Abstract
We introduce a task that we call partial decoupling, in which a bipartite quantum state is transformed by a unitary operation on one of the two subsystems and then is subject to the action of a quantum channel. We assume that the subsystem is decomposed into a direct-sum-product form, which often appears in the context of quantum information theory. The unitary is chosen at random from the set of unitaries having a simple form under the decomposition. The goal of the task is to make the final state, for typical choices of the unitary, close to the averaged final state over the unitaries. We consider a one-shot scenario, and derive upper and lower bounds on the average distance between the two states. The bounds are represented simply in terms of smooth conditional entropies of quantum states involving the initial state, the channel and the decomposition. Thereby we provide generalizations of the one-shot decoupling theorem. The obtained result would lead to further development of the decoupling approaches in quantum information theory and fundamental physics.
Highlights
Decoupling refers to the fact that we may destroy correlation between two quantum systems by applying an operation on one of the two subsystems
The bounds are represented in terms of the smooth conditional entropies of quantum states involving the initial state, the channel and the decomposition
We consider two scenarios in which a bipartite quantum state AR is transformed by a unitary operation on A and is subject to the action of a quantum channel T A→E
Summary
Decoupling refers to the fact that we may destroy correlation between two quantum systems by applying an operation on one of the two subsystems. [21,22,23], we investigate communication tasks between two parties in which the information to be transmitted has both classical and quantum components In this case, the Hilbert space Hlj in (1) is assumed to be a one-dimensional space C, and Hlj to be the spaces with the same dimension for all j:. [24], we apply the result of partial decoupling to investigate the information paradox of quantum black holes with symmetry. By letting j be the labeling of the conserved quantity, the internal dynamics randomizes only the multiplicity spaces {Hrj } and should be in the form of This case is in the scope of partial decoupling with a DSP decomposition given by the symmetry.
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