jensen-Shannon divergence (JD) is a symmetrized and smoothed version of the most important divergence measure of information theory, Kullback divergence. As opposed to Kullback divergence it determines in a very direct way a metric; indeed, it is the square of a metric. We consider a family of divergence measures (JD_ for >0), the Jensen divergences of order, which generalize JD as JD₁=JD. Using a result of Schoenberg, we prove that JD_ is the square of a metric for ∊ (0, 2], and that the resulting metric space of probability distributions can be isometrically embedded in a real Hilbert space. Quantum Jensen-Shannon divergence (QJD) is a symmetrized and smoothed version of quantum relative entropy and can be extended to a family of quantum Jensen divergences of order (QJD_). We strengthen results by Lamberti and co-workers by proving that for qubits and pure states, QJD_^1/2 is a metric space which can be isometrically embedded in a real Hilbert space when ∊ (0, 2]. In analogy with Burbea and Rao's generalization of JD, we also define general QJD by associating a Jensen-type quantity to any weighted family of states. Appropriate interpretations of quantities introduced are discussed and bounds are derived in terms of the total variation and trace distance.
Briët et al. (Tue,) studied this question.