Uhlmann's theorem for measured divergences
Abstract
Uhlmann's theorem is a cornerstone of quantum information theory, stating that for any quantum state AB and any state σA, there exists an extension σAB of σA such that the fidelity between AB and σAB equals the fidelity between their marginals A and σA. This property underpins many results and applications in quantum information science. In this work, we generalize Uhlmann's theorem to a broad class of measured f-divergences, including the measured α-R\'enyi divergences for all α ≥ 0. The well-known Uhlmann's theorem for the fidelity corresponds to the special case α = 12. Since most commonly used quantum R\'enyi divergences, including the Petz and sandwiched R\'enyi divergences, cannot satisfy this property (except for degenerate cases). This fundamentally distinguishes measured f-divergences from other quantum divergences and highlights their unique mathematical structure.
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